/* linux/arch/arm/plat-s3c24xx/pm.c * * Copyright (c) 2004,2006 Simtec Electronics * Ben Dooks * * S3C24XX Power Manager (Suspend-To-RAM) support * * See Documentation/arm/Samsung-S3C24XX/Suspend.txt for more information * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * * Parts based on arch/arm/mach-pxa/pm.c * * Thanks to Dimitry Andric for debugging */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* for external use */ unsigned long s3c_pm_flags; #define PFX "s3c24xx-pm: " static struct sleep_save core_save[] = { SAVE_ITEM(S3C2410_LOCKTIME), SAVE_ITEM(S3C2410_CLKCON), /* we restore the timings here, with the proviso that the board * brings the system up in an slower, or equal frequency setting * to the original system. * * if we cannot guarantee this, then things are going to go very * wrong here, as we modify the refresh and both pll settings. */ SAVE_ITEM(S3C2410_BWSCON), SAVE_ITEM(S3C2410_BANKCON0), SAVE_ITEM(S3C2410_BANKCON1), SAVE_ITEM(S3C2410_BANKCON2), SAVE_ITEM(S3C2410_BANKCON3), SAVE_ITEM(S3C2410_BANKCON4), SAVE_ITEM(S3C2410_BANKCON5), #ifndef CONFIG_CPU_FREQ SAVE_ITEM(S3C2410_CLKDIVN), SAVE_ITEM(S3C2410_MPLLCON), SAVE_ITEM(S3C2410_REFRESH), #endif SAVE_ITEM(S3C2410_UPLLCON), SAVE_ITEM(S3C2410_CLKSLOW), }; static struct gpio_sleep { void __iomem *base; unsigned int gpcon; unsigned int gpdat; unsigned int gpup; } gpio_save[] = { [0] = { .base = S3C2410_GPACON, }, [1] = { .base = S3C2410_GPBCON, }, [2] = { .base = S3C2410_GPCCON, }, [3] = { .base = S3C2410_GPDCON, }, [4] = { .base = S3C2410_GPECON, }, [5] = { .base = S3C2410_GPFCON, }, [6] = { .base = S3C2410_GPGCON, }, [7] = { .base = S3C2410_GPHCON, }, }; static struct sleep_save misc_save[] = { SAVE_ITEM(S3C2410_DCLKCON), }; #ifdef CONFIG_S3C2410_PM_DEBUG #define SAVE_UART(va) \ SAVE_ITEM((va) + S3C2410_ULCON), \ SAVE_ITEM((va) + S3C2410_UCON), \ SAVE_ITEM((va) + S3C2410_UFCON), \ SAVE_ITEM((va) + S3C2410_UMCON), \ SAVE_ITEM((va) + S3C2410_UBRDIV) static struct sleep_save uart_save[] = { SAVE_UART(S3C24XX_VA_UART0), SAVE_UART(S3C24XX_VA_UART1), #ifndef CONFIG_CPU_S3C2400 SAVE_UART(S3C24XX_VA_UART2), #endif }; /* debug * * we send the debug to printascii() to allow it to be seen if the * system never wakes up from the sleep */ extern void printascii(const char *); void pm_dbg(const char *fmt, ...) { va_list va; char buff[256]; va_start(va, fmt); vsprintf(buff, fmt, va); va_end(va); printascii(buff); } static void s3c2410_pm_debug_init(void) { unsigned long tmp = __raw_readl(S3C2410_CLKCON); /* re-start uart clocks */ tmp |= S3C2410_CLKCON_UART0; tmp |= S3C2410_CLKCON_UART1; tmp |= S3C2410_CLKCON_UART2; __raw_writel(tmp, S3C2410_CLKCON); udelay(10); } #define DBG(fmt...) pm_dbg(fmt) #else #define DBG(fmt...) printk(KERN_DEBUG fmt) #define s3c2410_pm_debug_init() do { } while(0) static struct sleep_save uart_save[] = {}; #endif #if defined(CONFIG_S3C2410_PM_CHECK) && CONFIG_S3C2410_PM_CHECK_CHUNKSIZE != 0 /* suspend checking code... * * this next area does a set of crc checks over all the installed * memory, so the system can verify if the resume was ok. * * CONFIG_S3C2410_PM_CHECK_CHUNKSIZE defines the block-size for the CRC, * increasing it will mean that the area corrupted will be less easy to spot, * and reducing the size will cause the CRC save area to grow */ #define CHECK_CHUNKSIZE (CONFIG_S3C2410_PM_CHECK_CHUNKSIZE * 1024) static u32 crc_size; /* size needed for the crc block */ static u32 *crcs; /* allocated over suspend/resume */ typedef u32 *(run_fn_t)(struct resource *ptr, u32 *arg); /* s3c2410_pm_run_res * * go thorugh the given resource list, and look for system ram */ static void s3c2410_pm_run_res(struct resource *ptr, run_fn_t fn, u32 *arg) { while (ptr != NULL) { if (ptr->child != NULL) s3c2410_pm_run_res(ptr->child, fn, arg); if ((ptr->flags & IORESOURCE_MEM) && strcmp(ptr->name, "System RAM") == 0) { DBG("Found system RAM at %08lx..%08lx\n", ptr->start, ptr->end); arg = (fn)(ptr, arg); } ptr = ptr->sibling; } } static void s3c2410_pm_run_sysram(run_fn_t fn, u32 *arg) { s3c2410_pm_run_res(&iomem_resource, fn, arg); } static u32 *s3c2410_pm_countram(struct resource *res, u32 *val) { u32 size = (u32)(res->end - res->start)+1; size += CHECK_CHUNKSIZE-1; size /= CHECK_CHUNKSIZE; DBG("Area %08lx..%08lx, %d blocks\n", res->start, res->end, size); *val += size * sizeof(u32); return val; } /* s3c2410_pm_prepare_check * * prepare the necessary information for creating the CRCs. This * must be done before the final save, as it will require memory * allocating, and thus touching bits of the kernel we do not * know about. */ static void s3c2410_pm_check_prepare(void) { crc_size = 0; s3c2410_pm_run_sysram(s3c2410_pm_countram, &crc_size); DBG("s3c2410_pm_prepare_check: %u checks needed\n", crc_size); crcs = kmalloc(crc_size+4, GFP_KERNEL); if (crcs == NULL) printk(KERN_ERR "Cannot allocated CRC save area\n"); } static u32 *s3c2410_pm_makecheck(struct resource *res, u32 *val) { unsigned long addr, left; for (addr = res->start; addr < res->end; addr += CHECK_CHUNKSIZE) { left = res->end - addr; if (left > CHECK_CHUNKSIZE) left = CHECK_CHUNKSIZE; *val = crc32_le(~0, phys_to_virt(addr), left); val++; } return val; } /* s3c2410_pm_check_store * * compute the CRC values for the memory blocks before the final * sleep. */ static void s3c2410_pm_check_store(void) { if (crcs != NULL) s3c2410_pm_run_sysram(s3c2410_pm_makecheck, crcs); } /* in_region * * return TRUE if the area defined by ptr..ptr+size contatins the * what..what+whatsz */ static inline int in_region(void *ptr, int size, void *what, size_t whatsz) { if ((what+whatsz) < ptr) return 0; if (what > (ptr+size)) return 0; return 1; } static u32 *s3c2410_pm_runcheck(struct resource *res, u32 *val) { void *save_at = phys_to_virt(s3c2410_sleep_save_phys); unsigned long addr; unsigned long left; void *ptr; u32 calc; for (addr = res->start; addr < res->end; addr += CHECK_CHUNKSIZE) { left = res->end - addr; if (left > CHECK_CHUNKSIZE) left = CHECK_CHUNKSIZE; ptr = phys_to_virt(addr); if (in_region(ptr, left, crcs, crc_size)) { DBG("skipping %08lx, has crc block in\n", addr); goto skip_check; } if (in_region(ptr, left, save_at, 32*4 )) { DBG("skipping %08lx, has save block in\n", addr); goto skip_check; } /* calculate and check the checksum */ calc = crc32_le(~0, ptr, left); if (calc != *val) { printk(KERN_ERR PFX "Restore CRC error at " "%08lx (%08x vs %08x)\n", addr, calc, *val); DBG("Restore CRC error at %08lx (%08x vs %08x)\n", addr, calc, *val); } skip_check: val++; } return val; } /* s3c2410_pm_check_restore * * check the CRCs after the restore event and free the memory used * to hold them */ static void s3c2410_pm_check_restore(void) { if (crcs != NULL) { s3c2410_pm_run_sysram(s3c2410_pm_runcheck, crcs); kfree(crcs); crcs = NULL; } } #else #define s3c2410_pm_check_prepare() do { } while(0) #define s3c2410_pm_check_restore() do { } while(0) #define s3c2410_pm_check_store() do { } while(0) #endif /* helper functions to save and restore register state */ void s3c2410_pm_do_save(struct sleep_save *ptr, int count) { for (; count > 0; count--, ptr++) { ptr->val = __raw_readl(ptr->reg); DBG("saved %p value %08lx\n", ptr->reg, ptr->val); } } /* s3c2410_pm_do_restore * * restore the system from the given list of saved registers * * Note, we do not use DBG() in here, as the system may not have * restore the UARTs state yet */ void s3c2410_pm_do_restore(struct sleep_save *ptr, int count) { for (; count > 0; count--, ptr++) { printk(KERN_DEBUG "restore %p (restore %08lx, was %08x)\n", ptr->reg, ptr->val, __raw_readl(ptr->reg)); __raw_writel(ptr->val, ptr->reg); } } /* s3c2410_pm_do_restore_core * * similar to s3c2410_pm_do_restore_core * * WARNING: Do not put any debug in here that may effect memory or use * peripherals, as things may be changing! */ static void s3c2410_pm_do_restore_core(struct sleep_save *ptr, int count) { for (; count > 0; count--, ptr++) { __raw_writel(ptr->val, ptr->reg); } } /* s3c2410_pm_show_resume_irqs * * print any IRQs asserted at resume time (ie, we woke from) */ static void s3c2410_pm_show_resume_irqs(int start, unsigned long which, unsigned long mask) { int i; which &= ~mask; for (i = 0; i <= 31; i++) { if ((which) & (1L<base; gps->gpcon = __raw_readl(base + OFFS_CON); gps->gpdat = __raw_readl(base + OFFS_DAT); if (gpio > 0) gps->gpup = __raw_readl(base + OFFS_UP); } } /* Test whether the given masked+shifted bits of an GPIO configuration * are one of the SFN (special function) modes. */ static inline int is_sfn(unsigned long con) { return (con == 2 || con == 3); } /* Test if the given masked+shifted GPIO configuration is an input */ static inline int is_in(unsigned long con) { return con == 0; } /* Test if the given masked+shifted GPIO configuration is an output */ static inline int is_out(unsigned long con) { return con == 1; } /* s3c2410_pm_restore_gpio() * * Restore one of the GPIO banks that was saved during suspend. This is * not as simple as once thought, due to the possibility of glitches * from the order that the CON and DAT registers are set in. * * The three states the pin can be are {IN,OUT,SFN} which gives us 9 * combinations of changes to check. Three of these, if the pin stays * in the same configuration can be discounted. This leaves us with * the following: * * { IN => OUT } Change DAT first * { IN => SFN } Change CON first * { OUT => SFN } Change CON first, so new data will not glitch * { OUT => IN } Change CON first, so new data will not glitch * { SFN => IN } Change CON first * { SFN => OUT } Change DAT first, so new data will not glitch [1] * * We do not currently deal with the UP registers as these control * weak resistors, so a small delay in change should not need to bring * these into the calculations. * * [1] this assumes that writing to a pin DAT whilst in SFN will set the * state for when it is next output. */ static void s3c2410_pm_restore_gpio(int index, struct gpio_sleep *gps) { void __iomem *base = gps->base; unsigned long gps_gpcon = gps->gpcon; unsigned long gps_gpdat = gps->gpdat; unsigned long old_gpcon; unsigned long old_gpdat; unsigned long old_gpup = 0x0; unsigned long gpcon; int nr; old_gpcon = __raw_readl(base + OFFS_CON); old_gpdat = __raw_readl(base + OFFS_DAT); if (base == S3C2410_GPACON) { /* GPACON only has one bit per control / data and no PULLUPs. * GPACON[x] = 0 => Output, 1 => SFN */ /* first set all SFN bits to SFN */ gpcon = old_gpcon | gps->gpcon; __raw_writel(gpcon, base + OFFS_CON); /* now set all the other bits */ __raw_writel(gps_gpdat, base + OFFS_DAT); __raw_writel(gps_gpcon, base + OFFS_CON); } else { unsigned long old, new, mask; unsigned long change_mask = 0x0; old_gpup = __raw_readl(base + OFFS_UP); /* Create a change_mask of all the items that need to have * their CON value changed before their DAT value, so that * we minimise the work between the two settings. */ for (nr = 0, mask = 0x03; nr < 32; nr += 2, mask <<= 2) { old = (old_gpcon & mask) >> nr; new = (gps_gpcon & mask) >> nr; /* If there is no change, then skip */ if (old == new) continue; /* If both are special function, then skip */ if (is_sfn(old) && is_sfn(new)) continue; /* Change is IN => OUT, do not change now */ if (is_in(old) && is_out(new)) continue; /* Change is SFN => OUT, do not change now */ if (is_sfn(old) && is_out(new)) continue; /* We should now be at the case of IN=>SFN, * OUT=>SFN, OUT=>IN, SFN=>IN. */ change_mask |= mask; } /* Write the new CON settings */ gpcon = old_gpcon & ~change_mask; gpcon |= gps_gpcon & change_mask; __raw_writel(gpcon, base + OFFS_CON); /* Now change any items that require DAT,CON */ __raw_writel(gps_gpdat, base + OFFS_DAT); __raw_writel(gps_gpcon, base + OFFS_CON); __raw_writel(gps->gpup, base + OFFS_UP); } DBG("GPIO[%d] CON %08lx => %08lx, DAT %08lx => %08lx\n", index, old_gpcon, gps_gpcon, old_gpdat, gps_gpdat); } /** s3c2410_pm_restore_gpios() * * Restore the state of the GPIOs */ static void s3c2410_pm_restore_gpios(void) { struct gpio_sleep *gps = gpio_save; int gpio; for (gpio = 0; gpio < ARRAY_SIZE(gpio_save); gpio++, gps++) { s3c2410_pm_restore_gpio(gpio, gps); } } void (*pm_cpu_prep)(void); void (*pm_cpu_sleep)(void); #define any_allowed(mask, allow) (((mask) & (allow)) != (allow)) /* s3c2410_pm_enter * * central control for sleep/resume process */ static int s3c2410_pm_enter(suspend_state_t state) { unsigned long regs_save[16]; /* ensure the debug is initialised (if enabled) */ s3c2410_pm_debug_init(); DBG("s3c2410_pm_enter(%d)\n", state); if (pm_cpu_prep == NULL || pm_cpu_sleep == NULL) { printk(KERN_ERR PFX "error: no cpu sleep functions set\n"); return -EINVAL; } /* check if we have anything to wake-up with... bad things seem * to happen if you suspend with no wakeup (system will often * require a full power-cycle) */ if (!any_allowed(s3c_irqwake_intmask, s3c_irqwake_intallow) && !any_allowed(s3c_irqwake_eintmask, s3c_irqwake_eintallow)) { printk(KERN_ERR PFX "No sources enabled for wake-up!\n"); printk(KERN_ERR PFX "Aborting sleep\n"); return -EINVAL; } /* prepare check area if configured */ s3c2410_pm_check_prepare(); /* store the physical address of the register recovery block */ s3c2410_sleep_save_phys = virt_to_phys(regs_save); DBG("s3c2410_sleep_save_phys=0x%08lx\n", s3c2410_sleep_save_phys); /* save all necessary core registers not covered by the drivers */ s3c2410_pm_save_gpios(); s3c2410_pm_do_save(misc_save, ARRAY_SIZE(misc_save)); s3c2410_pm_do_save(core_save, ARRAY_SIZE(core_save)); s3c2410_pm_do_save(uart_save, ARRAY_SIZE(uart_save)); /* set the irq configuration for wake */ s3c2410_pm_configure_extint(); DBG("sleep: irq wakeup masks: %08lx,%08lx\n", s3c_irqwake_intmask, s3c_irqwake_eintmask); __raw_writel(s3c_irqwake_intmask, S3C2410_INTMSK); __raw_writel(s3c_irqwake_eintmask, S3C2410_EINTMASK); /* ack any outstanding external interrupts before we go to sleep */ __raw_writel(__raw_readl(S3C2410_EINTPEND), S3C2410_EINTPEND); __raw_writel(__raw_readl(S3C2410_INTPND), S3C2410_INTPND); __raw_writel(__raw_readl(S3C2410_SRCPND), S3C2410_SRCPND); /* call cpu specific preparation */ pm_cpu_prep(); /* flush cache back to ram */ flush_cache_all(); s3c2410_pm_check_store(); /* send the cpu to sleep... */ __raw_writel(0x00, S3C2410_CLKCON); /* turn off clocks over sleep */ /* s3c2410_cpu_save will also act as our return point from when * we resume as it saves its own register state, so use the return * code to differentiate return from save and return from sleep */ if (s3c2410_cpu_save(regs_save) == 0) { flush_cache_all(); pm_cpu_sleep(); } /* restore the cpu state */ cpu_init(); /* restore the system state */ s3c2410_pm_do_restore_core(core_save, ARRAY_SIZE(core_save)); s3c2410_pm_do_restore(misc_save, ARRAY_SIZE(misc_save)); s3c2410_pm_do_restore(uart_save, ARRAY_SIZE(uart_save)); s3c2410_pm_restore_gpios(); s3c2410_pm_debug_init(); /* check what irq (if any) restored the system */ DBG("post sleep: IRQs 0x%08x, 0x%08x\n", __raw_readl(S3C2410_SRCPND), __raw_readl(S3C2410_EINTPEND)); s3c2410_pm_show_resume_irqs(IRQ_EINT0, __raw_readl(S3C2410_SRCPND), s3c_irqwake_intmask); s3c2410_pm_show_resume_irqs(IRQ_EINT4-4, __raw_readl(S3C2410_EINTPEND), s3c_irqwake_eintmask); DBG("post sleep, preparing to return\n"); s3c2410_pm_check_restore(); /* ok, let's return from sleep */ DBG("S3C2410 PM Resume (post-restore)\n"); return 0; } static int s3c2410_pm_begin(suspend_state_t state) { int ret = 0; #ifdef CONFIG_REGULATOR ret = regulator_suspend_prepare(state); #endif return ret; } static struct platform_suspend_ops s3c2410_pm_ops = { .enter = s3c2410_pm_enter, .valid = suspend_valid_only_mem, .begin = s3c2410_pm_begin, }; /* s3c2410_pm_init * * Attach the power management functions. This should be called * from the board specific initialisation if the board supports * it. */ int __init s3c2410_pm_init(void) { printk("S3C2410 Power Management, (c) 2004 Simtec Electronics\n"); suspend_set_ops(&s3c2410_pm_ops); return 0; }