/* * 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. * * Copyright (C) 2008 Maxime Bizon */ #include #include #include #include #include #include #include #include #include #include #include struct clk { void (*set)(struct clk *, int); unsigned int rate; unsigned int usage; int id; }; static DEFINE_MUTEX(clocks_mutex); static void clk_enable_unlocked(struct clk *clk) { if (clk->set && (clk->usage++) == 0) clk->set(clk, 1); } static void clk_disable_unlocked(struct clk *clk) { if (clk->set && (--clk->usage) == 0) clk->set(clk, 0); } static void bcm_hwclock_set(u32 mask, int enable) { u32 reg; reg = bcm_perf_readl(PERF_CKCTL_REG); if (enable) reg |= mask; else reg &= ~mask; bcm_perf_writel(reg, PERF_CKCTL_REG); } /* * Ethernet MAC "misc" clock: dma clocks and main clock on 6348 */ static void enet_misc_set(struct clk *clk, int enable) { u32 mask; if (BCMCPU_IS_6338()) mask = CKCTL_6338_ENET_EN; else if (BCMCPU_IS_6345()) mask = CKCTL_6345_ENET_EN; else if (BCMCPU_IS_6348()) mask = CKCTL_6348_ENET_EN; else /* BCMCPU_IS_6358 */ mask = CKCTL_6358_EMUSB_EN; bcm_hwclock_set(mask, enable); } static struct clk clk_enet_misc = { .set = enet_misc_set, }; /* * Ethernet MAC clocks: only revelant on 6358, silently enable misc * clocks */ static void enetx_set(struct clk *clk, int enable) { if (enable) clk_enable_unlocked(&clk_enet_misc); else clk_disable_unlocked(&clk_enet_misc); if (BCMCPU_IS_3368() || BCMCPU_IS_6358()) { u32 mask; if (clk->id == 0) mask = CKCTL_6358_ENET0_EN; else mask = CKCTL_6358_ENET1_EN; bcm_hwclock_set(mask, enable); } } static struct clk clk_enet0 = { .id = 0, .set = enetx_set, }; static struct clk clk_enet1 = { .id = 1, .set = enetx_set, }; /* * Ethernet PHY clock */ static void ephy_set(struct clk *clk, int enable) { if (BCMCPU_IS_3368() || BCMCPU_IS_6358()) bcm_hwclock_set(CKCTL_6358_EPHY_EN, enable); } static struct clk clk_ephy = { .set = ephy_set, }; /* * Ethernet switch clock */ static void enetsw_set(struct clk *clk, int enable) { if (BCMCPU_IS_6328()) bcm_hwclock_set(CKCTL_6328_ROBOSW_EN, enable); else if (BCMCPU_IS_6362()) bcm_hwclock_set(CKCTL_6362_ROBOSW_EN, enable); else if (BCMCPU_IS_6368()) bcm_hwclock_set(CKCTL_6368_ROBOSW_EN | CKCTL_6368_SWPKT_USB_EN | CKCTL_6368_SWPKT_SAR_EN, enable); else return; if (enable) { /* reset switch core afer clock change */ bcm63xx_core_set_reset(BCM63XX_RESET_ENETSW, 1); msleep(10); bcm63xx_core_set_reset(BCM63XX_RESET_ENETSW, 0); msleep(10); } } static struct clk clk_enetsw = { .set = enetsw_set, }; /* * PCM clock */ static void pcm_set(struct clk *clk, int enable) { if (BCMCPU_IS_3368()) bcm_hwclock_set(CKCTL_3368_PCM_EN, enable); if (BCMCPU_IS_6358()) bcm_hwclock_set(CKCTL_6358_PCM_EN, enable); } static struct clk clk_pcm = { .set = pcm_set, }; /* * USB host clock */ static void usbh_set(struct clk *clk, int enable) { if (BCMCPU_IS_6328()) bcm_hwclock_set(CKCTL_6328_USBH_EN, enable); else if (BCMCPU_IS_6348()) bcm_hwclock_set(CKCTL_6348_USBH_EN, enable); else if (BCMCPU_IS_6362()) bcm_hwclock_set(CKCTL_6362_USBH_EN, enable); else if (BCMCPU_IS_6368()) bcm_hwclock_set(CKCTL_6368_USBH_EN, enable); } static struct clk clk_usbh = { .set = usbh_set, }; /* * USB device clock */ static void usbd_set(struct clk *clk, int enable) { if (BCMCPU_IS_6328()) bcm_hwclock_set(CKCTL_6328_USBD_EN, enable); else if (BCMCPU_IS_6362()) bcm_hwclock_set(CKCTL_6362_USBD_EN, enable); else if (BCMCPU_IS_6368()) bcm_hwclock_set(CKCTL_6368_USBD_EN, enable); } static struct clk clk_usbd = { .set = usbd_set, }; /* * SPI clock */ static void spi_set(struct clk *clk, int enable) { u32 mask; if (BCMCPU_IS_6338()) mask = CKCTL_6338_SPI_EN; else if (BCMCPU_IS_6348()) mask = CKCTL_6348_SPI_EN; else if (BCMCPU_IS_3368() || BCMCPU_IS_6358()) mask = CKCTL_6358_SPI_EN; else if (BCMCPU_IS_6362()) mask = CKCTL_6362_SPI_EN; else /* BCMCPU_IS_6368 */ mask = CKCTL_6368_SPI_EN; bcm_hwclock_set(mask, enable); } static struct clk clk_spi = { .set = spi_set, }; /* * HSSPI clock */ static void hsspi_set(struct clk *clk, int enable) { u32 mask; if (BCMCPU_IS_6328()) mask = CKCTL_6328_HSSPI_EN; else if (BCMCPU_IS_6362()) mask = CKCTL_6362_HSSPI_EN; else return; bcm_hwclock_set(mask, enable); } static struct clk clk_hsspi = { .set = hsspi_set, }; /* * XTM clock */ static void xtm_set(struct clk *clk, int enable) { if (!BCMCPU_IS_6368()) return; bcm_hwclock_set(CKCTL_6368_SAR_EN | CKCTL_6368_SWPKT_SAR_EN, enable); if (enable) { /* reset sar core afer clock change */ bcm63xx_core_set_reset(BCM63XX_RESET_SAR, 1); mdelay(1); bcm63xx_core_set_reset(BCM63XX_RESET_SAR, 0); mdelay(1); } } static struct clk clk_xtm = { .set = xtm_set, }; /* * IPsec clock */ static void ipsec_set(struct clk *clk, int enable) { if (BCMCPU_IS_6362()) bcm_hwclock_set(CKCTL_6362_IPSEC_EN, enable); else if (BCMCPU_IS_6368()) bcm_hwclock_set(CKCTL_6368_IPSEC_EN, enable); } static struct clk clk_ipsec = { .set = ipsec_set, }; /* * PCIe clock */ static void pcie_set(struct clk *clk, int enable) { if (BCMCPU_IS_6328()) bcm_hwclock_set(CKCTL_6328_PCIE_EN, enable); else if (BCMCPU_IS_6362()) bcm_hwclock_set(CKCTL_6362_PCIE_EN, enable); } static struct clk clk_pcie = { .set = pcie_set, }; /* * Internal peripheral clock */ static struct clk clk_periph = { .rate = (50 * 1000 * 1000), }; /* * Linux clock API implementation */ int clk_enable(struct clk *clk) { mutex_lock(&clocks_mutex); clk_enable_unlocked(clk); mutex_unlock(&clocks_mutex); return 0; } EXPORT_SYMBOL(clk_enable); void clk_disable(struct clk *clk) { if (!clk) return; mutex_lock(&clocks_mutex); clk_disable_unlocked(clk); mutex_unlock(&clocks_mutex); } EXPORT_SYMBOL(clk_disable); unsigned long clk_get_rate(struct clk *clk) { if (!clk) return 0; return clk->rate; } EXPORT_SYMBOL(clk_get_rate); int clk_set_rate(struct clk *clk, unsigned long rate) { return 0; } EXPORT_SYMBOL_GPL(clk_set_rate); long clk_round_rate(struct clk *clk, unsigned long rate) { return 0; } EXPORT_SYMBOL_GPL(clk_round_rate); static struct clk_lookup bcm3368_clks[] = { /* fixed rate clocks */ CLKDEV_INIT(NULL, "periph", &clk_periph), CLKDEV_INIT("bcm63xx_uart.0", "refclk", &clk_periph), CLKDEV_INIT("bcm63xx_uart.1", "refclk", &clk_periph), /* gated clocks */ CLKDEV_INIT(NULL, "enet0", &clk_enet0), CLKDEV_INIT(NULL, "enet1", &clk_enet1), CLKDEV_INIT(NULL, "ephy", &clk_ephy), CLKDEV_INIT(NULL, "usbh", &clk_usbh), CLKDEV_INIT(NULL, "usbd", &clk_usbd), CLKDEV_INIT(NULL, "spi", &clk_spi), CLKDEV_INIT(NULL, "pcm", &clk_pcm), }; static struct clk_lookup bcm6328_clks[] = { /* fixed rate clocks */ CLKDEV_INIT(NULL, "periph", &clk_periph), CLKDEV_INIT("bcm63xx_uart.0", "refclk", &clk_periph), CLKDEV_INIT("bcm63xx_uart.1", "refclk", &clk_periph), /* gated clocks */ CLKDEV_INIT(NULL, "enetsw", &clk_enetsw), CLKDEV_INIT(NULL, "usbh", &clk_usbh), CLKDEV_INIT(NULL, "usbd", &clk_usbd), CLKDEV_INIT(NULL, "hsspi", &clk_hsspi), CLKDEV_INIT(NULL, "pcie", &clk_pcie), }; static struct clk_lookup bcm6338_clks[] = { /* fixed rate clocks */ CLKDEV_INIT(NULL, "periph", &clk_periph), CLKDEV_INIT("bcm63xx_uart.0", "refclk", &clk_periph), /* gated clocks */ CLKDEV_INIT(NULL, "enet0", &clk_enet0), CLKDEV_INIT(NULL, "enet1", &clk_enet1), CLKDEV_INIT(NULL, "ephy", &clk_ephy), CLKDEV_INIT(NULL, "usbh", &clk_usbh), CLKDEV_INIT(NULL, "usbd", &clk_usbd), CLKDEV_INIT(NULL, "spi", &clk_spi), }; static struct clk_lookup bcm6345_clks[] = { /* fixed rate clocks */ CLKDEV_INIT(NULL, "periph", &clk_periph), CLKDEV_INIT("bcm63xx_uart.0", "refclk", &clk_periph), /* gated clocks */ CLKDEV_INIT(NULL, "enet0", &clk_enet0), CLKDEV_INIT(NULL, "enet1", &clk_enet1), CLKDEV_INIT(NULL, "ephy", &clk_ephy), CLKDEV_INIT(NULL, "usbh", &clk_usbh), CLKDEV_INIT(NULL, "usbd", &clk_usbd), CLKDEV_INIT(NULL, "spi", &clk_spi), }; static struct clk_lookup bcm6348_clks[] = { /* fixed rate clocks */ CLKDEV_INIT(NULL, "periph", &clk_periph), CLKDEV_INIT("bcm63xx_uart.0", "refclk", &clk_periph), /* gated clocks */ CLKDEV_INIT(NULL, "enet0", &clk_enet0), CLKDEV_INIT(NULL, "enet1", &clk_enet1), CLKDEV_INIT(NULL, "ephy", &clk_ephy), CLKDEV_INIT(NULL, "usbh", &clk_usbh), CLKDEV_INIT(NULL, "usbd", &clk_usbd), CLKDEV_INIT(NULL, "spi", &clk_spi), }; static struct clk_lookup bcm6358_clks[] = { /* fixed rate clocks */ CLKDEV_INIT(NULL, "periph", &clk_periph), CLKDEV_INIT("bcm63xx_uart.0", "refclk", &clk_periph), CLKDEV_INIT("bcm63xx_uart.1", "refclk", &clk_periph), /* gated clocks */ CLKDEV_INIT(NULL, "enet0", &clk_enet0), CLKDEV_INIT(NULL, "enet1", &clk_enet1), CLKDEV_INIT(NULL, "ephy", &clk_ephy), CLKDEV_INIT(NULL, "usbh", &clk_usbh), CLKDEV_INIT(NULL, "usbd", &clk_usbd), CLKDEV_INIT(NULL, "spi", &clk_spi), CLKDEV_INIT(NULL, "pcm", &clk_pcm), }; static struct clk_lookup bcm6362_clks[] = { /* fixed rate clocks */ CLKDEV_INIT(NULL, "periph", &clk_periph), CLKDEV_INIT("bcm63xx_uart.0", "refclk", &clk_periph), CLKDEV_INIT("bcm63xx_uart.1", "refclk", &clk_periph), /* gated clocks */ CLKDEV_INIT(NULL, "enetsw", &clk_enetsw), CLKDEV_INIT(NULL, "usbh", &clk_usbh), CLKDEV_INIT(NULL, "usbd", &clk_usbd), CLKDEV_INIT(NULL, "spi", &clk_spi), CLKDEV_INIT(NULL, "hsspi", &clk_hsspi), CLKDEV_INIT(NULL, "pcie", &clk_pcie), CLKDEV_INIT(NULL, "ipsec", &clk_ipsec), }; static struct clk_lookup bcm6368_clks[] = { /* fixed rate clocks */ CLKDEV_INIT(NULL, "periph", &clk_periph), CLKDEV_INIT("bcm63xx_uart.0", "refclk", &clk_periph), CLKDEV_INIT("bcm63xx_uart.1", "refclk", &clk_periph), /* gated clocks */ CLKDEV_INIT(NULL, "enetsw", &clk_enetsw), CLKDEV_INIT(NULL, "usbh", &clk_usbh), CLKDEV_INIT(NULL, "usbd", &clk_usbd), CLKDEV_INIT(NULL, "spi", &clk_spi), CLKDEV_INIT(NULL, "xtm", &clk_xtm), CLKDEV_INIT(NULL, "ipsec", &clk_ipsec), }; #define HSSPI_PLL_HZ_6328 133333333 #define HSSPI_PLL_HZ_6362 400000000 static int __init bcm63xx_clk_init(void) { switch (bcm63xx_get_cpu_id()) { case BCM3368_CPU_ID: clkdev_add_table(bcm3368_clks, ARRAY_SIZE(bcm3368_clks)); break; case BCM6328_CPU_ID: clk_hsspi.rate = HSSPI_PLL_HZ_6328; clkdev_add_table(bcm6328_clks, ARRAY_SIZE(bcm6328_clks)); break; case BCM6338_CPU_ID: clkdev_add_table(bcm6338_clks, ARRAY_SIZE(bcm6338_clks)); break; case BCM6345_CPU_ID: clkdev_add_table(bcm6345_clks, ARRAY_SIZE(bcm6345_clks)); break; case BCM6348_CPU_ID: clkdev_add_table(bcm6348_clks, ARRAY_SIZE(bcm6348_clks)); break; case BCM6358_CPU_ID: clkdev_add_table(bcm6358_clks, ARRAY_SIZE(bcm6358_clks)); break; case BCM6362_CPU_ID: clk_hsspi.rate = HSSPI_PLL_HZ_6362; clkdev_add_table(bcm6362_clks, ARRAY_SIZE(bcm6362_clks)); break; case BCM6368_CPU_ID: clkdev_add_table(bcm6368_clks, ARRAY_SIZE(bcm6368_clks)); break; } return 0; } arch_initcall(bcm63xx_clk_init);