/* * Clk driver for NXP LPC18xx/LPC43xx Clock Generation Unit (CGU) * * Copyright (C) 2015 Joachim Eastwood * * This file is licensed under the terms of the GNU General Public * License version 2. This program is licensed "as is" without any * warranty of any kind, whether express or implied. */ #include #include #include #include #include #include #include /* Clock Generation Unit (CGU) registers */ #define LPC18XX_CGU_XTAL_OSC_CTRL 0x018 #define LPC18XX_CGU_PLL0USB_STAT 0x01c #define LPC18XX_CGU_PLL0USB_CTRL 0x020 #define LPC18XX_CGU_PLL0USB_MDIV 0x024 #define LPC18XX_CGU_PLL0USB_NP_DIV 0x028 #define LPC18XX_CGU_PLL0AUDIO_STAT 0x02c #define LPC18XX_CGU_PLL0AUDIO_CTRL 0x030 #define LPC18XX_CGU_PLL0AUDIO_MDIV 0x034 #define LPC18XX_CGU_PLL0AUDIO_NP_DIV 0x038 #define LPC18XX_CGU_PLL0AUDIO_FRAC 0x03c #define LPC18XX_CGU_PLL1_STAT 0x040 #define LPC18XX_CGU_PLL1_CTRL 0x044 #define LPC18XX_PLL1_CTRL_FBSEL BIT(6) #define LPC18XX_PLL1_CTRL_DIRECT BIT(7) #define LPC18XX_CGU_IDIV_CTRL(n) (0x048 + (n) * sizeof(u32)) #define LPC18XX_CGU_BASE_CLK(id) (0x05c + (id) * sizeof(u32)) #define LPC18XX_CGU_PLL_CTRL_OFFSET 0x4 /* PLL0 bits common to both audio and USB PLL */ #define LPC18XX_PLL0_STAT_LOCK BIT(0) #define LPC18XX_PLL0_CTRL_PD BIT(0) #define LPC18XX_PLL0_CTRL_BYPASS BIT(1) #define LPC18XX_PLL0_CTRL_DIRECTI BIT(2) #define LPC18XX_PLL0_CTRL_DIRECTO BIT(3) #define LPC18XX_PLL0_CTRL_CLKEN BIT(4) #define LPC18XX_PLL0_MDIV_MDEC_MASK 0x1ffff #define LPC18XX_PLL0_MDIV_SELP_SHIFT 17 #define LPC18XX_PLL0_MDIV_SELI_SHIFT 22 #define LPC18XX_PLL0_MSEL_MAX BIT(15) /* Register value that gives PLL0 post/pre dividers equal to 1 */ #define LPC18XX_PLL0_NP_DIVS_1 0x00302062 enum { CLK_SRC_OSC32, CLK_SRC_IRC, CLK_SRC_ENET_RX_CLK, CLK_SRC_ENET_TX_CLK, CLK_SRC_GP_CLKIN, CLK_SRC_RESERVED1, CLK_SRC_OSC, CLK_SRC_PLL0USB, CLK_SRC_PLL0AUDIO, CLK_SRC_PLL1, CLK_SRC_RESERVED2, CLK_SRC_RESERVED3, CLK_SRC_IDIVA, CLK_SRC_IDIVB, CLK_SRC_IDIVC, CLK_SRC_IDIVD, CLK_SRC_IDIVE, CLK_SRC_MAX }; static const char *clk_src_names[CLK_SRC_MAX] = { [CLK_SRC_OSC32] = "osc32", [CLK_SRC_IRC] = "irc", [CLK_SRC_ENET_RX_CLK] = "enet_rx_clk", [CLK_SRC_ENET_TX_CLK] = "enet_tx_clk", [CLK_SRC_GP_CLKIN] = "gp_clkin", [CLK_SRC_OSC] = "osc", [CLK_SRC_PLL0USB] = "pll0usb", [CLK_SRC_PLL0AUDIO] = "pll0audio", [CLK_SRC_PLL1] = "pll1", [CLK_SRC_IDIVA] = "idiva", [CLK_SRC_IDIVB] = "idivb", [CLK_SRC_IDIVC] = "idivc", [CLK_SRC_IDIVD] = "idivd", [CLK_SRC_IDIVE] = "idive", }; static const char *clk_base_names[BASE_CLK_MAX] = { [BASE_SAFE_CLK] = "base_safe_clk", [BASE_USB0_CLK] = "base_usb0_clk", [BASE_PERIPH_CLK] = "base_periph_clk", [BASE_USB1_CLK] = "base_usb1_clk", [BASE_CPU_CLK] = "base_cpu_clk", [BASE_SPIFI_CLK] = "base_spifi_clk", [BASE_SPI_CLK] = "base_spi_clk", [BASE_PHY_RX_CLK] = "base_phy_rx_clk", [BASE_PHY_TX_CLK] = "base_phy_tx_clk", [BASE_APB1_CLK] = "base_apb1_clk", [BASE_APB3_CLK] = "base_apb3_clk", [BASE_LCD_CLK] = "base_lcd_clk", [BASE_ADCHS_CLK] = "base_adchs_clk", [BASE_SDIO_CLK] = "base_sdio_clk", [BASE_SSP0_CLK] = "base_ssp0_clk", [BASE_SSP1_CLK] = "base_ssp1_clk", [BASE_UART0_CLK] = "base_uart0_clk", [BASE_UART1_CLK] = "base_uart1_clk", [BASE_UART2_CLK] = "base_uart2_clk", [BASE_UART3_CLK] = "base_uart3_clk", [BASE_OUT_CLK] = "base_out_clk", [BASE_AUDIO_CLK] = "base_audio_clk", [BASE_CGU_OUT0_CLK] = "base_cgu_out0_clk", [BASE_CGU_OUT1_CLK] = "base_cgu_out1_clk", }; static u32 lpc18xx_cgu_pll0_src_ids[] = { CLK_SRC_OSC32, CLK_SRC_IRC, CLK_SRC_ENET_RX_CLK, CLK_SRC_ENET_TX_CLK, CLK_SRC_GP_CLKIN, CLK_SRC_OSC, CLK_SRC_PLL1, CLK_SRC_IDIVA, CLK_SRC_IDIVB, CLK_SRC_IDIVC, CLK_SRC_IDIVD, CLK_SRC_IDIVE, }; static u32 lpc18xx_cgu_pll1_src_ids[] = { CLK_SRC_OSC32, CLK_SRC_IRC, CLK_SRC_ENET_RX_CLK, CLK_SRC_ENET_TX_CLK, CLK_SRC_GP_CLKIN, CLK_SRC_OSC, CLK_SRC_PLL0USB, CLK_SRC_PLL0AUDIO, CLK_SRC_IDIVA, CLK_SRC_IDIVB, CLK_SRC_IDIVC, CLK_SRC_IDIVD, CLK_SRC_IDIVE, }; static u32 lpc18xx_cgu_idiva_src_ids[] = { CLK_SRC_OSC32, CLK_SRC_IRC, CLK_SRC_ENET_RX_CLK, CLK_SRC_ENET_TX_CLK, CLK_SRC_GP_CLKIN, CLK_SRC_OSC, CLK_SRC_PLL0USB, CLK_SRC_PLL0AUDIO, CLK_SRC_PLL1 }; static u32 lpc18xx_cgu_idivbcde_src_ids[] = { CLK_SRC_OSC32, CLK_SRC_IRC, CLK_SRC_ENET_RX_CLK, CLK_SRC_ENET_TX_CLK, CLK_SRC_GP_CLKIN, CLK_SRC_OSC, CLK_SRC_PLL0AUDIO, CLK_SRC_PLL1, CLK_SRC_IDIVA, }; static u32 lpc18xx_cgu_base_irc_src_ids[] = {CLK_SRC_IRC}; static u32 lpc18xx_cgu_base_usb0_src_ids[] = {CLK_SRC_PLL0USB}; static u32 lpc18xx_cgu_base_common_src_ids[] = { CLK_SRC_OSC32, CLK_SRC_IRC, CLK_SRC_ENET_RX_CLK, CLK_SRC_ENET_TX_CLK, CLK_SRC_GP_CLKIN, CLK_SRC_OSC, CLK_SRC_PLL0AUDIO, CLK_SRC_PLL1, CLK_SRC_IDIVA, CLK_SRC_IDIVB, CLK_SRC_IDIVC, CLK_SRC_IDIVD, CLK_SRC_IDIVE, }; static u32 lpc18xx_cgu_base_all_src_ids[] = { CLK_SRC_OSC32, CLK_SRC_IRC, CLK_SRC_ENET_RX_CLK, CLK_SRC_ENET_TX_CLK, CLK_SRC_GP_CLKIN, CLK_SRC_OSC, CLK_SRC_PLL0USB, CLK_SRC_PLL0AUDIO, CLK_SRC_PLL1, CLK_SRC_IDIVA, CLK_SRC_IDIVB, CLK_SRC_IDIVC, CLK_SRC_IDIVD, CLK_SRC_IDIVE, }; struct lpc18xx_cgu_src_clk_div { u8 clk_id; u8 n_parents; struct clk_divider div; struct clk_mux mux; struct clk_gate gate; }; #define LPC1XX_CGU_SRC_CLK_DIV(_id, _width, _table) \ { \ .clk_id = CLK_SRC_ ##_id, \ .n_parents = ARRAY_SIZE(lpc18xx_cgu_ ##_table), \ .div = { \ .shift = 2, \ .width = _width, \ }, \ .mux = { \ .mask = 0x1f, \ .shift = 24, \ .table = lpc18xx_cgu_ ##_table, \ }, \ .gate = { \ .bit_idx = 0, \ .flags = CLK_GATE_SET_TO_DISABLE, \ }, \ } static struct lpc18xx_cgu_src_clk_div lpc18xx_cgu_src_clk_divs[] = { LPC1XX_CGU_SRC_CLK_DIV(IDIVA, 2, idiva_src_ids), LPC1XX_CGU_SRC_CLK_DIV(IDIVB, 4, idivbcde_src_ids), LPC1XX_CGU_SRC_CLK_DIV(IDIVC, 4, idivbcde_src_ids), LPC1XX_CGU_SRC_CLK_DIV(IDIVD, 4, idivbcde_src_ids), LPC1XX_CGU_SRC_CLK_DIV(IDIVE, 8, idivbcde_src_ids), }; struct lpc18xx_cgu_base_clk { u8 clk_id; u8 n_parents; struct clk_mux mux; struct clk_gate gate; }; #define LPC1XX_CGU_BASE_CLK(_id, _table, _flags) \ { \ .clk_id = BASE_ ##_id ##_CLK, \ .n_parents = ARRAY_SIZE(lpc18xx_cgu_ ##_table), \ .mux = { \ .mask = 0x1f, \ .shift = 24, \ .table = lpc18xx_cgu_ ##_table, \ .flags = _flags, \ }, \ .gate = { \ .bit_idx = 0, \ .flags = CLK_GATE_SET_TO_DISABLE, \ }, \ } static struct lpc18xx_cgu_base_clk lpc18xx_cgu_base_clks[] = { LPC1XX_CGU_BASE_CLK(SAFE, base_irc_src_ids, CLK_MUX_READ_ONLY), LPC1XX_CGU_BASE_CLK(USB0, base_usb0_src_ids, 0), LPC1XX_CGU_BASE_CLK(PERIPH, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(USB1, base_all_src_ids, 0), LPC1XX_CGU_BASE_CLK(CPU, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(SPIFI, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(SPI, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(PHY_RX, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(PHY_TX, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(APB1, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(APB3, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(LCD, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(ADCHS, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(SDIO, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(SSP0, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(SSP1, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(UART0, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(UART1, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(UART2, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(UART3, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(OUT, base_all_src_ids, 0), { /* 21 reserved */ }, { /* 22 reserved */ }, { /* 23 reserved */ }, { /* 24 reserved */ }, LPC1XX_CGU_BASE_CLK(AUDIO, base_common_src_ids, 0), LPC1XX_CGU_BASE_CLK(CGU_OUT0, base_all_src_ids, 0), LPC1XX_CGU_BASE_CLK(CGU_OUT1, base_all_src_ids, 0), }; struct lpc18xx_pll { struct clk_hw hw; void __iomem *reg; spinlock_t *lock; u8 flags; }; #define to_lpc_pll(hw) container_of(hw, struct lpc18xx_pll, hw) struct lpc18xx_cgu_pll_clk { u8 clk_id; u8 n_parents; u8 reg_offset; struct clk_mux mux; struct clk_gate gate; struct lpc18xx_pll pll; const struct clk_ops *pll_ops; }; #define LPC1XX_CGU_CLK_PLL(_id, _table, _pll_ops) \ { \ .clk_id = CLK_SRC_ ##_id, \ .n_parents = ARRAY_SIZE(lpc18xx_cgu_ ##_table), \ .reg_offset = LPC18XX_CGU_ ##_id ##_STAT, \ .mux = { \ .mask = 0x1f, \ .shift = 24, \ .table = lpc18xx_cgu_ ##_table, \ }, \ .gate = { \ .bit_idx = 0, \ .flags = CLK_GATE_SET_TO_DISABLE, \ }, \ .pll_ops = &lpc18xx_ ##_pll_ops, \ } /* * PLL0 uses a special register value encoding. The compute functions below * are taken or derived from the LPC1850 user manual (section 12.6.3.3). */ /* Compute PLL0 multiplier from decoded version */ static u32 lpc18xx_pll0_mdec2msel(u32 x) { int i; switch (x) { case 0x18003: return 1; case 0x10003: return 2; default: for (i = LPC18XX_PLL0_MSEL_MAX + 1; x != 0x4000 && i > 0; i--) x = ((x ^ x >> 14) & 1) | (x << 1 & 0x7fff); return i; } } /* Compute PLL0 decoded multiplier from binary version */ static u32 lpc18xx_pll0_msel2mdec(u32 msel) { u32 i, x = 0x4000; switch (msel) { case 0: return 0; case 1: return 0x18003; case 2: return 0x10003; default: for (i = msel; i <= LPC18XX_PLL0_MSEL_MAX; i++) x = ((x ^ x >> 1) & 1) << 14 | (x >> 1 & 0xffff); return x; } } /* Compute PLL0 bandwidth SELI reg from multiplier */ static u32 lpc18xx_pll0_msel2seli(u32 msel) { u32 tmp; if (msel > 16384) return 1; if (msel > 8192) return 2; if (msel > 2048) return 4; if (msel >= 501) return 8; if (msel >= 60) { tmp = 1024 / (msel + 9); return ((1024 == (tmp * (msel + 9))) == 0) ? tmp * 4 : (tmp + 1) * 4; } return (msel & 0x3c) + 4; } /* Compute PLL0 bandwidth SELP reg from multiplier */ static u32 lpc18xx_pll0_msel2selp(u32 msel) { if (msel < 60) return (msel >> 1) + 1; return 31; } static unsigned long lpc18xx_pll0_recalc_rate(struct clk_hw *hw, unsigned long parent_rate) { struct lpc18xx_pll *pll = to_lpc_pll(hw); u32 ctrl, mdiv, msel, npdiv; ctrl = readl(pll->reg + LPC18XX_CGU_PLL0USB_CTRL); mdiv = readl(pll->reg + LPC18XX_CGU_PLL0USB_MDIV); npdiv = readl(pll->reg + LPC18XX_CGU_PLL0USB_NP_DIV); if (ctrl & LPC18XX_PLL0_CTRL_BYPASS) return parent_rate; if (npdiv != LPC18XX_PLL0_NP_DIVS_1) { pr_warn("%s: pre/post dividers not supported\n", __func__); return 0; } msel = lpc18xx_pll0_mdec2msel(mdiv & LPC18XX_PLL0_MDIV_MDEC_MASK); if (msel) return 2 * msel * parent_rate; pr_warn("%s: unable to calculate rate\n", __func__); return 0; } static long lpc18xx_pll0_round_rate(struct clk_hw *hw, unsigned long rate, unsigned long *prate) { unsigned long m; if (*prate < rate) { pr_warn("%s: pll dividers not supported\n", __func__); return -EINVAL; } m = DIV_ROUND_UP_ULL(*prate, rate * 2); if (m <= 0 && m > LPC18XX_PLL0_MSEL_MAX) { pr_warn("%s: unable to support rate %lu\n", __func__, rate); return -EINVAL; } return 2 * *prate * m; } static int lpc18xx_pll0_set_rate(struct clk_hw *hw, unsigned long rate, unsigned long parent_rate) { struct lpc18xx_pll *pll = to_lpc_pll(hw); u32 ctrl, stat, m; int retry = 3; if (parent_rate < rate) { pr_warn("%s: pll dividers not supported\n", __func__); return -EINVAL; } m = DIV_ROUND_UP_ULL(parent_rate, rate * 2); if (m <= 0 && m > LPC18XX_PLL0_MSEL_MAX) { pr_warn("%s: unable to support rate %lu\n", __func__, rate); return -EINVAL; } m = lpc18xx_pll0_msel2mdec(m); m |= lpc18xx_pll0_msel2selp(m) << LPC18XX_PLL0_MDIV_SELP_SHIFT; m |= lpc18xx_pll0_msel2seli(m) << LPC18XX_PLL0_MDIV_SELI_SHIFT; /* Power down PLL, disable clk output and dividers */ ctrl = readl(pll->reg + LPC18XX_CGU_PLL0USB_CTRL); ctrl |= LPC18XX_PLL0_CTRL_PD; ctrl &= ~(LPC18XX_PLL0_CTRL_BYPASS | LPC18XX_PLL0_CTRL_DIRECTI | LPC18XX_PLL0_CTRL_DIRECTO | LPC18XX_PLL0_CTRL_CLKEN); writel(ctrl, pll->reg + LPC18XX_CGU_PLL0USB_CTRL); /* Configure new PLL settings */ writel(m, pll->reg + LPC18XX_CGU_PLL0USB_MDIV); writel(LPC18XX_PLL0_NP_DIVS_1, pll->reg + LPC18XX_CGU_PLL0USB_NP_DIV); /* Power up PLL and wait for lock */ ctrl &= ~LPC18XX_PLL0_CTRL_PD; writel(ctrl, pll->reg + LPC18XX_CGU_PLL0USB_CTRL); do { udelay(10); stat = readl(pll->reg + LPC18XX_CGU_PLL0USB_STAT); if (stat & LPC18XX_PLL0_STAT_LOCK) { ctrl |= LPC18XX_PLL0_CTRL_CLKEN; writel(ctrl, pll->reg + LPC18XX_CGU_PLL0USB_CTRL); return 0; } } while (retry--); pr_warn("%s: unable to lock pll\n", __func__); return -EINVAL; } static const struct clk_ops lpc18xx_pll0_ops = { .recalc_rate = lpc18xx_pll0_recalc_rate, .round_rate = lpc18xx_pll0_round_rate, .set_rate = lpc18xx_pll0_set_rate, }; static unsigned long lpc18xx_pll1_recalc_rate(struct clk_hw *hw, unsigned long parent_rate) { struct lpc18xx_pll *pll = to_lpc_pll(hw); u16 msel, nsel, psel; bool direct, fbsel; u32 ctrl; ctrl = readl(pll->reg + LPC18XX_CGU_PLL1_CTRL); direct = (ctrl & LPC18XX_PLL1_CTRL_DIRECT) ? true : false; fbsel = (ctrl & LPC18XX_PLL1_CTRL_FBSEL) ? true : false; msel = ((ctrl >> 16) & 0xff) + 1; nsel = ((ctrl >> 12) & 0x3) + 1; if (direct || fbsel) return msel * (parent_rate / nsel); psel = (ctrl >> 8) & 0x3; psel = 1 << psel; return (msel / (2 * psel)) * (parent_rate / nsel); } static const struct clk_ops lpc18xx_pll1_ops = { .recalc_rate = lpc18xx_pll1_recalc_rate, }; static int lpc18xx_cgu_gate_enable(struct clk_hw *hw) { return clk_gate_ops.enable(hw); } static void lpc18xx_cgu_gate_disable(struct clk_hw *hw) { clk_gate_ops.disable(hw); } static int lpc18xx_cgu_gate_is_enabled(struct clk_hw *hw) { const struct clk_hw *parent; /* * The consumer of base clocks needs know if the * base clock is really enabled before it can be * accessed. It is therefore necessary to verify * this all the way up. */ parent = clk_hw_get_parent(hw); if (!parent) return 0; if (!clk_hw_is_enabled(parent)) return 0; return clk_gate_ops.is_enabled(hw); } static const struct clk_ops lpc18xx_gate_ops = { .enable = lpc18xx_cgu_gate_enable, .disable = lpc18xx_cgu_gate_disable, .is_enabled = lpc18xx_cgu_gate_is_enabled, }; static struct lpc18xx_cgu_pll_clk lpc18xx_cgu_src_clk_plls[] = { LPC1XX_CGU_CLK_PLL(PLL0USB, pll0_src_ids, pll0_ops), LPC1XX_CGU_CLK_PLL(PLL0AUDIO, pll0_src_ids, pll0_ops), LPC1XX_CGU_CLK_PLL(PLL1, pll1_src_ids, pll1_ops), }; static void lpc18xx_fill_parent_names(const char **parent, const u32 *id, int size) { int i; for (i = 0; i < size; i++) parent[i] = clk_src_names[id[i]]; } static struct clk *lpc18xx_cgu_register_div(struct lpc18xx_cgu_src_clk_div *clk, void __iomem *base, int n) { void __iomem *reg = base + LPC18XX_CGU_IDIV_CTRL(n); const char *name = clk_src_names[clk->clk_id]; const char *parents[CLK_SRC_MAX]; clk->div.reg = reg; clk->mux.reg = reg; clk->gate.reg = reg; lpc18xx_fill_parent_names(parents, clk->mux.table, clk->n_parents); return clk_register_composite(NULL, name, parents, clk->n_parents, &clk->mux.hw, &clk_mux_ops, &clk->div.hw, &clk_divider_ops, &clk->gate.hw, &lpc18xx_gate_ops, 0); } static struct clk *lpc18xx_register_base_clk(struct lpc18xx_cgu_base_clk *clk, void __iomem *reg_base, int n) { void __iomem *reg = reg_base + LPC18XX_CGU_BASE_CLK(n); const char *name = clk_base_names[clk->clk_id]; const char *parents[CLK_SRC_MAX]; if (clk->n_parents == 0) return ERR_PTR(-ENOENT); clk->mux.reg = reg; clk->gate.reg = reg; lpc18xx_fill_parent_names(parents, clk->mux.table, clk->n_parents); /* SAFE_CLK can not be turned off */ if (n == BASE_SAFE_CLK) return clk_register_composite(NULL, name, parents, clk->n_parents, &clk->mux.hw, &clk_mux_ops, NULL, NULL, NULL, NULL, 0); return clk_register_composite(NULL, name, parents, clk->n_parents, &clk->mux.hw, &clk_mux_ops, NULL, NULL, &clk->gate.hw, &lpc18xx_gate_ops, 0); } static struct clk *lpc18xx_cgu_register_pll(struct lpc18xx_cgu_pll_clk *clk, void __iomem *base) { const char *name = clk_src_names[clk->clk_id]; const char *parents[CLK_SRC_MAX]; clk->pll.reg = base; clk->mux.reg = base + clk->reg_offset + LPC18XX_CGU_PLL_CTRL_OFFSET; clk->gate.reg = base + clk->reg_offset + LPC18XX_CGU_PLL_CTRL_OFFSET; lpc18xx_fill_parent_names(parents, clk->mux.table, clk->n_parents); return clk_register_composite(NULL, name, parents, clk->n_parents, &clk->mux.hw, &clk_mux_ops, &clk->pll.hw, clk->pll_ops, &clk->gate.hw, &lpc18xx_gate_ops, 0); } static void __init lpc18xx_cgu_register_source_clks(struct device_node *np, void __iomem *base) { const char *parents[CLK_SRC_MAX]; struct clk *clk; int i; /* Register the internal 12 MHz RC oscillator (IRC) */ clk = clk_register_fixed_rate(NULL, clk_src_names[CLK_SRC_IRC], NULL, 0, 12000000); if (IS_ERR(clk)) pr_warn("%s: failed to register irc clk\n", __func__); /* Register crystal oscillator controlller */ parents[0] = of_clk_get_parent_name(np, 0); clk = clk_register_gate(NULL, clk_src_names[CLK_SRC_OSC], parents[0], 0, base + LPC18XX_CGU_XTAL_OSC_CTRL, 0, CLK_GATE_SET_TO_DISABLE, NULL); if (IS_ERR(clk)) pr_warn("%s: failed to register osc clk\n", __func__); /* Register all PLLs */ for (i = 0; i < ARRAY_SIZE(lpc18xx_cgu_src_clk_plls); i++) { clk = lpc18xx_cgu_register_pll(&lpc18xx_cgu_src_clk_plls[i], base); if (IS_ERR(clk)) pr_warn("%s: failed to register pll (%d)\n", __func__, i); } /* Register all clock dividers A-E */ for (i = 0; i < ARRAY_SIZE(lpc18xx_cgu_src_clk_divs); i++) { clk = lpc18xx_cgu_register_div(&lpc18xx_cgu_src_clk_divs[i], base, i); if (IS_ERR(clk)) pr_warn("%s: failed to register div %d\n", __func__, i); } } static struct clk *clk_base[BASE_CLK_MAX]; static struct clk_onecell_data clk_base_data = { .clks = clk_base, .clk_num = BASE_CLK_MAX, }; static void __init lpc18xx_cgu_register_base_clks(void __iomem *reg_base) { int i; for (i = BASE_SAFE_CLK; i < BASE_CLK_MAX; i++) { clk_base[i] = lpc18xx_register_base_clk(&lpc18xx_cgu_base_clks[i], reg_base, i); if (IS_ERR(clk_base[i]) && PTR_ERR(clk_base[i]) != -ENOENT) pr_warn("%s: register base clk %d failed\n", __func__, i); } } static void __init lpc18xx_cgu_init(struct device_node *np) { void __iomem *reg_base; reg_base = of_iomap(np, 0); if (!reg_base) { pr_warn("%s: failed to map address range\n", __func__); return; } lpc18xx_cgu_register_source_clks(np, reg_base); lpc18xx_cgu_register_base_clks(reg_base); of_clk_add_provider(np, of_clk_src_onecell_get, &clk_base_data); } CLK_OF_DECLARE(lpc18xx_cgu, "nxp,lpc1850-cgu", lpc18xx_cgu_init);