Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Zhou Yanjie | 2440 | 99.23% | 5 | 71.43% |
Aidan MacDonald | 18 | 0.73% | 1 | 14.29% |
Paul Cercueil | 1 | 0.04% | 1 | 14.29% |
Total | 2459 | 7 |
// SPDX-License-Identifier: GPL-2.0 /* * X1000 SoC CGU driver * Copyright (c) 2019 周琰杰 (Zhou Yanjie) <zhouyanjie@wanyeetech.com> */ #include <linux/clk-provider.h> #include <linux/delay.h> #include <linux/io.h> #include <linux/of.h> #include <dt-bindings/clock/ingenic,x1000-cgu.h> #include "cgu.h" #include "pm.h" /* CGU register offsets */ #define CGU_REG_CPCCR 0x00 #define CGU_REG_APLL 0x10 #define CGU_REG_MPLL 0x14 #define CGU_REG_CLKGR 0x20 #define CGU_REG_OPCR 0x24 #define CGU_REG_DDRCDR 0x2c #define CGU_REG_USBPCR 0x3c #define CGU_REG_USBPCR1 0x48 #define CGU_REG_USBCDR 0x50 #define CGU_REG_MACCDR 0x54 #define CGU_REG_I2SCDR 0x60 #define CGU_REG_LPCDR 0x64 #define CGU_REG_MSC0CDR 0x68 #define CGU_REG_I2SCDR1 0x70 #define CGU_REG_SSICDR 0x74 #define CGU_REG_CIMCDR 0x7c #define CGU_REG_PCMCDR 0x84 #define CGU_REG_MSC1CDR 0xa4 #define CGU_REG_CMP_INTR 0xb0 #define CGU_REG_CMP_INTRE 0xb4 #define CGU_REG_DRCG 0xd0 #define CGU_REG_CPCSR 0xd4 #define CGU_REG_PCMCDR1 0xe0 #define CGU_REG_MACPHYC 0xe8 /* bits within the OPCR register */ #define OPCR_SPENDN0 BIT(7) #define OPCR_SPENDN1 BIT(6) /* bits within the USBPCR register */ #define USBPCR_SIDDQ BIT(21) #define USBPCR_OTG_DISABLE BIT(20) /* bits within the USBPCR1 register */ #define USBPCR1_REFCLKSEL_SHIFT 26 #define USBPCR1_REFCLKSEL_MASK (0x3 << USBPCR1_REFCLKSEL_SHIFT) #define USBPCR1_REFCLKSEL_CORE (0x2 << USBPCR1_REFCLKSEL_SHIFT) #define USBPCR1_REFCLKDIV_SHIFT 24 #define USBPCR1_REFCLKDIV_MASK (0x3 << USBPCR1_REFCLKDIV_SHIFT) #define USBPCR1_REFCLKDIV_48 (0x2 << USBPCR1_REFCLKDIV_SHIFT) #define USBPCR1_REFCLKDIV_24 (0x1 << USBPCR1_REFCLKDIV_SHIFT) #define USBPCR1_REFCLKDIV_12 (0x0 << USBPCR1_REFCLKDIV_SHIFT) static struct ingenic_cgu *cgu; static unsigned long x1000_otg_phy_recalc_rate(struct clk_hw *hw, unsigned long parent_rate) { u32 usbpcr1; unsigned refclk_div; usbpcr1 = readl(cgu->base + CGU_REG_USBPCR1); refclk_div = usbpcr1 & USBPCR1_REFCLKDIV_MASK; switch (refclk_div) { case USBPCR1_REFCLKDIV_12: return 12000000; case USBPCR1_REFCLKDIV_24: return 24000000; case USBPCR1_REFCLKDIV_48: return 48000000; } return parent_rate; } static long x1000_otg_phy_round_rate(struct clk_hw *hw, unsigned long req_rate, unsigned long *parent_rate) { if (req_rate < 18000000) return 12000000; if (req_rate < 36000000) return 24000000; return 48000000; } static int x1000_otg_phy_set_rate(struct clk_hw *hw, unsigned long req_rate, unsigned long parent_rate) { unsigned long flags; u32 usbpcr1, div_bits; switch (req_rate) { case 12000000: div_bits = USBPCR1_REFCLKDIV_12; break; case 24000000: div_bits = USBPCR1_REFCLKDIV_24; break; case 48000000: div_bits = USBPCR1_REFCLKDIV_48; break; default: return -EINVAL; } spin_lock_irqsave(&cgu->lock, flags); usbpcr1 = readl(cgu->base + CGU_REG_USBPCR1); usbpcr1 &= ~USBPCR1_REFCLKDIV_MASK; usbpcr1 |= div_bits; writel(usbpcr1, cgu->base + CGU_REG_USBPCR1); spin_unlock_irqrestore(&cgu->lock, flags); return 0; } static int x1000_usb_phy_enable(struct clk_hw *hw) { void __iomem *reg_opcr = cgu->base + CGU_REG_OPCR; void __iomem *reg_usbpcr = cgu->base + CGU_REG_USBPCR; writel(readl(reg_opcr) | OPCR_SPENDN0, reg_opcr); writel(readl(reg_usbpcr) & ~USBPCR_OTG_DISABLE & ~USBPCR_SIDDQ, reg_usbpcr); return 0; } static void x1000_usb_phy_disable(struct clk_hw *hw) { void __iomem *reg_opcr = cgu->base + CGU_REG_OPCR; void __iomem *reg_usbpcr = cgu->base + CGU_REG_USBPCR; writel(readl(reg_opcr) & ~OPCR_SPENDN0, reg_opcr); writel(readl(reg_usbpcr) | USBPCR_OTG_DISABLE | USBPCR_SIDDQ, reg_usbpcr); } static int x1000_usb_phy_is_enabled(struct clk_hw *hw) { void __iomem *reg_opcr = cgu->base + CGU_REG_OPCR; void __iomem *reg_usbpcr = cgu->base + CGU_REG_USBPCR; return (readl(reg_opcr) & OPCR_SPENDN0) && !(readl(reg_usbpcr) & USBPCR_SIDDQ) && !(readl(reg_usbpcr) & USBPCR_OTG_DISABLE); } static const struct clk_ops x1000_otg_phy_ops = { .recalc_rate = x1000_otg_phy_recalc_rate, .round_rate = x1000_otg_phy_round_rate, .set_rate = x1000_otg_phy_set_rate, .enable = x1000_usb_phy_enable, .disable = x1000_usb_phy_disable, .is_enabled = x1000_usb_phy_is_enabled, }; static const s8 pll_od_encoding[8] = { 0x0, 0x1, -1, 0x2, -1, -1, -1, 0x3, }; static const struct ingenic_cgu_clk_info x1000_cgu_clocks[] = { /* External clocks */ [X1000_CLK_EXCLK] = { "ext", CGU_CLK_EXT }, [X1000_CLK_RTCLK] = { "rtc", CGU_CLK_EXT }, /* PLLs */ [X1000_CLK_APLL] = { "apll", CGU_CLK_PLL, .parents = { X1000_CLK_EXCLK, -1, -1, -1 }, .pll = { .reg = CGU_REG_APLL, .rate_multiplier = 1, .m_shift = 24, .m_bits = 7, .m_offset = 1, .n_shift = 18, .n_bits = 5, .n_offset = 1, .od_shift = 16, .od_bits = 2, .od_max = 8, .od_encoding = pll_od_encoding, .bypass_reg = CGU_REG_APLL, .bypass_bit = 9, .enable_bit = 8, .stable_bit = 10, }, }, [X1000_CLK_MPLL] = { "mpll", CGU_CLK_PLL, .parents = { X1000_CLK_EXCLK, -1, -1, -1 }, .pll = { .reg = CGU_REG_MPLL, .rate_multiplier = 1, .m_shift = 24, .m_bits = 7, .m_offset = 1, .n_shift = 18, .n_bits = 5, .n_offset = 1, .od_shift = 16, .od_bits = 2, .od_max = 8, .od_encoding = pll_od_encoding, .bypass_reg = CGU_REG_MPLL, .bypass_bit = 6, .enable_bit = 7, .stable_bit = 0, }, }, /* Custom (SoC-specific) OTG PHY */ [X1000_CLK_OTGPHY] = { "otg_phy", CGU_CLK_CUSTOM, .parents = { -1, -1, X1000_CLK_EXCLK, -1 }, .custom = { &x1000_otg_phy_ops }, }, /* Muxes & dividers */ [X1000_CLK_SCLKA] = { "sclk_a", CGU_CLK_MUX, .parents = { -1, X1000_CLK_EXCLK, X1000_CLK_APLL, -1 }, .mux = { CGU_REG_CPCCR, 30, 2 }, }, [X1000_CLK_CPUMUX] = { "cpu_mux", CGU_CLK_MUX, .parents = { -1, X1000_CLK_SCLKA, X1000_CLK_MPLL, -1 }, .mux = { CGU_REG_CPCCR, 28, 2 }, }, [X1000_CLK_CPU] = { "cpu", CGU_CLK_DIV | CGU_CLK_GATE, /* * Disabling the CPU clock or any parent clocks will hang the * system; mark it critical. */ .flags = CLK_IS_CRITICAL, .parents = { X1000_CLK_CPUMUX, -1, -1, -1 }, .div = { CGU_REG_CPCCR, 0, 1, 4, 22, -1, -1 }, .gate = { CGU_REG_CLKGR, 30 }, }, [X1000_CLK_L2CACHE] = { "l2cache", CGU_CLK_DIV, /* * The L2 cache clock is critical if caches are enabled and * disabling it or any parent clocks will hang the system. */ .flags = CLK_IS_CRITICAL, .parents = { X1000_CLK_CPUMUX, -1, -1, -1 }, .div = { CGU_REG_CPCCR, 4, 1, 4, 22, -1, -1 }, }, [X1000_CLK_AHB0] = { "ahb0", CGU_CLK_MUX | CGU_CLK_DIV, .parents = { -1, X1000_CLK_SCLKA, X1000_CLK_MPLL, -1 }, .mux = { CGU_REG_CPCCR, 26, 2 }, .div = { CGU_REG_CPCCR, 8, 1, 4, 21, -1, -1 }, }, [X1000_CLK_AHB2PMUX] = { "ahb2_apb_mux", CGU_CLK_MUX, .parents = { -1, X1000_CLK_SCLKA, X1000_CLK_MPLL, -1 }, .mux = { CGU_REG_CPCCR, 24, 2 }, }, [X1000_CLK_AHB2] = { "ahb2", CGU_CLK_DIV, .parents = { X1000_CLK_AHB2PMUX, -1, -1, -1 }, .div = { CGU_REG_CPCCR, 12, 1, 4, 20, -1, -1 }, }, [X1000_CLK_PCLK] = { "pclk", CGU_CLK_DIV | CGU_CLK_GATE, .parents = { X1000_CLK_AHB2PMUX, -1, -1, -1 }, .div = { CGU_REG_CPCCR, 16, 1, 4, 20, -1, -1 }, .gate = { CGU_REG_CLKGR, 28 }, }, [X1000_CLK_DDR] = { "ddr", CGU_CLK_MUX | CGU_CLK_DIV | CGU_CLK_GATE, /* * Disabling DDR clock or its parents will render DRAM * inaccessible; mark it critical. */ .flags = CLK_IS_CRITICAL, .parents = { -1, X1000_CLK_SCLKA, X1000_CLK_MPLL, -1 }, .mux = { CGU_REG_DDRCDR, 30, 2 }, .div = { CGU_REG_DDRCDR, 0, 1, 4, 29, 28, 27 }, .gate = { CGU_REG_CLKGR, 31 }, }, [X1000_CLK_MAC] = { "mac", CGU_CLK_MUX | CGU_CLK_DIV | CGU_CLK_GATE, .parents = { X1000_CLK_SCLKA, X1000_CLK_MPLL }, .mux = { CGU_REG_MACCDR, 31, 1 }, .div = { CGU_REG_MACCDR, 0, 1, 8, 29, 28, 27 }, .gate = { CGU_REG_CLKGR, 25 }, }, [X1000_CLK_LCD] = { "lcd", CGU_CLK_MUX | CGU_CLK_DIV | CGU_CLK_GATE, .parents = { X1000_CLK_SCLKA, X1000_CLK_MPLL }, .mux = { CGU_REG_LPCDR, 31, 1 }, .div = { CGU_REG_LPCDR, 0, 1, 8, 28, 27, 26 }, .gate = { CGU_REG_CLKGR, 23 }, }, [X1000_CLK_MSCMUX] = { "msc_mux", CGU_CLK_MUX, .parents = { X1000_CLK_SCLKA, X1000_CLK_MPLL}, .mux = { CGU_REG_MSC0CDR, 31, 1 }, }, [X1000_CLK_MSC0] = { "msc0", CGU_CLK_DIV | CGU_CLK_GATE, .parents = { X1000_CLK_MSCMUX, -1, -1, -1 }, .div = { CGU_REG_MSC0CDR, 0, 2, 8, 29, 28, 27 }, .gate = { CGU_REG_CLKGR, 4 }, }, [X1000_CLK_MSC1] = { "msc1", CGU_CLK_DIV | CGU_CLK_GATE, .parents = { X1000_CLK_MSCMUX, -1, -1, -1 }, .div = { CGU_REG_MSC1CDR, 0, 2, 8, 29, 28, 27 }, .gate = { CGU_REG_CLKGR, 5 }, }, [X1000_CLK_OTG] = { "otg", CGU_CLK_DIV | CGU_CLK_GATE | CGU_CLK_MUX, .parents = { X1000_CLK_EXCLK, -1, X1000_CLK_APLL, X1000_CLK_MPLL }, .mux = { CGU_REG_USBCDR, 30, 2 }, .div = { CGU_REG_USBCDR, 0, 1, 8, 29, 28, 27 }, .gate = { CGU_REG_CLKGR, 3 }, }, [X1000_CLK_SSIPLL] = { "ssi_pll", CGU_CLK_MUX | CGU_CLK_DIV, .parents = { X1000_CLK_SCLKA, X1000_CLK_MPLL, -1, -1 }, .mux = { CGU_REG_SSICDR, 31, 1 }, .div = { CGU_REG_SSICDR, 0, 1, 8, 29, 28, 27 }, }, [X1000_CLK_SSIPLL_DIV2] = { "ssi_pll_div2", CGU_CLK_FIXDIV, .parents = { X1000_CLK_SSIPLL }, .fixdiv = { 2 }, }, [X1000_CLK_SSIMUX] = { "ssi_mux", CGU_CLK_MUX, .parents = { X1000_CLK_EXCLK, X1000_CLK_SSIPLL_DIV2, -1, -1 }, .mux = { CGU_REG_SSICDR, 30, 1 }, }, [X1000_CLK_EXCLK_DIV512] = { "exclk_div512", CGU_CLK_FIXDIV, .parents = { X1000_CLK_EXCLK }, .fixdiv = { 512 }, }, [X1000_CLK_RTC] = { "rtc_ercs", CGU_CLK_MUX | CGU_CLK_GATE, .parents = { X1000_CLK_EXCLK_DIV512, X1000_CLK_RTCLK }, .mux = { CGU_REG_OPCR, 2, 1}, .gate = { CGU_REG_CLKGR, 27 }, }, /* Gate-only clocks */ [X1000_CLK_EMC] = { "emc", CGU_CLK_GATE, .parents = { X1000_CLK_AHB2, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 0 }, }, [X1000_CLK_EFUSE] = { "efuse", CGU_CLK_GATE, .parents = { X1000_CLK_AHB2, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 1 }, }, [X1000_CLK_SFC] = { "sfc", CGU_CLK_GATE, .parents = { X1000_CLK_SSIPLL, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 2 }, }, [X1000_CLK_I2C0] = { "i2c0", CGU_CLK_GATE, .parents = { X1000_CLK_PCLK, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 7 }, }, [X1000_CLK_I2C1] = { "i2c1", CGU_CLK_GATE, .parents = { X1000_CLK_PCLK, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 8 }, }, [X1000_CLK_I2C2] = { "i2c2", CGU_CLK_GATE, .parents = { X1000_CLK_PCLK, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 9 }, }, [X1000_CLK_UART0] = { "uart0", CGU_CLK_GATE, .parents = { X1000_CLK_EXCLK, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 14 }, }, [X1000_CLK_UART1] = { "uart1", CGU_CLK_GATE, .parents = { X1000_CLK_EXCLK, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 15 }, }, [X1000_CLK_UART2] = { "uart2", CGU_CLK_GATE, .parents = { X1000_CLK_EXCLK, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 16 }, }, [X1000_CLK_TCU] = { "tcu", CGU_CLK_GATE, .parents = { X1000_CLK_EXCLK, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 18 }, }, [X1000_CLK_SSI] = { "ssi", CGU_CLK_GATE, .parents = { X1000_CLK_SSIMUX, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 19 }, }, [X1000_CLK_OST] = { "ost", CGU_CLK_GATE, .parents = { X1000_CLK_EXCLK, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 20 }, }, [X1000_CLK_PDMA] = { "pdma", CGU_CLK_GATE, .parents = { X1000_CLK_EXCLK, -1, -1, -1 }, .gate = { CGU_REG_CLKGR, 21 }, }, }; static void __init x1000_cgu_init(struct device_node *np) { int retval; cgu = ingenic_cgu_new(x1000_cgu_clocks, ARRAY_SIZE(x1000_cgu_clocks), np); if (!cgu) { pr_err("%s: failed to initialise CGU\n", __func__); return; } retval = ingenic_cgu_register_clocks(cgu); if (retval) { pr_err("%s: failed to register CGU Clocks\n", __func__); return; } ingenic_cgu_register_syscore_ops(cgu); } /* * CGU has some children devices, this is useful for probing children devices * in the case where the device node is compatible with "simple-mfd". */ CLK_OF_DECLARE_DRIVER(x1000_cgu, "ingenic,x1000-cgu", x1000_cgu_init);
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