// SPDX-License-Identifier: GPL-2.0 /* * Copyright (C) 2020 SiFive, Inc. * Copyright (C) 2020 Zong Li */ #include #include #include #include "sifive-prci.h" #include "fu540-prci.h" #include "fu740-prci.h" /* * Private functions */ /** * __prci_readl() - read from a PRCI register * @pd: PRCI context * @offs: register offset to read from (in bytes, from PRCI base address) * * Read the register located at offset @offs from the base virtual * address of the PRCI register target described by @pd, and return * the value to the caller. * * Context: Any context. * * Return: the contents of the register described by @pd and @offs. */ static u32 __prci_readl(struct __prci_data *pd, u32 offs) { return readl_relaxed(pd->va + offs); } static void __prci_writel(u32 v, u32 offs, struct __prci_data *pd) { writel_relaxed(v, pd->va + offs); } /* WRPLL-related private functions */ /** * __prci_wrpll_unpack() - unpack WRPLL configuration registers into parameters * @c: ptr to a struct wrpll_cfg record to write config into * @r: value read from the PRCI PLL configuration register * * Given a value @r read from an FU740 PRCI PLL configuration register, * split it into fields and populate it into the WRPLL configuration record * pointed to by @c. * * The COREPLLCFG0 macros are used below, but the other *PLLCFG0 macros * have the same register layout. * * Context: Any context. */ static void __prci_wrpll_unpack(struct wrpll_cfg *c, u32 r) { u32 v; v = r & PRCI_COREPLLCFG0_DIVR_MASK; v >>= PRCI_COREPLLCFG0_DIVR_SHIFT; c->divr = v; v = r & PRCI_COREPLLCFG0_DIVF_MASK; v >>= PRCI_COREPLLCFG0_DIVF_SHIFT; c->divf = v; v = r & PRCI_COREPLLCFG0_DIVQ_MASK; v >>= PRCI_COREPLLCFG0_DIVQ_SHIFT; c->divq = v; v = r & PRCI_COREPLLCFG0_RANGE_MASK; v >>= PRCI_COREPLLCFG0_RANGE_SHIFT; c->range = v; c->flags &= (WRPLL_FLAGS_INT_FEEDBACK_MASK | WRPLL_FLAGS_EXT_FEEDBACK_MASK); /* external feedback mode not supported */ c->flags |= WRPLL_FLAGS_INT_FEEDBACK_MASK; } /** * __prci_wrpll_pack() - pack PLL configuration parameters into a register value * @c: pointer to a struct wrpll_cfg record containing the PLL's cfg * * Using a set of WRPLL configuration values pointed to by @c, * assemble a PRCI PLL configuration register value, and return it to * the caller. * * Context: Any context. Caller must ensure that the contents of the * record pointed to by @c do not change during the execution * of this function. * * Returns: a value suitable for writing into a PRCI PLL configuration * register */ static u32 __prci_wrpll_pack(const struct wrpll_cfg *c) { u32 r = 0; r |= c->divr << PRCI_COREPLLCFG0_DIVR_SHIFT; r |= c->divf << PRCI_COREPLLCFG0_DIVF_SHIFT; r |= c->divq << PRCI_COREPLLCFG0_DIVQ_SHIFT; r |= c->range << PRCI_COREPLLCFG0_RANGE_SHIFT; /* external feedback mode not supported */ r |= PRCI_COREPLLCFG0_FSE_MASK; return r; } /** * __prci_wrpll_read_cfg0() - read the WRPLL configuration from the PRCI * @pd: PRCI context * @pwd: PRCI WRPLL metadata * * Read the current configuration of the PLL identified by @pwd from * the PRCI identified by @pd, and store it into the local configuration * cache in @pwd. * * Context: Any context. Caller must prevent the records pointed to by * @pd and @pwd from changing during execution. */ static void __prci_wrpll_read_cfg0(struct __prci_data *pd, struct __prci_wrpll_data *pwd) { __prci_wrpll_unpack(&pwd->c, __prci_readl(pd, pwd->cfg0_offs)); } /** * __prci_wrpll_write_cfg0() - write WRPLL configuration into the PRCI * @pd: PRCI context * @pwd: PRCI WRPLL metadata * @c: WRPLL configuration record to write * * Write the WRPLL configuration described by @c into the WRPLL * configuration register identified by @pwd in the PRCI instance * described by @c. Make a cached copy of the WRPLL's current * configuration so it can be used by other code. * * Context: Any context. Caller must prevent the records pointed to by * @pd and @pwd from changing during execution. */ static void __prci_wrpll_write_cfg0(struct __prci_data *pd, struct __prci_wrpll_data *pwd, struct wrpll_cfg *c) { __prci_writel(__prci_wrpll_pack(c), pwd->cfg0_offs, pd); memcpy(&pwd->c, c, sizeof(*c)); } /** * __prci_wrpll_write_cfg1() - write Clock enable/disable configuration * into the PRCI * @pd: PRCI context * @pwd: PRCI WRPLL metadata * @enable: Clock enable or disable value */ static void __prci_wrpll_write_cfg1(struct __prci_data *pd, struct __prci_wrpll_data *pwd, u32 enable) { __prci_writel(enable, pwd->cfg1_offs, pd); } /* * Linux clock framework integration * * See the Linux clock framework documentation for more information on * these functions. */ unsigned long sifive_prci_wrpll_recalc_rate(struct clk_hw *hw, unsigned long parent_rate) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_wrpll_data *pwd = pc->pwd; return wrpll_calc_output_rate(&pwd->c, parent_rate); } long sifive_prci_wrpll_round_rate(struct clk_hw *hw, unsigned long rate, unsigned long *parent_rate) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_wrpll_data *pwd = pc->pwd; struct wrpll_cfg c; memcpy(&c, &pwd->c, sizeof(c)); wrpll_configure_for_rate(&c, rate, *parent_rate); return wrpll_calc_output_rate(&c, *parent_rate); } int sifive_prci_wrpll_set_rate(struct clk_hw *hw, unsigned long rate, unsigned long parent_rate) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_wrpll_data *pwd = pc->pwd; struct __prci_data *pd = pc->pd; int r; r = wrpll_configure_for_rate(&pwd->c, rate, parent_rate); if (r) return r; if (pwd->enable_bypass) pwd->enable_bypass(pd); __prci_wrpll_write_cfg0(pd, pwd, &pwd->c); udelay(wrpll_calc_max_lock_us(&pwd->c)); return 0; } int sifive_clk_is_enabled(struct clk_hw *hw) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_wrpll_data *pwd = pc->pwd; struct __prci_data *pd = pc->pd; u32 r; r = __prci_readl(pd, pwd->cfg1_offs); if (r & PRCI_COREPLLCFG1_CKE_MASK) return 1; else return 0; } int sifive_prci_clock_enable(struct clk_hw *hw) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_wrpll_data *pwd = pc->pwd; struct __prci_data *pd = pc->pd; if (sifive_clk_is_enabled(hw)) return 0; __prci_wrpll_write_cfg1(pd, pwd, PRCI_COREPLLCFG1_CKE_MASK); if (pwd->disable_bypass) pwd->disable_bypass(pd); return 0; } void sifive_prci_clock_disable(struct clk_hw *hw) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_wrpll_data *pwd = pc->pwd; struct __prci_data *pd = pc->pd; u32 r; if (pwd->enable_bypass) pwd->enable_bypass(pd); r = __prci_readl(pd, pwd->cfg1_offs); r &= ~PRCI_COREPLLCFG1_CKE_MASK; __prci_wrpll_write_cfg1(pd, pwd, r); } /* TLCLKSEL clock integration */ unsigned long sifive_prci_tlclksel_recalc_rate(struct clk_hw *hw, unsigned long parent_rate) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_data *pd = pc->pd; u32 v; u8 div; v = __prci_readl(pd, PRCI_CLKMUXSTATUSREG_OFFSET); v &= PRCI_CLKMUXSTATUSREG_TLCLKSEL_STATUS_MASK; div = v ? 1 : 2; return div_u64(parent_rate, div); } /* HFPCLK clock integration */ unsigned long sifive_prci_hfpclkplldiv_recalc_rate(struct clk_hw *hw, unsigned long parent_rate) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_data *pd = pc->pd; u32 div = __prci_readl(pd, PRCI_HFPCLKPLLDIV_OFFSET); return div_u64(parent_rate, div + 2); } /* * Core clock mux control */ /** * sifive_prci_coreclksel_use_hfclk() - switch the CORECLK mux to output HFCLK * @pd: struct __prci_data * for the PRCI containing the CORECLK mux reg * * Switch the CORECLK mux to the HFCLK input source; return once complete. * * Context: Any context. Caller must prevent concurrent changes to the * PRCI_CORECLKSEL_OFFSET register. */ void sifive_prci_coreclksel_use_hfclk(struct __prci_data *pd) { u32 r; r = __prci_readl(pd, PRCI_CORECLKSEL_OFFSET); r |= PRCI_CORECLKSEL_CORECLKSEL_MASK; __prci_writel(r, PRCI_CORECLKSEL_OFFSET, pd); r = __prci_readl(pd, PRCI_CORECLKSEL_OFFSET); /* barrier */ } /** * sifive_prci_coreclksel_use_corepll() - switch the CORECLK mux to output * COREPLL * @pd: struct __prci_data * for the PRCI containing the CORECLK mux reg * * Switch the CORECLK mux to the COREPLL output clock; return once complete. * * Context: Any context. Caller must prevent concurrent changes to the * PRCI_CORECLKSEL_OFFSET register. */ void sifive_prci_coreclksel_use_corepll(struct __prci_data *pd) { u32 r; r = __prci_readl(pd, PRCI_CORECLKSEL_OFFSET); r &= ~PRCI_CORECLKSEL_CORECLKSEL_MASK; __prci_writel(r, PRCI_CORECLKSEL_OFFSET, pd); r = __prci_readl(pd, PRCI_CORECLKSEL_OFFSET); /* barrier */ } /** * sifive_prci_coreclksel_use_final_corepll() - switch the CORECLK mux to output * FINAL_COREPLL * @pd: struct __prci_data * for the PRCI containing the CORECLK mux reg * * Switch the CORECLK mux to the final COREPLL output clock; return once * complete. * * Context: Any context. Caller must prevent concurrent changes to the * PRCI_CORECLKSEL_OFFSET register. */ void sifive_prci_coreclksel_use_final_corepll(struct __prci_data *pd) { u32 r; r = __prci_readl(pd, PRCI_CORECLKSEL_OFFSET); r &= ~PRCI_CORECLKSEL_CORECLKSEL_MASK; __prci_writel(r, PRCI_CORECLKSEL_OFFSET, pd); r = __prci_readl(pd, PRCI_CORECLKSEL_OFFSET); /* barrier */ } /** * sifive_prci_corepllsel_use_dvfscorepll() - switch the COREPLL mux to * output DVFS_COREPLL * @pd: struct __prci_data * for the PRCI containing the COREPLL mux reg * * Switch the COREPLL mux to the DVFSCOREPLL output clock; return once complete. * * Context: Any context. Caller must prevent concurrent changes to the * PRCI_COREPLLSEL_OFFSET register. */ void sifive_prci_corepllsel_use_dvfscorepll(struct __prci_data *pd) { u32 r; r = __prci_readl(pd, PRCI_COREPLLSEL_OFFSET); r |= PRCI_COREPLLSEL_COREPLLSEL_MASK; __prci_writel(r, PRCI_COREPLLSEL_OFFSET, pd); r = __prci_readl(pd, PRCI_COREPLLSEL_OFFSET); /* barrier */ } /** * sifive_prci_corepllsel_use_corepll() - switch the COREPLL mux to * output COREPLL * @pd: struct __prci_data * for the PRCI containing the COREPLL mux reg * * Switch the COREPLL mux to the COREPLL output clock; return once complete. * * Context: Any context. Caller must prevent concurrent changes to the * PRCI_COREPLLSEL_OFFSET register. */ void sifive_prci_corepllsel_use_corepll(struct __prci_data *pd) { u32 r; r = __prci_readl(pd, PRCI_COREPLLSEL_OFFSET); r &= ~PRCI_COREPLLSEL_COREPLLSEL_MASK; __prci_writel(r, PRCI_COREPLLSEL_OFFSET, pd); r = __prci_readl(pd, PRCI_COREPLLSEL_OFFSET); /* barrier */ } /** * sifive_prci_hfpclkpllsel_use_hfclk() - switch the HFPCLKPLL mux to * output HFCLK * @pd: struct __prci_data * for the PRCI containing the HFPCLKPLL mux reg * * Switch the HFPCLKPLL mux to the HFCLK input source; return once complete. * * Context: Any context. Caller must prevent concurrent changes to the * PRCI_HFPCLKPLLSEL_OFFSET register. */ void sifive_prci_hfpclkpllsel_use_hfclk(struct __prci_data *pd) { u32 r; r = __prci_readl(pd, PRCI_HFPCLKPLLSEL_OFFSET); r |= PRCI_HFPCLKPLLSEL_HFPCLKPLLSEL_MASK; __prci_writel(r, PRCI_HFPCLKPLLSEL_OFFSET, pd); r = __prci_readl(pd, PRCI_HFPCLKPLLSEL_OFFSET); /* barrier */ } /** * sifive_prci_hfpclkpllsel_use_hfpclkpll() - switch the HFPCLKPLL mux to * output HFPCLKPLL * @pd: struct __prci_data * for the PRCI containing the HFPCLKPLL mux reg * * Switch the HFPCLKPLL mux to the HFPCLKPLL output clock; return once complete. * * Context: Any context. Caller must prevent concurrent changes to the * PRCI_HFPCLKPLLSEL_OFFSET register. */ void sifive_prci_hfpclkpllsel_use_hfpclkpll(struct __prci_data *pd) { u32 r; r = __prci_readl(pd, PRCI_HFPCLKPLLSEL_OFFSET); r &= ~PRCI_HFPCLKPLLSEL_HFPCLKPLLSEL_MASK; __prci_writel(r, PRCI_HFPCLKPLLSEL_OFFSET, pd); r = __prci_readl(pd, PRCI_HFPCLKPLLSEL_OFFSET); /* barrier */ } /* PCIE AUX clock APIs for enable, disable. */ int sifive_prci_pcie_aux_clock_is_enabled(struct clk_hw *hw) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_data *pd = pc->pd; u32 r; r = __prci_readl(pd, PRCI_PCIE_AUX_OFFSET); if (r & PRCI_PCIE_AUX_EN_MASK) return 1; else return 0; } int sifive_prci_pcie_aux_clock_enable(struct clk_hw *hw) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_data *pd = pc->pd; u32 r __maybe_unused; if (sifive_prci_pcie_aux_clock_is_enabled(hw)) return 0; __prci_writel(1, PRCI_PCIE_AUX_OFFSET, pd); r = __prci_readl(pd, PRCI_PCIE_AUX_OFFSET); /* barrier */ return 0; } void sifive_prci_pcie_aux_clock_disable(struct clk_hw *hw) { struct __prci_clock *pc = clk_hw_to_prci_clock(hw); struct __prci_data *pd = pc->pd; u32 r __maybe_unused; __prci_writel(0, PRCI_PCIE_AUX_OFFSET, pd); r = __prci_readl(pd, PRCI_PCIE_AUX_OFFSET); /* barrier */ } /** * __prci_register_clocks() - register clock controls in the PRCI * @dev: Linux struct device * @pd: The pointer for PRCI per-device instance data * @desc: The pointer for the information of clocks of each SoCs * * Register the list of clock controls described in __prci_init_clocks[] with * the Linux clock framework. * * Return: 0 upon success or a negative error code upon failure. */ static int __prci_register_clocks(struct device *dev, struct __prci_data *pd, const struct prci_clk_desc *desc) { struct clk_init_data init = { }; struct __prci_clock *pic; int parent_count, i, r; parent_count = of_clk_get_parent_count(dev->of_node); if (parent_count != EXPECTED_CLK_PARENT_COUNT) { dev_err(dev, "expected only two parent clocks, found %d\n", parent_count); return -EINVAL; } /* Register PLLs */ for (i = 0; i < desc->num_clks; ++i) { pic = &(desc->clks[i]); init.name = pic->name; init.parent_names = &pic->parent_name; init.num_parents = 1; init.ops = pic->ops; pic->hw.init = &init; pic->pd = pd; if (pic->pwd) __prci_wrpll_read_cfg0(pd, pic->pwd); r = devm_clk_hw_register(dev, &pic->hw); if (r) { dev_warn(dev, "Failed to register clock %s: %d\n", init.name, r); return r; } pd->hw_clks.hws[i] = &pic->hw; } pd->hw_clks.num = i; r = devm_of_clk_add_hw_provider(dev, of_clk_hw_onecell_get, &pd->hw_clks); if (r) { dev_err(dev, "could not add hw_provider: %d\n", r); return r; } return 0; } /** * sifive_prci_probe() - initialize prci data and check parent count * @pdev: platform device pointer for the prci * * Return: 0 upon success or a negative error code upon failure. */ static int sifive_prci_probe(struct platform_device *pdev) { struct device *dev = &pdev->dev; struct __prci_data *pd; const struct prci_clk_desc *desc; int r; desc = of_device_get_match_data(&pdev->dev); pd = devm_kzalloc(dev, struct_size(pd, hw_clks.hws, desc->num_clks), GFP_KERNEL); if (!pd) return -ENOMEM; pd->va = devm_platform_ioremap_resource(pdev, 0); if (IS_ERR(pd->va)) return PTR_ERR(pd->va); pd->reset.rcdev.owner = THIS_MODULE; pd->reset.rcdev.nr_resets = PRCI_RST_NR; pd->reset.rcdev.ops = &reset_simple_ops; pd->reset.rcdev.of_node = pdev->dev.of_node; pd->reset.active_low = true; pd->reset.membase = pd->va + PRCI_DEVICESRESETREG_OFFSET; spin_lock_init(&pd->reset.lock); r = devm_reset_controller_register(&pdev->dev, &pd->reset.rcdev); if (r) { dev_err(dev, "could not register reset controller: %d\n", r); return r; } r = __prci_register_clocks(dev, pd, desc); if (r) { dev_err(dev, "could not register clocks: %d\n", r); return r; } dev_dbg(dev, "SiFive PRCI probed\n"); return 0; } static const struct of_device_id sifive_prci_of_match[] = { {.compatible = "sifive,fu540-c000-prci", .data = &prci_clk_fu540}, {.compatible = "sifive,fu740-c000-prci", .data = &prci_clk_fu740}, {} }; static struct platform_driver sifive_prci_driver = { .driver = { .name = "sifive-clk-prci", .of_match_table = sifive_prci_of_match, }, .probe = sifive_prci_probe, }; static int __init sifive_prci_init(void) { return platform_driver_register(&sifive_prci_driver); } core_initcall(sifive_prci_init);