// SPDX-License-Identifier: GPL-2.0-only /* * PLL clock driver for the Mobileye EyeQ5, EyeQ6L and EyeQ6H platforms. * * This controller handles: * - Read-only PLLs, all derived from the same main crystal clock. * - It also exposes divider clocks, those are children to PLLs. * - Fixed factor clocks, children to PLLs. * * Parent clock is expected to be constant. This driver's registers live in a * shared region called OLB. Some PLLs and fixed-factors are initialised early * by of_clk_init(); if so, two clk providers are registered. * * We use eqc_ as prefix, as-in "EyeQ Clock", but way shorter. * * Copyright (C) 2024 Mobileye Vision Technologies Ltd. */ /* * Set pr_fmt() for printing from eqc_early_init(). * It is called at of_clk_init() stage (read: really early). */ #define pr_fmt(fmt) "clk-eyeq: " fmt #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* In frac mode, it enables fractional noise canceling DAC. Else, no function. */ #define PCSR0_DAC_EN BIT(0) /* Fractional or integer mode */ #define PCSR0_DSM_EN BIT(1) #define PCSR0_PLL_EN BIT(2) /* All clocks output held at 0 */ #define PCSR0_FOUTPOSTDIV_EN BIT(3) #define PCSR0_POST_DIV1 GENMASK(6, 4) #define PCSR0_POST_DIV2 GENMASK(9, 7) #define PCSR0_REF_DIV GENMASK(15, 10) #define PCSR0_INTIN GENMASK(27, 16) #define PCSR0_BYPASS BIT(28) /* Bits 30..29 are reserved */ #define PCSR0_PLL_LOCKED BIT(31) #define PCSR1_RESET BIT(0) #define PCSR1_SSGC_DIV GENMASK(4, 1) /* Spread amplitude (% = 0.1 * SPREAD[4:0]) */ #define PCSR1_SPREAD GENMASK(9, 5) #define PCSR1_DIS_SSCG BIT(10) /* Down-spread or center-spread */ #define PCSR1_DOWN_SPREAD BIT(11) #define PCSR1_FRAC_IN GENMASK(31, 12) struct eqc_pll { unsigned int index; const char *name; unsigned int reg64; }; /* * Divider clock. Divider is 2*(v+1), with v the register value. * Min divider is 2, max is 2*(2^width). */ struct eqc_div { unsigned int index; const char *name; unsigned int parent; unsigned int reg; u8 shift; u8 width; }; struct eqc_fixed_factor { unsigned int index; const char *name; unsigned int mult; unsigned int div; unsigned int parent; }; struct eqc_match_data { unsigned int pll_count; const struct eqc_pll *plls; unsigned int div_count; const struct eqc_div *divs; unsigned int fixed_factor_count; const struct eqc_fixed_factor *fixed_factors; const char *reset_auxdev_name; const char *pinctrl_auxdev_name; unsigned int early_clk_count; }; struct eqc_early_match_data { unsigned int early_pll_count; const struct eqc_pll *early_plls; unsigned int early_fixed_factor_count; const struct eqc_fixed_factor *early_fixed_factors; /* * We want our of_xlate callback to EPROBE_DEFER instead of dev_err() * and EINVAL. For that, we must know the total clock count. */ unsigned int late_clk_count; }; /* * Both factors (mult and div) must fit in 32 bits. When an operation overflows, * this function throws away low bits so that factors still fit in 32 bits. * * Precision loss depends on amplitude of mult and div. Worst theorical * loss is: (UINT_MAX+1) / UINT_MAX - 1 = 2.3e-10. * This is 1Hz every 4.3GHz. */ static void eqc_pll_downshift_factors(unsigned long *mult, unsigned long *div) { unsigned long biggest; unsigned int shift; /* This function can be removed if mult/div switch to unsigned long. */ static_assert(sizeof_field(struct clk_fixed_factor, mult) == sizeof(unsigned int)); static_assert(sizeof_field(struct clk_fixed_factor, div) == sizeof(unsigned int)); /* No overflow, nothing to be done. */ if (*mult <= UINT_MAX && *div <= UINT_MAX) return; /* * Compute the shift required to bring the biggest factor into unsigned * int range. That is, shift its highest set bit to the unsigned int * most significant bit. */ biggest = max(*mult, *div); shift = __fls(biggest) - (BITS_PER_BYTE * sizeof(unsigned int)) + 1; *mult >>= shift; *div >>= shift; } static int eqc_pll_parse_registers(u32 r0, u32 r1, unsigned long *mult, unsigned long *div, unsigned long *acc) { u32 spread; if (r0 & PCSR0_BYPASS) { *mult = 1; *div = 1; *acc = 0; return 0; } if (!(r0 & PCSR0_PLL_LOCKED)) return -EINVAL; *mult = FIELD_GET(PCSR0_INTIN, r0); *div = FIELD_GET(PCSR0_REF_DIV, r0); if (r0 & PCSR0_FOUTPOSTDIV_EN) *div *= FIELD_GET(PCSR0_POST_DIV1, r0) * FIELD_GET(PCSR0_POST_DIV2, r0); /* Fractional mode, in 2^20 (0x100000) parts. */ if (r0 & PCSR0_DSM_EN) { *div *= (1ULL << 20); *mult = *mult * (1ULL << 20) + FIELD_GET(PCSR1_FRAC_IN, r1); } if (!*mult || !*div) return -EINVAL; if (r1 & (PCSR1_RESET | PCSR1_DIS_SSCG)) { *acc = 0; return 0; } /* * Spread spectrum. * * Spread is 1/1000 parts of frequency, accuracy is half of * that. To get accuracy, convert to ppb (parts per billion). * * acc = spread * 1e6 / 2 * with acc in parts per billion and, * spread in parts per thousand. */ spread = FIELD_GET(PCSR1_SPREAD, r1); *acc = spread * 500000; if (r1 & PCSR1_DOWN_SPREAD) { /* * Downspreading: the central frequency is half a * spread lower. */ *mult *= 2000 - spread; *div *= 2000; /* * Previous operation might overflow 32 bits. If it * does, throw away the least amount of low bits. */ eqc_pll_downshift_factors(mult, div); } return 0; } static void eqc_probe_init_plls(struct device *dev, const struct eqc_match_data *data, void __iomem *base, struct clk_hw_onecell_data *cells) { unsigned long mult, div, acc; const struct eqc_pll *pll; struct clk_hw *hw; unsigned int i; u32 r0, r1; u64 val; int ret; for (i = 0; i < data->pll_count; i++) { pll = &data->plls[i]; val = readq(base + pll->reg64); r0 = val; r1 = val >> 32; ret = eqc_pll_parse_registers(r0, r1, &mult, &div, &acc); if (ret) { dev_warn(dev, "failed parsing state of %s\n", pll->name); cells->hws[pll->index] = ERR_PTR(ret); continue; } hw = clk_hw_register_fixed_factor_with_accuracy_fwname(dev, dev->of_node, pll->name, "ref", 0, mult, div, acc); cells->hws[pll->index] = hw; if (IS_ERR(hw)) dev_warn(dev, "failed registering %s: %pe\n", pll->name, hw); } } static void eqc_probe_init_divs(struct device *dev, const struct eqc_match_data *data, void __iomem *base, struct clk_hw_onecell_data *cells) { struct clk_parent_data parent_data = { }; const struct eqc_div *div; struct clk_hw *parent; void __iomem *reg; struct clk_hw *hw; unsigned int i; for (i = 0; i < data->div_count; i++) { div = &data->divs[i]; reg = base + div->reg; parent = cells->hws[div->parent]; if (IS_ERR(parent)) { /* Parent is in early clk provider. */ parent_data.index = div->parent; parent_data.hw = NULL; } else { /* Avoid clock lookup when we already have the hw reference. */ parent_data.index = 0; parent_data.hw = parent; } hw = clk_hw_register_divider_table_parent_data(dev, div->name, &parent_data, 0, reg, div->shift, div->width, CLK_DIVIDER_EVEN_INTEGERS, NULL, NULL); cells->hws[div->index] = hw; if (IS_ERR(hw)) dev_warn(dev, "failed registering %s: %pe\n", div->name, hw); } } static void eqc_probe_init_fixed_factors(struct device *dev, const struct eqc_match_data *data, struct clk_hw_onecell_data *cells) { const struct eqc_fixed_factor *ff; struct clk_hw *hw, *parent_hw; unsigned int i; for (i = 0; i < data->fixed_factor_count; i++) { ff = &data->fixed_factors[i]; parent_hw = cells->hws[ff->parent]; if (IS_ERR(parent_hw)) { /* Parent is in early clk provider. */ hw = clk_hw_register_fixed_factor_index(dev, ff->name, ff->parent, 0, ff->mult, ff->div); } else { /* Avoid clock lookup when we already have the hw reference. */ hw = clk_hw_register_fixed_factor_parent_hw(dev, ff->name, parent_hw, 0, ff->mult, ff->div); } cells->hws[ff->index] = hw; if (IS_ERR(hw)) dev_warn(dev, "failed registering %s: %pe\n", ff->name, hw); } } static void eqc_auxdev_release(struct device *dev) { struct auxiliary_device *adev = to_auxiliary_dev(dev); kfree(adev); } static int eqc_auxdev_create(struct device *dev, void __iomem *base, const char *name, u32 id) { struct auxiliary_device *adev; int ret; adev = kzalloc(sizeof(*adev), GFP_KERNEL); if (!adev) return -ENOMEM; adev->name = name; adev->dev.parent = dev; adev->dev.platform_data = (void __force *)base; adev->dev.release = eqc_auxdev_release; adev->id = id; ret = auxiliary_device_init(adev); if (ret) return ret; ret = auxiliary_device_add(adev); if (ret) auxiliary_device_uninit(adev); return ret; } static int eqc_probe(struct platform_device *pdev) { struct device *dev = &pdev->dev; struct device_node *np = dev->of_node; const struct eqc_match_data *data; struct clk_hw_onecell_data *cells; unsigned int i, clk_count; struct resource *res; void __iomem *base; int ret; data = device_get_match_data(dev); if (!data) return 0; /* No clocks nor auxdevs, we are done. */ res = platform_get_resource(pdev, IORESOURCE_MEM, 0); if (!res) return -ENODEV; base = ioremap(res->start, resource_size(res)); if (!base) return -ENOMEM; /* Init optional reset auxiliary device. */ if (data->reset_auxdev_name) { ret = eqc_auxdev_create(dev, base, data->reset_auxdev_name, 0); if (ret) dev_warn(dev, "failed creating auxiliary device %s.%s: %d\n", KBUILD_MODNAME, data->reset_auxdev_name, ret); } /* Init optional pinctrl auxiliary device. */ if (data->pinctrl_auxdev_name) { ret = eqc_auxdev_create(dev, base, data->pinctrl_auxdev_name, 0); if (ret) dev_warn(dev, "failed creating auxiliary device %s.%s: %d\n", KBUILD_MODNAME, data->pinctrl_auxdev_name, ret); } if (data->pll_count + data->div_count + data->fixed_factor_count == 0) return 0; /* Zero clocks, we are done. */ clk_count = data->pll_count + data->div_count + data->fixed_factor_count + data->early_clk_count; cells = kzalloc(struct_size(cells, hws, clk_count), GFP_KERNEL); if (!cells) return -ENOMEM; cells->num = clk_count; /* Early PLLs are marked as errors: the early provider will get queried. */ for (i = 0; i < clk_count; i++) cells->hws[i] = ERR_PTR(-EINVAL); eqc_probe_init_plls(dev, data, base, cells); eqc_probe_init_divs(dev, data, base, cells); eqc_probe_init_fixed_factors(dev, data, cells); return of_clk_add_hw_provider(np, of_clk_hw_onecell_get, cells); } /* Required early for GIC timer (pll-cpu) and UARTs (pll-per). */ static const struct eqc_pll eqc_eyeq5_early_plls[] = { { .index = EQ5C_PLL_CPU, .name = "pll-cpu", .reg64 = 0x02C }, { .index = EQ5C_PLL_PER, .name = "pll-per", .reg64 = 0x05C }, }; static const struct eqc_pll eqc_eyeq5_plls[] = { { .index = EQ5C_PLL_VMP, .name = "pll-vmp", .reg64 = 0x034 }, { .index = EQ5C_PLL_PMA, .name = "pll-pma", .reg64 = 0x03C }, { .index = EQ5C_PLL_VDI, .name = "pll-vdi", .reg64 = 0x044 }, { .index = EQ5C_PLL_DDR0, .name = "pll-ddr0", .reg64 = 0x04C }, { .index = EQ5C_PLL_PCI, .name = "pll-pci", .reg64 = 0x054 }, { .index = EQ5C_PLL_PMAC, .name = "pll-pmac", .reg64 = 0x064 }, { .index = EQ5C_PLL_MPC, .name = "pll-mpc", .reg64 = 0x06C }, { .index = EQ5C_PLL_DDR1, .name = "pll-ddr1", .reg64 = 0x074 }, }; enum { /* * EQ5C_PLL_CPU children. * EQ5C_PER_OCC_PCI is the last clock exposed in dt-bindings. */ EQ5C_CPU_OCC = EQ5C_PER_OCC_PCI + 1, EQ5C_CPU_SI_CSS0, EQ5C_CPU_CPC, EQ5C_CPU_CM, EQ5C_CPU_MEM, EQ5C_CPU_OCC_ISRAM, EQ5C_CPU_ISRAM, EQ5C_CPU_OCC_DBU, EQ5C_CPU_SI_DBU_TP, /* * EQ5C_PLL_VDI children. */ EQ5C_VDI_OCC_VDI, EQ5C_VDI_VDI, EQ5C_VDI_OCC_CAN_SER, EQ5C_VDI_CAN_SER, EQ5C_VDI_I2C_SER, /* * EQ5C_PLL_PER children. */ EQ5C_PER_PERIPH, EQ5C_PER_CAN, EQ5C_PER_TIMER, EQ5C_PER_CCF, EQ5C_PER_OCC_MJPEG, EQ5C_PER_HSM, EQ5C_PER_MJPEG, EQ5C_PER_FCMU_A, }; static const struct eqc_fixed_factor eqc_eyeq5_early_fixed_factors[] = { /* EQ5C_PLL_CPU children */ { EQ5C_CPU_OCC, "occ-cpu", 1, 1, EQ5C_PLL_CPU }, { EQ5C_CPU_SI_CSS0, "si-css0", 1, 1, EQ5C_CPU_OCC }, { EQ5C_CPU_CORE0, "core0", 1, 1, EQ5C_CPU_SI_CSS0 }, { EQ5C_CPU_CORE1, "core1", 1, 1, EQ5C_CPU_SI_CSS0 }, { EQ5C_CPU_CORE2, "core2", 1, 1, EQ5C_CPU_SI_CSS0 }, { EQ5C_CPU_CORE3, "core3", 1, 1, EQ5C_CPU_SI_CSS0 }, /* EQ5C_PLL_PER children */ { EQ5C_PER_OCC, "occ-periph", 1, 16, EQ5C_PLL_PER }, { EQ5C_PER_UART, "uart", 1, 1, EQ5C_PER_OCC }, }; static const struct eqc_fixed_factor eqc_eyeq5_fixed_factors[] = { /* EQ5C_PLL_CPU children */ { EQ5C_CPU_CPC, "cpc", 1, 1, EQ5C_CPU_SI_CSS0 }, { EQ5C_CPU_CM, "cm", 1, 1, EQ5C_CPU_SI_CSS0 }, { EQ5C_CPU_MEM, "mem", 1, 1, EQ5C_CPU_SI_CSS0 }, { EQ5C_CPU_OCC_ISRAM, "occ-isram", 1, 2, EQ5C_PLL_CPU }, { EQ5C_CPU_ISRAM, "isram", 1, 1, EQ5C_CPU_OCC_ISRAM }, { EQ5C_CPU_OCC_DBU, "occ-dbu", 1, 10, EQ5C_PLL_CPU }, { EQ5C_CPU_SI_DBU_TP, "si-dbu-tp", 1, 1, EQ5C_CPU_OCC_DBU }, /* EQ5C_PLL_VDI children */ { EQ5C_VDI_OCC_VDI, "occ-vdi", 1, 2, EQ5C_PLL_VDI }, { EQ5C_VDI_VDI, "vdi", 1, 1, EQ5C_VDI_OCC_VDI }, { EQ5C_VDI_OCC_CAN_SER, "occ-can-ser", 1, 16, EQ5C_PLL_VDI }, { EQ5C_VDI_CAN_SER, "can-ser", 1, 1, EQ5C_VDI_OCC_CAN_SER }, { EQ5C_VDI_I2C_SER, "i2c-ser", 1, 20, EQ5C_PLL_VDI }, /* EQ5C_PLL_PER children */ { EQ5C_PER_PERIPH, "periph", 1, 1, EQ5C_PER_OCC }, { EQ5C_PER_CAN, "can", 1, 1, EQ5C_PER_OCC }, { EQ5C_PER_SPI, "spi", 1, 1, EQ5C_PER_OCC }, { EQ5C_PER_I2C, "i2c", 1, 1, EQ5C_PER_OCC }, { EQ5C_PER_TIMER, "timer", 1, 1, EQ5C_PER_OCC }, { EQ5C_PER_GPIO, "gpio", 1, 1, EQ5C_PER_OCC }, { EQ5C_PER_EMMC, "emmc-sys", 1, 10, EQ5C_PLL_PER }, { EQ5C_PER_CCF, "ccf-ctrl", 1, 4, EQ5C_PLL_PER }, { EQ5C_PER_OCC_MJPEG, "occ-mjpeg", 1, 2, EQ5C_PLL_PER }, { EQ5C_PER_HSM, "hsm", 1, 1, EQ5C_PER_OCC_MJPEG }, { EQ5C_PER_MJPEG, "mjpeg", 1, 1, EQ5C_PER_OCC_MJPEG }, { EQ5C_PER_FCMU_A, "fcmu-a", 1, 20, EQ5C_PLL_PER }, { EQ5C_PER_OCC_PCI, "occ-pci-sys", 1, 8, EQ5C_PLL_PER }, }; static const struct eqc_div eqc_eyeq5_divs[] = { { .index = EQ5C_DIV_OSPI, .name = "div-ospi", .parent = EQ5C_PLL_PER, .reg = 0x11C, .shift = 0, .width = 4, }, }; static const struct eqc_early_match_data eqc_eyeq5_early_match_data __initconst = { .early_pll_count = ARRAY_SIZE(eqc_eyeq5_early_plls), .early_plls = eqc_eyeq5_early_plls, .early_fixed_factor_count = ARRAY_SIZE(eqc_eyeq5_early_fixed_factors), .early_fixed_factors = eqc_eyeq5_early_fixed_factors, .late_clk_count = ARRAY_SIZE(eqc_eyeq5_plls) + ARRAY_SIZE(eqc_eyeq5_divs) + ARRAY_SIZE(eqc_eyeq5_fixed_factors), }; static const struct eqc_match_data eqc_eyeq5_match_data = { .pll_count = ARRAY_SIZE(eqc_eyeq5_plls), .plls = eqc_eyeq5_plls, .div_count = ARRAY_SIZE(eqc_eyeq5_divs), .divs = eqc_eyeq5_divs, .fixed_factor_count = ARRAY_SIZE(eqc_eyeq5_fixed_factors), .fixed_factors = eqc_eyeq5_fixed_factors, .reset_auxdev_name = "reset", .pinctrl_auxdev_name = "pinctrl", .early_clk_count = ARRAY_SIZE(eqc_eyeq5_early_plls) + ARRAY_SIZE(eqc_eyeq5_early_fixed_factors), }; static const struct eqc_pll eqc_eyeq6l_plls[] = { { .index = EQ6LC_PLL_DDR, .name = "pll-ddr", .reg64 = 0x02C }, { .index = EQ6LC_PLL_CPU, .name = "pll-cpu", .reg64 = 0x034 }, /* also acc */ { .index = EQ6LC_PLL_PER, .name = "pll-per", .reg64 = 0x03C }, { .index = EQ6LC_PLL_VDI, .name = "pll-vdi", .reg64 = 0x044 }, }; static const struct eqc_match_data eqc_eyeq6l_match_data = { .pll_count = ARRAY_SIZE(eqc_eyeq6l_plls), .plls = eqc_eyeq6l_plls, .reset_auxdev_name = "reset", }; static const struct eqc_match_data eqc_eyeq6h_west_match_data = { .reset_auxdev_name = "reset_west", }; static const struct eqc_pll eqc_eyeq6h_east_plls[] = { { .index = 0, .name = "pll-east", .reg64 = 0x074 }, }; static const struct eqc_match_data eqc_eyeq6h_east_match_data = { .pll_count = ARRAY_SIZE(eqc_eyeq6h_east_plls), .plls = eqc_eyeq6h_east_plls, .reset_auxdev_name = "reset_east", }; static const struct eqc_pll eqc_eyeq6h_south_plls[] = { { .index = EQ6HC_SOUTH_PLL_VDI, .name = "pll-vdi", .reg64 = 0x000 }, { .index = EQ6HC_SOUTH_PLL_PCIE, .name = "pll-pcie", .reg64 = 0x008 }, { .index = EQ6HC_SOUTH_PLL_PER, .name = "pll-per", .reg64 = 0x010 }, { .index = EQ6HC_SOUTH_PLL_ISP, .name = "pll-isp", .reg64 = 0x018 }, }; static const struct eqc_div eqc_eyeq6h_south_divs[] = { { .index = EQ6HC_SOUTH_DIV_EMMC, .name = "div-emmc", .parent = EQ6HC_SOUTH_PLL_PER, .reg = 0x070, .shift = 4, .width = 4, }, { .index = EQ6HC_SOUTH_DIV_OSPI_REF, .name = "div-ospi-ref", .parent = EQ6HC_SOUTH_PLL_PER, .reg = 0x090, .shift = 4, .width = 4, }, { .index = EQ6HC_SOUTH_DIV_OSPI_SYS, .name = "div-ospi-sys", .parent = EQ6HC_SOUTH_PLL_PER, .reg = 0x090, .shift = 8, .width = 1, }, { .index = EQ6HC_SOUTH_DIV_TSU, .name = "div-tsu", .parent = EQ6HC_SOUTH_PLL_PCIE, .reg = 0x098, .shift = 4, .width = 8, }, }; static const struct eqc_match_data eqc_eyeq6h_south_match_data = { .pll_count = ARRAY_SIZE(eqc_eyeq6h_south_plls), .plls = eqc_eyeq6h_south_plls, .div_count = ARRAY_SIZE(eqc_eyeq6h_south_divs), .divs = eqc_eyeq6h_south_divs, }; static const struct eqc_pll eqc_eyeq6h_ddr0_plls[] = { { .index = 0, .name = "pll-ddr0", .reg64 = 0x074 }, }; static const struct eqc_match_data eqc_eyeq6h_ddr0_match_data = { .pll_count = ARRAY_SIZE(eqc_eyeq6h_ddr0_plls), .plls = eqc_eyeq6h_ddr0_plls, }; static const struct eqc_pll eqc_eyeq6h_ddr1_plls[] = { { .index = 0, .name = "pll-ddr1", .reg64 = 0x074 }, }; static const struct eqc_match_data eqc_eyeq6h_ddr1_match_data = { .pll_count = ARRAY_SIZE(eqc_eyeq6h_ddr1_plls), .plls = eqc_eyeq6h_ddr1_plls, }; static const struct eqc_pll eqc_eyeq6h_acc_plls[] = { { .index = EQ6HC_ACC_PLL_XNN, .name = "pll-xnn", .reg64 = 0x040 }, { .index = EQ6HC_ACC_PLL_VMP, .name = "pll-vmp", .reg64 = 0x050 }, { .index = EQ6HC_ACC_PLL_PMA, .name = "pll-pma", .reg64 = 0x05C }, { .index = EQ6HC_ACC_PLL_MPC, .name = "pll-mpc", .reg64 = 0x068 }, { .index = EQ6HC_ACC_PLL_NOC, .name = "pll-noc", .reg64 = 0x070 }, }; static const struct eqc_match_data eqc_eyeq6h_acc_match_data = { .pll_count = ARRAY_SIZE(eqc_eyeq6h_acc_plls), .plls = eqc_eyeq6h_acc_plls, .reset_auxdev_name = "reset_acc", }; static const struct of_device_id eqc_match_table[] = { { .compatible = "mobileye,eyeq5-olb", .data = &eqc_eyeq5_match_data }, { .compatible = "mobileye,eyeq6l-olb", .data = &eqc_eyeq6l_match_data }, { .compatible = "mobileye,eyeq6h-west-olb", .data = &eqc_eyeq6h_west_match_data }, { .compatible = "mobileye,eyeq6h-east-olb", .data = &eqc_eyeq6h_east_match_data }, { .compatible = "mobileye,eyeq6h-south-olb", .data = &eqc_eyeq6h_south_match_data }, { .compatible = "mobileye,eyeq6h-ddr0-olb", .data = &eqc_eyeq6h_ddr0_match_data }, { .compatible = "mobileye,eyeq6h-ddr1-olb", .data = &eqc_eyeq6h_ddr1_match_data }, { .compatible = "mobileye,eyeq6h-acc-olb", .data = &eqc_eyeq6h_acc_match_data }, {} }; static struct platform_driver eqc_driver = { .probe = eqc_probe, .driver = { .name = "clk-eyeq", .of_match_table = eqc_match_table, .suppress_bind_attrs = true, }, }; builtin_platform_driver(eqc_driver); /* Required early for GIC timer. */ static const struct eqc_pll eqc_eyeq6h_central_early_plls[] = { { .index = EQ6HC_CENTRAL_PLL_CPU, .name = "pll-cpu", .reg64 = 0x02C }, }; static const struct eqc_fixed_factor eqc_eyeq6h_central_early_fixed_factors[] = { { EQ6HC_CENTRAL_CPU_OCC, "occ-cpu", 1, 1, EQ6HC_CENTRAL_PLL_CPU }, }; static const struct eqc_early_match_data eqc_eyeq6h_central_early_match_data __initconst = { .early_pll_count = ARRAY_SIZE(eqc_eyeq6h_central_early_plls), .early_plls = eqc_eyeq6h_central_early_plls, .early_fixed_factor_count = ARRAY_SIZE(eqc_eyeq6h_central_early_fixed_factors), .early_fixed_factors = eqc_eyeq6h_central_early_fixed_factors, }; /* Required early for UART. */ static const struct eqc_pll eqc_eyeq6h_west_early_plls[] = { { .index = EQ6HC_WEST_PLL_PER, .name = "pll-west", .reg64 = 0x074 }, }; static const struct eqc_fixed_factor eqc_eyeq6h_west_early_fixed_factors[] = { { EQ6HC_WEST_PER_OCC, "west-per-occ", 1, 10, EQ6HC_WEST_PLL_PER }, { EQ6HC_WEST_PER_UART, "west-per-uart", 1, 1, EQ6HC_WEST_PER_OCC }, }; static const struct eqc_early_match_data eqc_eyeq6h_west_early_match_data __initconst = { .early_pll_count = ARRAY_SIZE(eqc_eyeq6h_west_early_plls), .early_plls = eqc_eyeq6h_west_early_plls, .early_fixed_factor_count = ARRAY_SIZE(eqc_eyeq6h_west_early_fixed_factors), .early_fixed_factors = eqc_eyeq6h_west_early_fixed_factors, }; static void __init eqc_early_init(struct device_node *np, const struct eqc_early_match_data *early_data) { struct clk_hw_onecell_data *cells; unsigned int i, clk_count; void __iomem *base; int ret; clk_count = early_data->early_pll_count + early_data->early_fixed_factor_count + early_data->late_clk_count; cells = kzalloc(struct_size(cells, hws, clk_count), GFP_KERNEL); if (!cells) { ret = -ENOMEM; goto err; } cells->num = clk_count; /* * Mark all clocks as deferred; some are registered here, the rest at * platform device probe. * * Once the platform device is probed, its provider will take priority * when looking up clocks. */ for (i = 0; i < clk_count; i++) cells->hws[i] = ERR_PTR(-EPROBE_DEFER); /* Offsets (reg64) of early PLLs are relative to OLB block. */ base = of_iomap(np, 0); if (!base) { ret = -ENODEV; goto err; } for (i = 0; i < early_data->early_pll_count; i++) { const struct eqc_pll *pll = &early_data->early_plls[i]; unsigned long mult, div, acc; struct clk_hw *hw; u32 r0, r1; u64 val; val = readq(base + pll->reg64); r0 = val; r1 = val >> 32; ret = eqc_pll_parse_registers(r0, r1, &mult, &div, &acc); if (ret) { pr_err("failed parsing state of %s\n", pll->name); goto err; } hw = clk_hw_register_fixed_factor_with_accuracy_fwname(NULL, np, pll->name, "ref", 0, mult, div, acc); cells->hws[pll->index] = hw; if (IS_ERR(hw)) { pr_err("failed registering %s: %pe\n", pll->name, hw); ret = PTR_ERR(hw); goto err; } } for (i = 0; i < early_data->early_fixed_factor_count; i++) { const struct eqc_fixed_factor *ff = &early_data->early_fixed_factors[i]; struct clk_hw *parent_hw = cells->hws[ff->parent]; struct clk_hw *hw; hw = clk_hw_register_fixed_factor_parent_hw(NULL, ff->name, parent_hw, 0, ff->mult, ff->div); cells->hws[ff->index] = hw; if (IS_ERR(hw)) { pr_err("failed registering %s: %pe\n", ff->name, hw); ret = PTR_ERR(hw); goto err; } } ret = of_clk_add_hw_provider(np, of_clk_hw_onecell_get, cells); if (ret) { pr_err("failed registering clk provider: %d\n", ret); goto err; } return; err: /* * We are doomed. The system will not be able to boot. * * Let's still try to be good citizens by freeing resources and print * a last error message that might help debugging. */ pr_err("failed clk init: %d\n", ret); if (cells) { of_clk_del_provider(np); for (i = 0; i < early_data->early_pll_count; i++) { const struct eqc_pll *pll = &early_data->early_plls[i]; struct clk_hw *hw = cells->hws[pll->index]; if (!IS_ERR_OR_NULL(hw)) clk_hw_unregister_fixed_factor(hw); } kfree(cells); } } static void __init eqc_eyeq5_early_init(struct device_node *np) { eqc_early_init(np, &eqc_eyeq5_early_match_data); } CLK_OF_DECLARE_DRIVER(eqc_eyeq5, "mobileye,eyeq5-olb", eqc_eyeq5_early_init); static void __init eqc_eyeq6h_central_early_init(struct device_node *np) { eqc_early_init(np, &eqc_eyeq6h_central_early_match_data); } CLK_OF_DECLARE_DRIVER(eqc_eyeq6h_central, "mobileye,eyeq6h-central-olb", eqc_eyeq6h_central_early_init); static void __init eqc_eyeq6h_west_early_init(struct device_node *np) { eqc_early_init(np, &eqc_eyeq6h_west_early_match_data); } CLK_OF_DECLARE_DRIVER(eqc_eyeq6h_west, "mobileye,eyeq6h-west-olb", eqc_eyeq6h_west_early_init);