/* * Copyright 2013 Freescale Semiconductor, Inc. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. * * clock driver for Freescale QorIQ SoCs. */ #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #include #include #include #include #include #include #include #include #include #include #define PLL_DIV1 0 #define PLL_DIV2 1 #define PLL_DIV3 2 #define PLL_DIV4 3 #define PLATFORM_PLL 0 #define CGA_PLL1 1 #define CGA_PLL2 2 #define CGA_PLL3 3 #define CGA_PLL4 4 /* only on clockgen-1.0, which lacks CGB */ #define CGB_PLL1 4 #define CGB_PLL2 5 struct clockgen_pll_div { struct clk *clk; char name[32]; }; struct clockgen_pll { struct clockgen_pll_div div[4]; }; #define CLKSEL_VALID 1 #define CLKSEL_80PCT 2 /* Only allowed if PLL <= 80% of max cpu freq */ struct clockgen_sourceinfo { u32 flags; /* CLKSEL_xxx */ int pll; /* CGx_PLLn */ int div; /* PLL_DIVn */ }; #define NUM_MUX_PARENTS 16 struct clockgen_muxinfo { struct clockgen_sourceinfo clksel[NUM_MUX_PARENTS]; }; #define NUM_HWACCEL 5 #define NUM_CMUX 8 struct clockgen; /* * cmux freq must be >= platform pll. * If not set, cmux freq must be >= platform pll/2 */ #define CG_CMUX_GE_PLAT 1 #define CG_PLL_8BIT 2 /* PLLCnGSR[CFG] is 8 bits, not 6 */ #define CG_VER3 4 /* version 3 cg: reg layout different */ #define CG_LITTLE_ENDIAN 8 struct clockgen_chipinfo { const char *compat, *guts_compat; const struct clockgen_muxinfo *cmux_groups[2]; const struct clockgen_muxinfo *hwaccel[NUM_HWACCEL]; void (*init_periph)(struct clockgen *cg); int cmux_to_group[NUM_CMUX]; /* -1 terminates if fewer than NUM_CMUX */ u32 pll_mask; /* 1 << n bit set if PLL n is valid */ u32 flags; /* CG_xxx */ }; struct clockgen { struct device_node *node; void __iomem *regs; struct clockgen_chipinfo info; /* mutable copy */ struct clk *sysclk, *coreclk; struct clockgen_pll pll[6]; struct clk *cmux[NUM_CMUX]; struct clk *hwaccel[NUM_HWACCEL]; struct clk *fman[2]; struct ccsr_guts __iomem *guts; }; static struct clockgen clockgen; static void cg_out(struct clockgen *cg, u32 val, u32 __iomem *reg) { if (cg->info.flags & CG_LITTLE_ENDIAN) iowrite32(val, reg); else iowrite32be(val, reg); } static u32 cg_in(struct clockgen *cg, u32 __iomem *reg) { u32 val; if (cg->info.flags & CG_LITTLE_ENDIAN) val = ioread32(reg); else val = ioread32be(reg); return val; } static const struct clockgen_muxinfo p2041_cmux_grp1 = { { [0] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, [1] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, [4] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, } }; static const struct clockgen_muxinfo p2041_cmux_grp2 = { { [0] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, [4] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, [5] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, } }; static const struct clockgen_muxinfo p5020_cmux_grp1 = { { [0] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, [1] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, [4] = { CLKSEL_VALID | CLKSEL_80PCT, CGA_PLL2, PLL_DIV1 }, } }; static const struct clockgen_muxinfo p5020_cmux_grp2 = { { [0] = { CLKSEL_VALID | CLKSEL_80PCT, CGA_PLL1, PLL_DIV1 }, [4] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, [5] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, } }; static const struct clockgen_muxinfo p5040_cmux_grp1 = { { [0] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, [1] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, [4] = { CLKSEL_VALID | CLKSEL_80PCT, CGA_PLL2, PLL_DIV1 }, [5] = { CLKSEL_VALID | CLKSEL_80PCT, CGA_PLL2, PLL_DIV2 }, } }; static const struct clockgen_muxinfo p5040_cmux_grp2 = { { [0] = { CLKSEL_VALID | CLKSEL_80PCT, CGA_PLL1, PLL_DIV1 }, [1] = { CLKSEL_VALID | CLKSEL_80PCT, CGA_PLL1, PLL_DIV2 }, [4] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, [5] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, } }; static const struct clockgen_muxinfo p4080_cmux_grp1 = { { [0] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, [1] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, [4] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, [5] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, [8] = { CLKSEL_VALID | CLKSEL_80PCT, CGA_PLL3, PLL_DIV1 }, } }; static const struct clockgen_muxinfo p4080_cmux_grp2 = { { [0] = { CLKSEL_VALID | CLKSEL_80PCT, CGA_PLL1, PLL_DIV1 }, [8] = { CLKSEL_VALID, CGA_PLL3, PLL_DIV1 }, [9] = { CLKSEL_VALID, CGA_PLL3, PLL_DIV2 }, [12] = { CLKSEL_VALID, CGA_PLL4, PLL_DIV1 }, [13] = { CLKSEL_VALID, CGA_PLL4, PLL_DIV2 }, } }; static const struct clockgen_muxinfo t1023_cmux = { { [0] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, [1] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, } }; static const struct clockgen_muxinfo t1040_cmux = { { [0] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, [1] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, [4] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, [5] = { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, } }; static const struct clockgen_muxinfo clockgen2_cmux_cga = { { { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV4 }, {}, { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV4 }, {}, { CLKSEL_VALID, CGA_PLL3, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL3, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL3, PLL_DIV4 }, }, }; static const struct clockgen_muxinfo clockgen2_cmux_cga12 = { { { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV4 }, {}, { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV4 }, }, }; static const struct clockgen_muxinfo clockgen2_cmux_cgb = { { { CLKSEL_VALID, CGB_PLL1, PLL_DIV1 }, { CLKSEL_VALID, CGB_PLL1, PLL_DIV2 }, { CLKSEL_VALID, CGB_PLL1, PLL_DIV4 }, {}, { CLKSEL_VALID, CGB_PLL2, PLL_DIV1 }, { CLKSEL_VALID, CGB_PLL2, PLL_DIV2 }, { CLKSEL_VALID, CGB_PLL2, PLL_DIV4 }, }, }; static const struct clockgen_muxinfo ls1043a_hwa1 = { { {}, {}, { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV3 }, {}, {}, { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV3 }, }, }; static const struct clockgen_muxinfo ls1043a_hwa2 = { { {}, { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, {}, { CLKSEL_VALID, CGA_PLL2, PLL_DIV3 }, }, }; static const struct clockgen_muxinfo ls1046a_hwa1 = { { {}, {}, { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV3 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV4 }, { CLKSEL_VALID, PLATFORM_PLL, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV3 }, }, }; static const struct clockgen_muxinfo ls1046a_hwa2 = { { {}, { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV3 }, {}, {}, { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, }, }; static const struct clockgen_muxinfo ls1012a_cmux = { { [0] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, {}, [2] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, } }; static const struct clockgen_muxinfo t1023_hwa1 = { { {}, { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV3 }, }, }; static const struct clockgen_muxinfo t1023_hwa2 = { { [6] = { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, }, }; static const struct clockgen_muxinfo t2080_hwa1 = { { {}, { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV3 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV4 }, { CLKSEL_VALID, PLATFORM_PLL, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV3 }, }, }; static const struct clockgen_muxinfo t2080_hwa2 = { { {}, { CLKSEL_VALID, CGA_PLL2, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV3 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV4 }, { CLKSEL_VALID, PLATFORM_PLL, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV3 }, }, }; static const struct clockgen_muxinfo t4240_hwa1 = { { { CLKSEL_VALID, PLATFORM_PLL, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV1 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV3 }, { CLKSEL_VALID, CGA_PLL1, PLL_DIV4 }, {}, { CLKSEL_VALID, CGA_PLL2, PLL_DIV2 }, { CLKSEL_VALID, CGA_PLL2, PLL_DIV3 }, }, }; static const struct clockgen_muxinfo t4240_hwa4 = { { [2] = { CLKSEL_VALID, CGB_PLL1, PLL_DIV2 }, [3] = { CLKSEL_VALID, CGB_PLL1, PLL_DIV3 }, [4] = { CLKSEL_VALID, CGB_PLL1, PLL_DIV4 }, [5] = { CLKSEL_VALID, PLATFORM_PLL, PLL_DIV1 }, [6] = { CLKSEL_VALID, CGB_PLL2, PLL_DIV2 }, }, }; static const struct clockgen_muxinfo t4240_hwa5 = { { [2] = { CLKSEL_VALID, CGB_PLL2, PLL_DIV2 }, [3] = { CLKSEL_VALID, CGB_PLL2, PLL_DIV3 }, [4] = { CLKSEL_VALID, CGB_PLL2, PLL_DIV4 }, [5] = { CLKSEL_VALID, PLATFORM_PLL, PLL_DIV1 }, [6] = { CLKSEL_VALID, CGB_PLL1, PLL_DIV2 }, [7] = { CLKSEL_VALID, CGB_PLL1, PLL_DIV3 }, }, }; #define RCWSR7_FM1_CLK_SEL 0x40000000 #define RCWSR7_FM2_CLK_SEL 0x20000000 #define RCWSR7_HWA_ASYNC_DIV 0x04000000 static void __init p2041_init_periph(struct clockgen *cg) { u32 reg; reg = ioread32be(&cg->guts->rcwsr[7]); if (reg & RCWSR7_FM1_CLK_SEL) cg->fman[0] = cg->pll[CGA_PLL2].div[PLL_DIV2].clk; else cg->fman[0] = cg->pll[PLATFORM_PLL].div[PLL_DIV2].clk; } static void __init p4080_init_periph(struct clockgen *cg) { u32 reg; reg = ioread32be(&cg->guts->rcwsr[7]); if (reg & RCWSR7_FM1_CLK_SEL) cg->fman[0] = cg->pll[CGA_PLL3].div[PLL_DIV2].clk; else cg->fman[0] = cg->pll[PLATFORM_PLL].div[PLL_DIV2].clk; if (reg & RCWSR7_FM2_CLK_SEL) cg->fman[1] = cg->pll[CGA_PLL3].div[PLL_DIV2].clk; else cg->fman[1] = cg->pll[PLATFORM_PLL].div[PLL_DIV2].clk; } static void __init p5020_init_periph(struct clockgen *cg) { u32 reg; int div = PLL_DIV2; reg = ioread32be(&cg->guts->rcwsr[7]); if (reg & RCWSR7_HWA_ASYNC_DIV) div = PLL_DIV4; if (reg & RCWSR7_FM1_CLK_SEL) cg->fman[0] = cg->pll[CGA_PLL2].div[div].clk; else cg->fman[0] = cg->pll[PLATFORM_PLL].div[PLL_DIV2].clk; } static void __init p5040_init_periph(struct clockgen *cg) { u32 reg; int div = PLL_DIV2; reg = ioread32be(&cg->guts->rcwsr[7]); if (reg & RCWSR7_HWA_ASYNC_DIV) div = PLL_DIV4; if (reg & RCWSR7_FM1_CLK_SEL) cg->fman[0] = cg->pll[CGA_PLL3].div[div].clk; else cg->fman[0] = cg->pll[PLATFORM_PLL].div[PLL_DIV2].clk; if (reg & RCWSR7_FM2_CLK_SEL) cg->fman[1] = cg->pll[CGA_PLL3].div[div].clk; else cg->fman[1] = cg->pll[PLATFORM_PLL].div[PLL_DIV2].clk; } static void __init t1023_init_periph(struct clockgen *cg) { cg->fman[0] = cg->hwaccel[1]; } static void __init t1040_init_periph(struct clockgen *cg) { cg->fman[0] = cg->pll[PLATFORM_PLL].div[PLL_DIV1].clk; } static void __init t2080_init_periph(struct clockgen *cg) { cg->fman[0] = cg->hwaccel[0]; } static void __init t4240_init_periph(struct clockgen *cg) { cg->fman[0] = cg->hwaccel[3]; cg->fman[1] = cg->hwaccel[4]; } static const struct clockgen_chipinfo chipinfo[] = { { .compat = "fsl,b4420-clockgen", .guts_compat = "fsl,b4860-device-config", .init_periph = t2080_init_periph, .cmux_groups = { &clockgen2_cmux_cga12, &clockgen2_cmux_cgb }, .hwaccel = { &t2080_hwa1 }, .cmux_to_group = { 0, 1, 1, 1, -1 }, .pll_mask = 0x3f, .flags = CG_PLL_8BIT, }, { .compat = "fsl,b4860-clockgen", .guts_compat = "fsl,b4860-device-config", .init_periph = t2080_init_periph, .cmux_groups = { &clockgen2_cmux_cga12, &clockgen2_cmux_cgb }, .hwaccel = { &t2080_hwa1 }, .cmux_to_group = { 0, 1, 1, 1, -1 }, .pll_mask = 0x3f, .flags = CG_PLL_8BIT, }, { .compat = "fsl,ls1021a-clockgen", .cmux_groups = { &t1023_cmux }, .cmux_to_group = { 0, -1 }, .pll_mask = 0x03, }, { .compat = "fsl,ls1043a-clockgen", .init_periph = t2080_init_periph, .cmux_groups = { &t1040_cmux }, .hwaccel = { &ls1043a_hwa1, &ls1043a_hwa2 }, .cmux_to_group = { 0, -1 }, .pll_mask = 0x07, .flags = CG_PLL_8BIT, }, { .compat = "fsl,ls1046a-clockgen", .init_periph = t2080_init_periph, .cmux_groups = { &t1040_cmux }, .hwaccel = { &ls1046a_hwa1, &ls1046a_hwa2 }, .cmux_to_group = { 0, -1 }, .pll_mask = 0x07, .flags = CG_PLL_8BIT, }, { .compat = "fsl,ls1088a-clockgen", .cmux_groups = { &clockgen2_cmux_cga12 }, .cmux_to_group = { 0, 0, -1 }, .pll_mask = 0x07, .flags = CG_VER3 | CG_LITTLE_ENDIAN, }, { .compat = "fsl,ls1012a-clockgen", .cmux_groups = { &ls1012a_cmux }, .cmux_to_group = { 0, -1 }, .pll_mask = 0x03, }, { .compat = "fsl,ls2080a-clockgen", .cmux_groups = { &clockgen2_cmux_cga12, &clockgen2_cmux_cgb }, .cmux_to_group = { 0, 0, 1, 1, -1 }, .pll_mask = 0x37, .flags = CG_VER3 | CG_LITTLE_ENDIAN, }, { .compat = "fsl,p2041-clockgen", .guts_compat = "fsl,qoriq-device-config-1.0", .init_periph = p2041_init_periph, .cmux_groups = { &p2041_cmux_grp1, &p2041_cmux_grp2 }, .cmux_to_group = { 0, 0, 1, 1, -1 }, .pll_mask = 0x07, }, { .compat = "fsl,p3041-clockgen", .guts_compat = "fsl,qoriq-device-config-1.0", .init_periph = p2041_init_periph, .cmux_groups = { &p2041_cmux_grp1, &p2041_cmux_grp2 }, .cmux_to_group = { 0, 0, 1, 1, -1 }, .pll_mask = 0x07, }, { .compat = "fsl,p4080-clockgen", .guts_compat = "fsl,qoriq-device-config-1.0", .init_periph = p4080_init_periph, .cmux_groups = { &p4080_cmux_grp1, &p4080_cmux_grp2 }, .cmux_to_group = { 0, 0, 0, 0, 1, 1, 1, 1 }, .pll_mask = 0x1f, }, { .compat = "fsl,p5020-clockgen", .guts_compat = "fsl,qoriq-device-config-1.0", .init_periph = p5020_init_periph, .cmux_groups = { &p2041_cmux_grp1, &p2041_cmux_grp2 }, .cmux_to_group = { 0, 1, -1 }, .pll_mask = 0x07, }, { .compat = "fsl,p5040-clockgen", .guts_compat = "fsl,p5040-device-config", .init_periph = p5040_init_periph, .cmux_groups = { &p5040_cmux_grp1, &p5040_cmux_grp2 }, .cmux_to_group = { 0, 0, 1, 1, -1 }, .pll_mask = 0x0f, }, { .compat = "fsl,t1023-clockgen", .guts_compat = "fsl,t1023-device-config", .init_periph = t1023_init_periph, .cmux_groups = { &t1023_cmux }, .hwaccel = { &t1023_hwa1, &t1023_hwa2 }, .cmux_to_group = { 0, 0, -1 }, .pll_mask = 0x03, .flags = CG_PLL_8BIT, }, { .compat = "fsl,t1040-clockgen", .guts_compat = "fsl,t1040-device-config", .init_periph = t1040_init_periph, .cmux_groups = { &t1040_cmux }, .cmux_to_group = { 0, 0, 0, 0, -1 }, .pll_mask = 0x07, .flags = CG_PLL_8BIT, }, { .compat = "fsl,t2080-clockgen", .guts_compat = "fsl,t2080-device-config", .init_periph = t2080_init_periph, .cmux_groups = { &clockgen2_cmux_cga12 }, .hwaccel = { &t2080_hwa1, &t2080_hwa2 }, .cmux_to_group = { 0, -1 }, .pll_mask = 0x07, .flags = CG_PLL_8BIT, }, { .compat = "fsl,t4240-clockgen", .guts_compat = "fsl,t4240-device-config", .init_periph = t4240_init_periph, .cmux_groups = { &clockgen2_cmux_cga, &clockgen2_cmux_cgb }, .hwaccel = { &t4240_hwa1, NULL, NULL, &t4240_hwa4, &t4240_hwa5 }, .cmux_to_group = { 0, 0, 1, -1 }, .pll_mask = 0x3f, .flags = CG_PLL_8BIT, }, {}, }; struct mux_hwclock { struct clk_hw hw; struct clockgen *cg; const struct clockgen_muxinfo *info; u32 __iomem *reg; u8 parent_to_clksel[NUM_MUX_PARENTS]; s8 clksel_to_parent[NUM_MUX_PARENTS]; int num_parents; }; #define to_mux_hwclock(p) container_of(p, struct mux_hwclock, hw) #define CLKSEL_MASK 0x78000000 #define CLKSEL_SHIFT 27 static int mux_set_parent(struct clk_hw *hw, u8 idx) { struct mux_hwclock *hwc = to_mux_hwclock(hw); u32 clksel; if (idx >= hwc->num_parents) return -EINVAL; clksel = hwc->parent_to_clksel[idx]; cg_out(hwc->cg, (clksel << CLKSEL_SHIFT) & CLKSEL_MASK, hwc->reg); return 0; } static u8 mux_get_parent(struct clk_hw *hw) { struct mux_hwclock *hwc = to_mux_hwclock(hw); u32 clksel; s8 ret; clksel = (cg_in(hwc->cg, hwc->reg) & CLKSEL_MASK) >> CLKSEL_SHIFT; ret = hwc->clksel_to_parent[clksel]; if (ret < 0) { pr_err("%s: mux at %p has bad clksel\n", __func__, hwc->reg); return 0; } return ret; } static const struct clk_ops cmux_ops = { .get_parent = mux_get_parent, .set_parent = mux_set_parent, }; /* * Don't allow setting for now, as the clock options haven't been * sanitized for additional restrictions. */ static const struct clk_ops hwaccel_ops = { .get_parent = mux_get_parent, }; static const struct clockgen_pll_div *get_pll_div(struct clockgen *cg, struct mux_hwclock *hwc, int idx) { int pll, div; if (!(hwc->info->clksel[idx].flags & CLKSEL_VALID)) return NULL; pll = hwc->info->clksel[idx].pll; div = hwc->info->clksel[idx].div; return &cg->pll[pll].div[div]; } static struct clk * __init create_mux_common(struct clockgen *cg, struct mux_hwclock *hwc, const struct clk_ops *ops, unsigned long min_rate, unsigned long max_rate, unsigned long pct80_rate, const char *fmt, int idx) { struct clk_init_data init = {}; struct clk *clk; const struct clockgen_pll_div *div; const char *parent_names[NUM_MUX_PARENTS]; char name[32]; int i, j; snprintf(name, sizeof(name), fmt, idx); for (i = 0, j = 0; i < NUM_MUX_PARENTS; i++) { unsigned long rate; hwc->clksel_to_parent[i] = -1; div = get_pll_div(cg, hwc, i); if (!div) continue; rate = clk_get_rate(div->clk); if (hwc->info->clksel[i].flags & CLKSEL_80PCT && rate > pct80_rate) continue; if (rate < min_rate) continue; if (rate > max_rate) continue; parent_names[j] = div->name; hwc->parent_to_clksel[j] = i; hwc->clksel_to_parent[i] = j; j++; } init.name = name; init.ops = ops; init.parent_names = parent_names; init.num_parents = hwc->num_parents = j; init.flags = 0; hwc->hw.init = &init; hwc->cg = cg; clk = clk_register(NULL, &hwc->hw); if (IS_ERR(clk)) { pr_err("%s: Couldn't register %s: %ld\n", __func__, name, PTR_ERR(clk)); kfree(hwc); return NULL; } return clk; } static struct clk * __init create_one_cmux(struct clockgen *cg, int idx) { struct mux_hwclock *hwc; const struct clockgen_pll_div *div; unsigned long plat_rate, min_rate; u64 max_rate, pct80_rate; u32 clksel; hwc = kzalloc(sizeof(*hwc), GFP_KERNEL); if (!hwc) return NULL; if (cg->info.flags & CG_VER3) hwc->reg = cg->regs + 0x70000 + 0x20 * idx; else hwc->reg = cg->regs + 0x20 * idx; hwc->info = cg->info.cmux_groups[cg->info.cmux_to_group[idx]]; /* * Find the rate for the default clksel, and treat it as the * maximum rated core frequency. If this is an incorrect * assumption, certain clock options (possibly including the * default clksel) may be inappropriately excluded on certain * chips. */ clksel = (cg_in(cg, hwc->reg) & CLKSEL_MASK) >> CLKSEL_SHIFT; div = get_pll_div(cg, hwc, clksel); if (!div) { kfree(hwc); return NULL; } max_rate = clk_get_rate(div->clk); pct80_rate = max_rate * 8; do_div(pct80_rate, 10); plat_rate = clk_get_rate(cg->pll[PLATFORM_PLL].div[PLL_DIV1].clk); if (cg->info.flags & CG_CMUX_GE_PLAT) min_rate = plat_rate; else min_rate = plat_rate / 2; return create_mux_common(cg, hwc, &cmux_ops, min_rate, max_rate, pct80_rate, "cg-cmux%d", idx); } static struct clk * __init create_one_hwaccel(struct clockgen *cg, int idx) { struct mux_hwclock *hwc; hwc = kzalloc(sizeof(*hwc), GFP_KERNEL); if (!hwc) return NULL; hwc->reg = cg->regs + 0x20 * idx + 0x10; hwc->info = cg->info.hwaccel[idx]; return create_mux_common(cg, hwc, &hwaccel_ops, 0, ULONG_MAX, 0, "cg-hwaccel%d", idx); } static void __init create_muxes(struct clockgen *cg) { int i; for (i = 0; i < ARRAY_SIZE(cg->cmux); i++) { if (cg->info.cmux_to_group[i] < 0) break; if (cg->info.cmux_to_group[i] >= ARRAY_SIZE(cg->info.cmux_groups)) { WARN_ON_ONCE(1); continue; } cg->cmux[i] = create_one_cmux(cg, i); } for (i = 0; i < ARRAY_SIZE(cg->hwaccel); i++) { if (!cg->info.hwaccel[i]) continue; cg->hwaccel[i] = create_one_hwaccel(cg, i); } } static void __init clockgen_init(struct device_node *np); /* * Legacy nodes may get probed before the parent clockgen node. * It is assumed that device trees with legacy nodes will not * contain a "clocks" property -- otherwise the input clocks may * not be initialized at this point. */ static void __init legacy_init_clockgen(struct device_node *np) { if (!clockgen.node) clockgen_init(of_get_parent(np)); } /* Legacy node */ static void __init core_mux_init(struct device_node *np) { struct clk *clk; struct resource res; int idx, rc; legacy_init_clockgen(np); if (of_address_to_resource(np, 0, &res)) return; idx = (res.start & 0xf0) >> 5; clk = clockgen.cmux[idx]; rc = of_clk_add_provider(np, of_clk_src_simple_get, clk); if (rc) { pr_err("%s: Couldn't register clk provider for node %s: %d\n", __func__, np->name, rc); return; } } static struct clk __init *sysclk_from_fixed(struct device_node *node, const char *name) { u32 rate; if (of_property_read_u32(node, "clock-frequency", &rate)) return ERR_PTR(-ENODEV); return clk_register_fixed_rate(NULL, name, NULL, 0, rate); } static struct clk __init *input_clock(const char *name, struct clk *clk) { const char *input_name; /* Register the input clock under the desired name. */ input_name = __clk_get_name(clk); clk = clk_register_fixed_factor(NULL, name, input_name, 0, 1, 1); if (IS_ERR(clk)) pr_err("%s: Couldn't register %s: %ld\n", __func__, name, PTR_ERR(clk)); return clk; } static struct clk __init *input_clock_by_name(const char *name, const char *dtname) { struct clk *clk; clk = of_clk_get_by_name(clockgen.node, dtname); if (IS_ERR(clk)) return clk; return input_clock(name, clk); } static struct clk __init *input_clock_by_index(const char *name, int idx) { struct clk *clk; clk = of_clk_get(clockgen.node, 0); if (IS_ERR(clk)) return clk; return input_clock(name, clk); } static struct clk * __init create_sysclk(const char *name) { struct device_node *sysclk; struct clk *clk; clk = sysclk_from_fixed(clockgen.node, name); if (!IS_ERR(clk)) return clk; clk = input_clock_by_name(name, "sysclk"); if (!IS_ERR(clk)) return clk; clk = input_clock_by_index(name, 0); if (!IS_ERR(clk)) return clk; sysclk = of_get_child_by_name(clockgen.node, "sysclk"); if (sysclk) { clk = sysclk_from_fixed(sysclk, name); if (!IS_ERR(clk)) return clk; } pr_err("%s: No input sysclk\n", __func__); return NULL; } static struct clk * __init create_coreclk(const char *name) { struct clk *clk; clk = input_clock_by_name(name, "coreclk"); if (!IS_ERR(clk)) return clk; /* * This indicates a mix of legacy nodes with the new coreclk * mechanism, which should never happen. If this error occurs, * don't use the wrong input clock just because coreclk isn't * ready yet. */ if (WARN_ON(PTR_ERR(clk) == -EPROBE_DEFER)) return clk; return NULL; } /* Legacy node */ static void __init sysclk_init(struct device_node *node) { struct clk *clk; legacy_init_clockgen(node); clk = clockgen.sysclk; if (clk) of_clk_add_provider(node, of_clk_src_simple_get, clk); } #define PLL_KILL BIT(31) static void __init create_one_pll(struct clockgen *cg, int idx) { u32 __iomem *reg; u32 mult; struct clockgen_pll *pll = &cg->pll[idx]; const char *input = "cg-sysclk"; int i; if (!(cg->info.pll_mask & (1 << idx))) return; if (cg->coreclk && idx != PLATFORM_PLL) { if (IS_ERR(cg->coreclk)) return; input = "cg-coreclk"; } if (cg->info.flags & CG_VER3) { switch (idx) { case PLATFORM_PLL: reg = cg->regs + 0x60080; break; case CGA_PLL1: reg = cg->regs + 0x80; break; case CGA_PLL2: reg = cg->regs + 0xa0; break; case CGB_PLL1: reg = cg->regs + 0x10080; break; case CGB_PLL2: reg = cg->regs + 0x100a0; break; default: WARN_ONCE(1, "index %d\n", idx); return; } } else { if (idx == PLATFORM_PLL) reg = cg->regs + 0xc00; else reg = cg->regs + 0x800 + 0x20 * (idx - 1); } /* Get the multiple of PLL */ mult = cg_in(cg, reg); /* Check if this PLL is disabled */ if (mult & PLL_KILL) { pr_debug("%s(): pll %p disabled\n", __func__, reg); return; } if ((cg->info.flags & CG_VER3) || ((cg->info.flags & CG_PLL_8BIT) && idx != PLATFORM_PLL)) mult = (mult & GENMASK(8, 1)) >> 1; else mult = (mult & GENMASK(6, 1)) >> 1; for (i = 0; i < ARRAY_SIZE(pll->div); i++) { struct clk *clk; snprintf(pll->div[i].name, sizeof(pll->div[i].name), "cg-pll%d-div%d", idx, i + 1); clk = clk_register_fixed_factor(NULL, pll->div[i].name, input, 0, mult, i + 1); if (IS_ERR(clk)) { pr_err("%s: %s: register failed %ld\n", __func__, pll->div[i].name, PTR_ERR(clk)); continue; } pll->div[i].clk = clk; } } static void __init create_plls(struct clockgen *cg) { int i; for (i = 0; i < ARRAY_SIZE(cg->pll); i++) create_one_pll(cg, i); } static void __init legacy_pll_init(struct device_node *np, int idx) { struct clockgen_pll *pll; struct clk_onecell_data *onecell_data; struct clk **subclks; int count, rc; legacy_init_clockgen(np); pll = &clockgen.pll[idx]; count = of_property_count_strings(np, "clock-output-names"); BUILD_BUG_ON(ARRAY_SIZE(pll->div) < 4); subclks = kcalloc(4, sizeof(struct clk *), GFP_KERNEL); if (!subclks) return; onecell_data = kmalloc(sizeof(*onecell_data), GFP_KERNEL); if (!onecell_data) goto err_clks; if (count <= 3) { subclks[0] = pll->div[0].clk; subclks[1] = pll->div[1].clk; subclks[2] = pll->div[3].clk; } else { subclks[0] = pll->div[0].clk; subclks[1] = pll->div[1].clk; subclks[2] = pll->div[2].clk; subclks[3] = pll->div[3].clk; } onecell_data->clks = subclks; onecell_data->clk_num = count; rc = of_clk_add_provider(np, of_clk_src_onecell_get, onecell_data); if (rc) { pr_err("%s: Couldn't register clk provider for node %s: %d\n", __func__, np->name, rc); goto err_cell; } return; err_cell: kfree(onecell_data); err_clks: kfree(subclks); } /* Legacy node */ static void __init pltfrm_pll_init(struct device_node *np) { legacy_pll_init(np, PLATFORM_PLL); } /* Legacy node */ static void __init core_pll_init(struct device_node *np) { struct resource res; int idx; if (of_address_to_resource(np, 0, &res)) return; if ((res.start & 0xfff) == 0xc00) { /* * ls1021a devtree labels the platform PLL * with the core PLL compatible */ pltfrm_pll_init(np); } else { idx = (res.start & 0xf0) >> 5; legacy_pll_init(np, CGA_PLL1 + idx); } } static struct clk *clockgen_clk_get(struct of_phandle_args *clkspec, void *data) { struct clockgen *cg = data; struct clk *clk; struct clockgen_pll *pll; u32 type, idx; if (clkspec->args_count < 2) { pr_err("%s: insufficient phandle args\n", __func__); return ERR_PTR(-EINVAL); } type = clkspec->args[0]; idx = clkspec->args[1]; switch (type) { case 0: if (idx != 0) goto bad_args; clk = cg->sysclk; break; case 1: if (idx >= ARRAY_SIZE(cg->cmux)) goto bad_args; clk = cg->cmux[idx]; break; case 2: if (idx >= ARRAY_SIZE(cg->hwaccel)) goto bad_args; clk = cg->hwaccel[idx]; break; case 3: if (idx >= ARRAY_SIZE(cg->fman)) goto bad_args; clk = cg->fman[idx]; break; case 4: pll = &cg->pll[PLATFORM_PLL]; if (idx >= ARRAY_SIZE(pll->div)) goto bad_args; clk = pll->div[idx].clk; break; case 5: if (idx != 0) goto bad_args; clk = cg->coreclk; if (IS_ERR(clk)) clk = NULL; break; default: goto bad_args; } if (!clk) return ERR_PTR(-ENOENT); return clk; bad_args: pr_err("%s: Bad phandle args %u %u\n", __func__, type, idx); return ERR_PTR(-EINVAL); } #ifdef CONFIG_PPC #include static const u32 a4510_svrs[] __initconst = { (SVR_P2040 << 8) | 0x10, /* P2040 1.0 */ (SVR_P2040 << 8) | 0x11, /* P2040 1.1 */ (SVR_P2041 << 8) | 0x10, /* P2041 1.0 */ (SVR_P2041 << 8) | 0x11, /* P2041 1.1 */ (SVR_P3041 << 8) | 0x10, /* P3041 1.0 */ (SVR_P3041 << 8) | 0x11, /* P3041 1.1 */ (SVR_P4040 << 8) | 0x20, /* P4040 2.0 */ (SVR_P4080 << 8) | 0x20, /* P4080 2.0 */ (SVR_P5010 << 8) | 0x10, /* P5010 1.0 */ (SVR_P5010 << 8) | 0x20, /* P5010 2.0 */ (SVR_P5020 << 8) | 0x10, /* P5020 1.0 */ (SVR_P5021 << 8) | 0x10, /* P5021 1.0 */ (SVR_P5040 << 8) | 0x10, /* P5040 1.0 */ }; #define SVR_SECURITY 0x80000 /* The Security (E) bit */ static bool __init has_erratum_a4510(void) { u32 svr = mfspr(SPRN_SVR); int i; svr &= ~SVR_SECURITY; for (i = 0; i < ARRAY_SIZE(a4510_svrs); i++) { if (svr == a4510_svrs[i]) return true; } return false; } #else static bool __init has_erratum_a4510(void) { return false; } #endif static void __init clockgen_init(struct device_node *np) { int i, ret; bool is_old_ls1021a = false; /* May have already been called by a legacy probe */ if (clockgen.node) return; clockgen.node = np; clockgen.regs = of_iomap(np, 0); if (!clockgen.regs && of_device_is_compatible(of_root, "fsl,ls1021a")) { /* Compatibility hack for old, broken device trees */ clockgen.regs = ioremap(0x1ee1000, 0x1000); is_old_ls1021a = true; } if (!clockgen.regs) { pr_err("%s(): %s: of_iomap() failed\n", __func__, np->name); return; } for (i = 0; i < ARRAY_SIZE(chipinfo); i++) { if (of_device_is_compatible(np, chipinfo[i].compat)) break; if (is_old_ls1021a && !strcmp(chipinfo[i].compat, "fsl,ls1021a-clockgen")) break; } if (i == ARRAY_SIZE(chipinfo)) { pr_err("%s: unknown clockgen node %s\n", __func__, np->full_name); goto err; } clockgen.info = chipinfo[i]; if (clockgen.info.guts_compat) { struct device_node *guts; guts = of_find_compatible_node(NULL, NULL, clockgen.info.guts_compat); if (guts) { clockgen.guts = of_iomap(guts, 0); if (!clockgen.guts) { pr_err("%s: Couldn't map %s regs\n", __func__, guts->full_name); } } } if (has_erratum_a4510()) clockgen.info.flags |= CG_CMUX_GE_PLAT; clockgen.sysclk = create_sysclk("cg-sysclk"); clockgen.coreclk = create_coreclk("cg-coreclk"); create_plls(&clockgen); create_muxes(&clockgen); if (clockgen.info.init_periph) clockgen.info.init_periph(&clockgen); ret = of_clk_add_provider(np, clockgen_clk_get, &clockgen); if (ret) { pr_err("%s: Couldn't register clk provider for node %s: %d\n", __func__, np->name, ret); } return; err: iounmap(clockgen.regs); clockgen.regs = NULL; } CLK_OF_DECLARE(qoriq_clockgen_1, "fsl,qoriq-clockgen-1.0", clockgen_init); CLK_OF_DECLARE(qoriq_clockgen_2, "fsl,qoriq-clockgen-2.0", clockgen_init); CLK_OF_DECLARE(qoriq_clockgen_ls1012a, "fsl,ls1012a-clockgen", clockgen_init); CLK_OF_DECLARE(qoriq_clockgen_ls1021a, "fsl,ls1021a-clockgen", clockgen_init); CLK_OF_DECLARE(qoriq_clockgen_ls1043a, "fsl,ls1043a-clockgen", clockgen_init); CLK_OF_DECLARE(qoriq_clockgen_ls1046a, "fsl,ls1046a-clockgen", clockgen_init); CLK_OF_DECLARE(qoriq_clockgen_ls1088a, "fsl,ls1088a-clockgen", clockgen_init); CLK_OF_DECLARE(qoriq_clockgen_ls2080a, "fsl,ls2080a-clockgen", clockgen_init); /* Legacy nodes */ CLK_OF_DECLARE(qoriq_sysclk_1, "fsl,qoriq-sysclk-1.0", sysclk_init); CLK_OF_DECLARE(qoriq_sysclk_2, "fsl,qoriq-sysclk-2.0", sysclk_init); CLK_OF_DECLARE(qoriq_core_pll_1, "fsl,qoriq-core-pll-1.0", core_pll_init); CLK_OF_DECLARE(qoriq_core_pll_2, "fsl,qoriq-core-pll-2.0", core_pll_init); CLK_OF_DECLARE(qoriq_core_mux_1, "fsl,qoriq-core-mux-1.0", core_mux_init); CLK_OF_DECLARE(qoriq_core_mux_2, "fsl,qoriq-core-mux-2.0", core_mux_init); CLK_OF_DECLARE(qoriq_pltfrm_pll_1, "fsl,qoriq-platform-pll-1.0", pltfrm_pll_init); CLK_OF_DECLARE(qoriq_pltfrm_pll_2, "fsl,qoriq-platform-pll-2.0", pltfrm_pll_init);