u-boot-imx/arch/arm/cpu/armv7/zynq/clk.c - nest-guard/1.0/u-boot - Git at Google

 /*
  * Copyright (C) 2013 Soren Brinkmann <soren.brinkmann@xilinx.com>
  * Copyright (C) 2013 Xilinx, Inc. All rights reserved.
  *
  * SPDX-License-Identifier:	GPL-2.0+
  */
 #include <common.h>
 #include <errno.h>
 #include <clk.h>
 #include <asm/io.h>
 #include <asm/arch/hardware.h>
 #include <asm/arch/clk.h>

 /* Board oscillator frequency */
 #ifndef CONFIG_ZYNQ_PS_CLK_FREQ
 # define CONFIG_ZYNQ_PS_CLK_FREQ	33333333UL
 #endif

 /* Register bitfield defines */
 #define PLLCTRL_FBDIV_MASK	0x7f000
 #define PLLCTRL_FBDIV_SHIFT	12
 #define PLLCTRL_BPFORCE_MASK	(1 << 4)
 #define PLLCTRL_PWRDWN_MASK	2
 #define PLLCTRL_PWRDWN_SHIFT	1
 #define PLLCTRL_RESET_MASK	1
 #define PLLCTRL_RESET_SHIFT	0

 #define ZYNQ_CLK_MAXDIV		0x3f
 #define CLK_CTRL_DIV1_SHIFT	20
 #define CLK_CTRL_DIV1_MASK	(ZYNQ_CLK_MAXDIV << CLK_CTRL_DIV1_SHIFT)
 #define CLK_CTRL_DIV0_SHIFT	8
 #define CLK_CTRL_DIV0_MASK	(ZYNQ_CLK_MAXDIV << CLK_CTRL_DIV0_SHIFT)
 #define CLK_CTRL_SRCSEL_SHIFT	4
 #define CLK_CTRL_SRCSEL_MASK	(0x3 << CLK_CTRL_SRCSEL_SHIFT)

 #define CLK_CTRL_DIV2X_SHIFT	26
 #define CLK_CTRL_DIV2X_MASK	(ZYNQ_CLK_MAXDIV << CLK_CTRL_DIV2X_SHIFT)
 #define CLK_CTRL_DIV3X_SHIFT	20
 #define CLK_CTRL_DIV3X_MASK	(ZYNQ_CLK_MAXDIV << CLK_CTRL_DIV3X_SHIFT)

 #define ZYNQ_CLKMUX_SEL_0	0
 #define ZYNQ_CLKMUX_SEL_1	1
 #define ZYNQ_CLKMUX_SEL_2	2
 #define ZYNQ_CLKMUX_SEL_3	3

 DECLARE_GLOBAL_DATA_PTR;

 struct clk;

 /**
  * struct clk_ops:
  * @set_rate:	Function pointer to set_rate() implementation
  * @get_rate:	Function pointer to get_rate() implementation
  */
 struct clk_ops {
 	int (*set_rate)(struct clk *clk, unsigned long rate);
 	unsigned long (*get_rate)(struct clk *clk);
 };

 /**
  * struct clk:
  * @name:	Clock name
  * @frequency:	Currenct frequency
  * @parent:	Parent clock
  * @flags:	Clock flags
  * @reg:	Clock control register
  * @ops:	Clock operations
  */
 struct clk {
 	char		*name;
 	unsigned long	frequency;
 	enum zynq_clk	parent;
 	unsigned int	flags;
 	u32		*reg;
 	struct clk_ops	ops;
 };
 #define ZYNQ_CLK_FLAGS_HAS_2_DIVS	1

 static struct clk clks[clk_max];

 /**
  * __zynq_clk_cpu_get_parent() - Decode clock multiplexer
  * @srcsel:	Mux select value
  * Returns the clock identifier associated with the selected mux input.
  */
 static int __zynq_clk_cpu_get_parent(unsigned int srcsel)
 {
 	unsigned int ret;

 	switch (srcsel) {
 	case ZYNQ_CLKMUX_SEL_0:
 	case ZYNQ_CLKMUX_SEL_1:
 		ret = armpll_clk;
 		break;
 	case ZYNQ_CLKMUX_SEL_2:
 		ret = ddrpll_clk;
 		break;
 	case ZYNQ_CLKMUX_SEL_3:
 		ret = iopll_clk;
 		break;
 	default:
 		ret = armpll_clk;
 		break;
 	}

 	return ret;
 }

 /**
  * ddr2x_get_rate() - Get clock rate of DDR2x clock
  * @clk:	Clock handle
  * Returns the current clock rate of @clk.
  */
 static unsigned long ddr2x_get_rate(struct clk *clk)
 {
 	u32 clk_ctrl = readl(clk->reg);
 	u32 div = (clk_ctrl & CLK_CTRL_DIV2X_MASK) >> CLK_CTRL_DIV2X_SHIFT;

 	return DIV_ROUND_CLOSEST(zynq_clk_get_rate(clk->parent), div);
 }

 /**
  * ddr3x_get_rate() - Get clock rate of DDR3x clock
  * @clk:	Clock handle
  * Returns the current clock rate of @clk.
  */
 static unsigned long ddr3x_get_rate(struct clk *clk)
 {
 	u32 clk_ctrl = readl(clk->reg);
 	u32 div = (clk_ctrl & CLK_CTRL_DIV3X_MASK) >> CLK_CTRL_DIV3X_SHIFT;

 	return DIV_ROUND_CLOSEST(zynq_clk_get_rate(clk->parent), div);
 }

 static void init_ddr_clocks(void)
 {
 	u32 div0, div1;
 	unsigned long prate = zynq_clk_get_rate(ddrpll_clk);
 	u32 clk_ctrl = readl(&slcr_base->ddr_clk_ctrl);

 	/* DDR2x */
 	clks[ddr2x_clk].reg = &slcr_base->ddr_clk_ctrl;
 	clks[ddr2x_clk].parent = ddrpll_clk;
 	clks[ddr2x_clk].name = "ddr_2x";
 	clks[ddr2x_clk].frequency = ddr2x_get_rate(&clks[ddr2x_clk]);
 	clks[ddr2x_clk].ops.get_rate = ddr2x_get_rate;

 	/* DDR3x */
 	clks[ddr3x_clk].reg = &slcr_base->ddr_clk_ctrl;
 	clks[ddr3x_clk].parent = ddrpll_clk;
 	clks[ddr3x_clk].name = "ddr_3x";
 	clks[ddr3x_clk].frequency = ddr3x_get_rate(&clks[ddr3x_clk]);
 	clks[ddr3x_clk].ops.get_rate = ddr3x_get_rate;

 	/* DCI */
 	clk_ctrl = readl(&slcr_base->dci_clk_ctrl);
 	div0 = (clk_ctrl & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
 	div1 = (clk_ctrl & CLK_CTRL_DIV1_MASK) >> CLK_CTRL_DIV1_SHIFT;
 	clks[dci_clk].reg = &slcr_base->dci_clk_ctrl;
 	clks[dci_clk].parent = ddrpll_clk;
 	clks[dci_clk].frequency = DIV_ROUND_CLOSEST(
 			DIV_ROUND_CLOSEST(prate, div0), div1);
 	clks[dci_clk].name = "dci";

 	gd->bd->bi_ddr_freq = clks[ddr3x_clk].frequency / 1000000;
 }

 static void init_cpu_clocks(void)
 {
 	int clk_621;
 	u32 reg, div, srcsel;
 	enum zynq_clk parent;

 	reg = readl(&slcr_base->arm_clk_ctrl);
 	clk_621 = readl(&slcr_base->clk_621_true) & 1;
 	div = (reg & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
 	srcsel = (reg & CLK_CTRL_SRCSEL_MASK) >> CLK_CTRL_SRCSEL_SHIFT;
 	parent = __zynq_clk_cpu_get_parent(srcsel);

 	/* cpu clocks */
 	clks[cpu_6or4x_clk].reg = &slcr_base->arm_clk_ctrl;
 	clks[cpu_6or4x_clk].parent = parent;
 	clks[cpu_6or4x_clk].frequency = DIV_ROUND_CLOSEST(
 			zynq_clk_get_rate(parent), div);
 	clks[cpu_6or4x_clk].name = "cpu_6or4x";

 	clks[cpu_3or2x_clk].reg = &slcr_base->arm_clk_ctrl;
 	clks[cpu_3or2x_clk].parent = cpu_6or4x_clk;
 	clks[cpu_3or2x_clk].frequency = zynq_clk_get_rate(cpu_6or4x_clk) / 2;
 	clks[cpu_3or2x_clk].name = "cpu_3or2x";

 	clks[cpu_2x_clk].reg = &slcr_base->arm_clk_ctrl;
 	clks[cpu_2x_clk].parent = cpu_6or4x_clk;
 	clks[cpu_2x_clk].frequency = zynq_clk_get_rate(cpu_6or4x_clk) /
 			(2 + clk_621);
 	clks[cpu_2x_clk].name = "cpu_2x";

 	clks[cpu_1x_clk].reg = &slcr_base->arm_clk_ctrl;
 	clks[cpu_1x_clk].parent = cpu_6or4x_clk;
 	clks[cpu_1x_clk].frequency = zynq_clk_get_rate(cpu_6or4x_clk) /
 			(4 + 2 * clk_621);
 	clks[cpu_1x_clk].name = "cpu_1x";
 }

 /**
  * periph_calc_two_divs() - Calculate clock dividers
  * @cur_rate:	Current clock rate
  * @tgt_rate:	Target clock rate
  * @prate:	Parent clock rate
  * @div0:	First divider (output)
  * @div1:	Second divider (output)
  * Returns the actual clock rate possible.
  *
  * Calculates clock dividers for clocks with two 6-bit dividers.
  */
 static unsigned long periph_calc_two_divs(unsigned long cur_rate,
 		unsigned long tgt_rate, unsigned long prate, u32 *div0,
 		u32 *div1)
 {
 	long err, best_err = (long)(~0UL >> 1);
 	unsigned long rate, best_rate = 0;
 	u32 d0, d1;

 	for (d0 = 1; d0 <= ZYNQ_CLK_MAXDIV; d0++) {
 		for (d1 = 1; d1 <= ZYNQ_CLK_MAXDIV >> 1; d1++) {
 			rate = DIV_ROUND_CLOSEST(DIV_ROUND_CLOSEST(prate, d0),
 					d1);
 			err = abs(rate - tgt_rate);

 			if (err < best_err) {
 				*div0 = d0;
 				*div1 = d1;
 				best_err = err;
 				best_rate = rate;
 			}
 		}
 	}

 	return best_rate;
 }

 /**
  * zynq_clk_periph_set_rate() - Set clock rate
  * @clk:	Handle of the peripheral clock
  * @rate:	New clock rate
  * Sets the clock frequency of @clk to @rate. Returns zero on success.
  */
 static int zynq_clk_periph_set_rate(struct clk *clk,
 		unsigned long rate)
 {
 	u32 ctrl, div0 = 0, div1 = 0;
 	unsigned long prate, new_rate, cur_rate = clk->frequency;

 	ctrl = readl(clk->reg);
 	prate = zynq_clk_get_rate(clk->parent);
 	ctrl &= ~CLK_CTRL_DIV0_MASK;

 	if (clk->flags & ZYNQ_CLK_FLAGS_HAS_2_DIVS) {
 		ctrl &= ~CLK_CTRL_DIV1_MASK;
 		new_rate = periph_calc_two_divs(cur_rate, rate, prate, &div0,
 				&div1);
 		ctrl |= div1 << CLK_CTRL_DIV1_SHIFT;
 	} else {
 		div0 = DIV_ROUND_CLOSEST(prate, rate);
 		div0 &= ZYNQ_CLK_MAXDIV;
 		new_rate = DIV_ROUND_CLOSEST(rate, div0);
 	}

 	/* write new divs to hardware */
 	ctrl |= div0 << CLK_CTRL_DIV0_SHIFT;
 	writel(ctrl, clk->reg);

 	/* update frequency in clk framework */
 	clk->frequency = new_rate;

 	return 0;
 }

 /**
  * zynq_clk_periph_get_rate() - Get clock rate
  * @clk:	Handle of the peripheral clock
  * Returns the current clock rate of @clk.
  */
 static unsigned long zynq_clk_periph_get_rate(struct clk *clk)
 {
 	u32 clk_ctrl = readl(clk->reg);
 	u32 div0 = (clk_ctrl & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
 	u32 div1 = 1;

 	if (clk->flags & ZYNQ_CLK_FLAGS_HAS_2_DIVS)
 		div1 = (clk_ctrl & CLK_CTRL_DIV1_MASK) >> CLK_CTRL_DIV1_SHIFT;

 	/* a register value of zero == division by 1 */
 	if (!div0)
 		div0 = 1;
 	if (!div1)
 		div1 = 1;

 	return
 		DIV_ROUND_CLOSEST(
 			DIV_ROUND_CLOSEST(zynq_clk_get_rate(clk->parent), div0),
 			div1);
 }

 /**
  * __zynq_clk_periph_get_parent() - Decode clock multiplexer
  * @srcsel:	Mux select value
  * Returns the clock identifier associated with the selected mux input.
  */
 static enum zynq_clk __zynq_clk_periph_get_parent(u32 srcsel)
 {
 	switch (srcsel) {
 	case ZYNQ_CLKMUX_SEL_0:
 	case ZYNQ_CLKMUX_SEL_1:
 		return iopll_clk;
 	case ZYNQ_CLKMUX_SEL_2:
 		return armpll_clk;
 	case ZYNQ_CLKMUX_SEL_3:
 		return ddrpll_clk;
 	default:
 		return 0;
 	}
 }

 /**
  * zynq_clk_periph_get_parent() - Decode clock multiplexer
  * @clk:	Clock handle
  * Returns the clock identifier associated with the selected mux input.
  */
 static enum zynq_clk zynq_clk_periph_get_parent(struct clk *clk)
 {
 	u32 clk_ctrl = readl(clk->reg);
 	u32 srcsel = (clk_ctrl & CLK_CTRL_SRCSEL_MASK) >> CLK_CTRL_SRCSEL_SHIFT;

 	return __zynq_clk_periph_get_parent(srcsel);
 }

 /**
  * zynq_clk_register_periph_clk() - Set up a peripheral clock with the framework
  * @clk:	Pointer to struct clk for the clock
  * @ctrl:	Clock control register
  * @name:	PLL name
  * @two_divs:	Indicates whether the clock features one or two dividers
  */
 static int zynq_clk_register_periph_clk(struct clk *clk, u32 *ctrl, char *name,
 		bool two_divs)
 {
 	clk->name = name;
 	clk->reg = ctrl;
 	if (two_divs)
 		clk->flags = ZYNQ_CLK_FLAGS_HAS_2_DIVS;
 	clk->parent = zynq_clk_periph_get_parent(clk);
 	clk->frequency = zynq_clk_periph_get_rate(clk);
 	clk->ops.get_rate = zynq_clk_periph_get_rate;
 	clk->ops.set_rate = zynq_clk_periph_set_rate;

 	return 0;
 }

 static void init_periph_clocks(void)
 {
 	zynq_clk_register_periph_clk(&clks[gem0_clk], &slcr_base->gem0_clk_ctrl,
 				     "gem0", 1);
 	zynq_clk_register_periph_clk(&clks[gem1_clk], &slcr_base->gem1_clk_ctrl,
 				     "gem1", 1);

 	zynq_clk_register_periph_clk(&clks[smc_clk], &slcr_base->smc_clk_ctrl,
 				     "smc", 0);

 	zynq_clk_register_periph_clk(&clks[lqspi_clk],
 				     &slcr_base->lqspi_clk_ctrl, "lqspi", 0);

 	zynq_clk_register_periph_clk(&clks[sdio0_clk],
 				     &slcr_base->sdio_clk_ctrl, "sdio0", 0);
 	zynq_clk_register_periph_clk(&clks[sdio1_clk],
 				     &slcr_base->sdio_clk_ctrl, "sdio1", 0);

 	zynq_clk_register_periph_clk(&clks[spi0_clk], &slcr_base->spi_clk_ctrl,
 				     "spi0", 0);
 	zynq_clk_register_periph_clk(&clks[spi1_clk], &slcr_base->spi_clk_ctrl,
 				     "spi1", 0);

 	zynq_clk_register_periph_clk(&clks[uart0_clk],
 				     &slcr_base->uart_clk_ctrl, "uart0", 0);
 	zynq_clk_register_periph_clk(&clks[uart1_clk],
 				     &slcr_base->uart_clk_ctrl, "uart1", 0);

 	zynq_clk_register_periph_clk(&clks[dbg_trc_clk],
 				     &slcr_base->dbg_clk_ctrl, "dbg_trc", 0);
 	zynq_clk_register_periph_clk(&clks[dbg_apb_clk],
 				     &slcr_base->dbg_clk_ctrl, "dbg_apb", 0);

 	zynq_clk_register_periph_clk(&clks[pcap_clk],
 				     &slcr_base->pcap_clk_ctrl, "pcap", 0);

 	zynq_clk_register_periph_clk(&clks[fclk0_clk],
 				     &slcr_base->fpga0_clk_ctrl, "fclk0", 1);
 	zynq_clk_register_periph_clk(&clks[fclk1_clk],
 				     &slcr_base->fpga1_clk_ctrl, "fclk1", 1);
 	zynq_clk_register_periph_clk(&clks[fclk2_clk],
 				     &slcr_base->fpga2_clk_ctrl, "fclk2", 1);
 	zynq_clk_register_periph_clk(&clks[fclk3_clk],
 				     &slcr_base->fpga3_clk_ctrl, "fclk3", 1);
 }

 /**
  * zynq_clk_register_aper_clk() - Set up a APER clock with the framework
  * @clk:	Pointer to struct clk for the clock
  * @ctrl:	Clock control register
  * @name:	PLL name
  */
 static void zynq_clk_register_aper_clk(struct clk *clk, u32 *ctrl, char *name)
 {
 	clk->name = name;
 	clk->reg = ctrl;
 	clk->parent = cpu_1x_clk;
 	clk->frequency = zynq_clk_get_rate(clk->parent);
 }

 static void init_aper_clocks(void)
 {
 	zynq_clk_register_aper_clk(&clks[usb0_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "usb0_aper");
 	zynq_clk_register_aper_clk(&clks[usb1_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "usb1_aper");

 	zynq_clk_register_aper_clk(&clks[gem0_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "gem0_aper");
 	zynq_clk_register_aper_clk(&clks[gem1_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "gem1_aper");

 	zynq_clk_register_aper_clk(&clks[sdio0_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "sdio0_aper");
 	zynq_clk_register_aper_clk(&clks[sdio1_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "sdio1_aper");

 	zynq_clk_register_aper_clk(&clks[spi0_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "spi0_aper");
 	zynq_clk_register_aper_clk(&clks[spi1_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "spi1_aper");

 	zynq_clk_register_aper_clk(&clks[can0_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "can0_aper");
 	zynq_clk_register_aper_clk(&clks[can1_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "can1_aper");

 	zynq_clk_register_aper_clk(&clks[i2c0_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "i2c0_aper");
 	zynq_clk_register_aper_clk(&clks[i2c1_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "i2c1_aper");

 	zynq_clk_register_aper_clk(&clks[uart0_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "uart0_aper");
 	zynq_clk_register_aper_clk(&clks[uart1_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "uart1_aper");

 	zynq_clk_register_aper_clk(&clks[gpio_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "gpio_aper");

 	zynq_clk_register_aper_clk(&clks[lqspi_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "lqspi_aper");

 	zynq_clk_register_aper_clk(&clks[smc_aper_clk],
 				   &slcr_base->aper_clk_ctrl, "smc_aper");
 }

 /**
  * __zynq_clk_pll_get_rate() - Get PLL rate
  * @addr:	Address of the PLL's control register
  * Returns the current PLL output rate.
  */
 static unsigned long __zynq_clk_pll_get_rate(u32 *addr)
 {
 	u32 reg, mul, bypass;

 	reg = readl(addr);
 	bypass = reg & PLLCTRL_BPFORCE_MASK;
 	if (bypass)
 		mul = 1;
 	else
 		mul = (reg & PLLCTRL_FBDIV_MASK) >> PLLCTRL_FBDIV_SHIFT;

 	return CONFIG_ZYNQ_PS_CLK_FREQ * mul;
 }

 /**
  * zynq_clk_pll_get_rate() - Get PLL rate
  * @pll:	Handle of the PLL
  * Returns the current clock rate of @pll.
  */
 static unsigned long zynq_clk_pll_get_rate(struct clk *pll)
 {
 	return __zynq_clk_pll_get_rate(pll->reg);
 }

 /**
  * zynq_clk_register_pll() - Set up a PLL with the framework
  * @clk:	Pointer to struct clk for the PLL
  * @ctrl:	PLL control register
  * @name:	PLL name
  * @prate:	PLL input clock rate
  */
 static void zynq_clk_register_pll(struct clk *clk, u32 *ctrl, char *name,
 		unsigned long prate)
 {
 	clk->name = name;
 	clk->reg = ctrl;
 	clk->frequency = zynq_clk_pll_get_rate(clk);
 	clk->ops.get_rate = zynq_clk_pll_get_rate;
 }

 /**
  * clkid_2_register() - Get clock control register
  * @id:	Clock identifier of one of the PLLs
  * Returns the address of the requested PLL's control register.
  */
 static u32 *clkid_2_register(enum zynq_clk id)
 {
 	switch (id) {
 	case armpll_clk:
 		return &slcr_base->arm_pll_ctrl;
 	case ddrpll_clk:
 		return &slcr_base->ddr_pll_ctrl;
 	case iopll_clk:
 		return &slcr_base->io_pll_ctrl;
 	default:
 		return &slcr_base->io_pll_ctrl;
 	}
 }

 /* API */
 /**
  * zynq_clk_early_init() - Early init for the clock framework
  *
  * This function is called from before relocation and sets up the CPU clock
  * frequency in the global data struct.
  */
 void zynq_clk_early_init(void)
 {
 	u32 reg = readl(&slcr_base->arm_clk_ctrl);
 	u32 div = (reg & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
 	u32 srcsel = (reg & CLK_CTRL_SRCSEL_MASK) >> CLK_CTRL_SRCSEL_SHIFT;
 	enum zynq_clk parent = __zynq_clk_cpu_get_parent(srcsel);
 	u32 *pllreg = clkid_2_register(parent);
 	unsigned long prate = __zynq_clk_pll_get_rate(pllreg);

 	if (!div)
 		div = 1;

 	gd->cpu_clk = DIV_ROUND_CLOSEST(prate, div);
 }

 /**
  * get_uart_clk() - Get UART input frequency
  * @dev_index:	UART ID
  * Returns UART input clock frequency in Hz.
  *
  * Compared to zynq_clk_get_rate() this function is designed to work before
  * relocation and can be called when the serial UART is set up.
  */
 unsigned long get_uart_clk(int dev_index)
 {
 	u32 reg = readl(&slcr_base->uart_clk_ctrl);
 	u32 div = (reg & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
 	u32 srcsel = (reg & CLK_CTRL_SRCSEL_MASK) >> CLK_CTRL_SRCSEL_SHIFT;
 	enum zynq_clk parent = __zynq_clk_periph_get_parent(srcsel);
 	u32 *pllreg = clkid_2_register(parent);
 	unsigned long prate = __zynq_clk_pll_get_rate(pllreg);

 	if (!div)
 		div = 1;

 	return DIV_ROUND_CLOSEST(prate, div);
 }

 /**
  * set_cpu_clk_info() - Initialize clock framework
  * Always returns zero.
  *
  * This function is called from common code after relocation and sets up the
  * clock framework. The framework must not be used before this function had been
  * called.
  */
 int set_cpu_clk_info(void)
 {
 	zynq_clk_register_pll(&clks[armpll_clk], &slcr_base->arm_pll_ctrl,
 			      "armpll", CONFIG_ZYNQ_PS_CLK_FREQ);
 	zynq_clk_register_pll(&clks[ddrpll_clk], &slcr_base->ddr_pll_ctrl,
 			      "ddrpll", CONFIG_ZYNQ_PS_CLK_FREQ);
 	zynq_clk_register_pll(&clks[iopll_clk], &slcr_base->io_pll_ctrl,
 			      "iopll", CONFIG_ZYNQ_PS_CLK_FREQ);

 	init_ddr_clocks();
 	init_cpu_clocks();
 	init_periph_clocks();
 	init_aper_clocks();

 	gd->bd->bi_arm_freq = gd->cpu_clk / 1000000;
 	gd->bd->bi_dsp_freq = 0;

 	return 0;
 }

 /**
  * zynq_clk_get_rate() - Get clock rate
  * @clk:	Clock identifier
  * Returns the current clock rate of @clk on success or zero for an invalid
  * clock id.
  */
 unsigned long zynq_clk_get_rate(enum zynq_clk clk)
 {
 	if (clk < 0 || clk >= clk_max)
 		return 0;

 	return clks[clk].frequency;
 }

 /**
  * zynq_clk_set_rate() - Set clock rate
  * @clk:	Clock identifier
  * @rate:	Requested clock rate
  * Passes on the return value from the clock's set_rate() function or negative
  * errno.
  */
 int zynq_clk_set_rate(enum zynq_clk clk, unsigned long rate)
 {
 	if (clk < 0 || clk >= clk_max)
 		return -ENODEV;

 	if (clks[clk].ops.set_rate)
 		return clks[clk].ops.set_rate(&clks[clk], rate);

 	return -ENXIO;
 }

 /**
  * zynq_clk_get_name() - Get clock name
  * @clk:	Clock identifier
  * Returns the name of @clk.
  */
 const char *zynq_clk_get_name(enum zynq_clk clk)
 {
 	return clks[clk].name;
 }

 /**
  * soc_clk_dump() - Print clock frequencies
  * Returns zero on success
  *
  * Implementation for the clk dump command.
  */
 int soc_clk_dump(void)
 {
 	int i;

 	printf("clk\t\tfrequency\n");
 	for (i = 0; i < clk_max; i++) {
 		const char *name = zynq_clk_get_name(i);
 		if (name)
 			printf("%10s%20lu\n", name, zynq_clk_get_rate(i));
 	}

 	return 0;
 }
	/*
	* Copyright (C) 2013 Soren Brinkmann <soren.brinkmann@xilinx.com>
	* Copyright (C) 2013 Xilinx, Inc. All rights reserved.
	*
	* SPDX-License-Identifier: GPL-2.0+
	*/
	#include <common.h>
	#include <errno.h>
	#include <clk.h>
	#include <asm/io.h>
	#include <asm/arch/hardware.h>
	#include <asm/arch/clk.h>

	/* Board oscillator frequency */
	#ifndef CONFIG_ZYNQ_PS_CLK_FREQ
	# define CONFIG_ZYNQ_PS_CLK_FREQ 33333333UL
	#endif

	/* Register bitfield defines */
	#define PLLCTRL_FBDIV_MASK 0x7f000
	#define PLLCTRL_FBDIV_SHIFT 12
	#define PLLCTRL_BPFORCE_MASK (1 << 4)
	#define PLLCTRL_PWRDWN_MASK 2
	#define PLLCTRL_PWRDWN_SHIFT 1
	#define PLLCTRL_RESET_MASK 1
	#define PLLCTRL_RESET_SHIFT 0

	#define ZYNQ_CLK_MAXDIV 0x3f
	#define CLK_CTRL_DIV1_SHIFT 20
	#define CLK_CTRL_DIV1_MASK (ZYNQ_CLK_MAXDIV << CLK_CTRL_DIV1_SHIFT)
	#define CLK_CTRL_DIV0_SHIFT 8
	#define CLK_CTRL_DIV0_MASK (ZYNQ_CLK_MAXDIV << CLK_CTRL_DIV0_SHIFT)
	#define CLK_CTRL_SRCSEL_SHIFT 4
	#define CLK_CTRL_SRCSEL_MASK (0x3 << CLK_CTRL_SRCSEL_SHIFT)

	#define CLK_CTRL_DIV2X_SHIFT 26
	#define CLK_CTRL_DIV2X_MASK (ZYNQ_CLK_MAXDIV << CLK_CTRL_DIV2X_SHIFT)
	#define CLK_CTRL_DIV3X_SHIFT 20
	#define CLK_CTRL_DIV3X_MASK (ZYNQ_CLK_MAXDIV << CLK_CTRL_DIV3X_SHIFT)

	#define ZYNQ_CLKMUX_SEL_0 0
	#define ZYNQ_CLKMUX_SEL_1 1
	#define ZYNQ_CLKMUX_SEL_2 2
	#define ZYNQ_CLKMUX_SEL_3 3

	DECLARE_GLOBAL_DATA_PTR;

	struct clk;

	/**
	* struct clk_ops:
	* @set_rate: Function pointer to set_rate() implementation
	* @get_rate: Function pointer to get_rate() implementation
	*/
	struct clk_ops {
	int (set_rate)(struct clk clk, unsigned long rate);
	unsigned long (get_rate)(struct clk clk);
	};

	/**
	* struct clk:
	* @name: Clock name
	* @frequency: Currenct frequency
	* @parent: Parent clock
	* @flags: Clock flags
	* @reg: Clock control register
	* @ops: Clock operations
	*/
	struct clk {
	char *name;
	unsigned long frequency;
	enum zynq_clk parent;
	unsigned int flags;
	u32 *reg;
	struct clk_ops ops;
	};
	#define ZYNQ_CLK_FLAGS_HAS_2_DIVS 1

	static struct clk clks[clk_max];

	/**
	* __zynq_clk_cpu_get_parent() - Decode clock multiplexer
	* @srcsel: Mux select value
	* Returns the clock identifier associated with the selected mux input.
	*/
	static int __zynq_clk_cpu_get_parent(unsigned int srcsel)
	{
	unsigned int ret;

	switch (srcsel) {
	case ZYNQ_CLKMUX_SEL_0:
	case ZYNQ_CLKMUX_SEL_1:
	ret = armpll_clk;
	break;
	case ZYNQ_CLKMUX_SEL_2:
	ret = ddrpll_clk;
	break;
	case ZYNQ_CLKMUX_SEL_3:
	ret = iopll_clk;
	break;
	default:
	ret = armpll_clk;
	break;
	}

	return ret;
	}

	/**
	* ddr2x_get_rate() - Get clock rate of DDR2x clock
	* @clk: Clock handle
	* Returns the current clock rate of @clk.
	*/
	static unsigned long ddr2x_get_rate(struct clk *clk)
	{
	u32 clk_ctrl = readl(clk->reg);
	u32 div = (clk_ctrl & CLK_CTRL_DIV2X_MASK) >> CLK_CTRL_DIV2X_SHIFT;

	return DIV_ROUND_CLOSEST(zynq_clk_get_rate(clk->parent), div);
	}

	/**
	* ddr3x_get_rate() - Get clock rate of DDR3x clock
	* @clk: Clock handle
	* Returns the current clock rate of @clk.
	*/
	static unsigned long ddr3x_get_rate(struct clk *clk)
	{
	u32 clk_ctrl = readl(clk->reg);
	u32 div = (clk_ctrl & CLK_CTRL_DIV3X_MASK) >> CLK_CTRL_DIV3X_SHIFT;

	return DIV_ROUND_CLOSEST(zynq_clk_get_rate(clk->parent), div);
	}

	static void init_ddr_clocks(void)
	{
	u32 div0, div1;
	unsigned long prate = zynq_clk_get_rate(ddrpll_clk);
	u32 clk_ctrl = readl(&slcr_base->ddr_clk_ctrl);

	/* DDR2x */
	clks[ddr2x_clk].reg = &slcr_base->ddr_clk_ctrl;
	clks[ddr2x_clk].parent = ddrpll_clk;
	clks[ddr2x_clk].name = "ddr_2x";
	clks[ddr2x_clk].frequency = ddr2x_get_rate(&clks[ddr2x_clk]);
	clks[ddr2x_clk].ops.get_rate = ddr2x_get_rate;

	/* DDR3x */
	clks[ddr3x_clk].reg = &slcr_base->ddr_clk_ctrl;
	clks[ddr3x_clk].parent = ddrpll_clk;
	clks[ddr3x_clk].name = "ddr_3x";
	clks[ddr3x_clk].frequency = ddr3x_get_rate(&clks[ddr3x_clk]);
	clks[ddr3x_clk].ops.get_rate = ddr3x_get_rate;

	/* DCI */
	clk_ctrl = readl(&slcr_base->dci_clk_ctrl);
	div0 = (clk_ctrl & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
	div1 = (clk_ctrl & CLK_CTRL_DIV1_MASK) >> CLK_CTRL_DIV1_SHIFT;
	clks[dci_clk].reg = &slcr_base->dci_clk_ctrl;
	clks[dci_clk].parent = ddrpll_clk;
	clks[dci_clk].frequency = DIV_ROUND_CLOSEST(
	DIV_ROUND_CLOSEST(prate, div0), div1);
	clks[dci_clk].name = "dci";

	gd->bd->bi_ddr_freq = clks[ddr3x_clk].frequency / 1000000;
	}

	static void init_cpu_clocks(void)
	{
	int clk_621;
	u32 reg, div, srcsel;
	enum zynq_clk parent;

	reg = readl(&slcr_base->arm_clk_ctrl);
	clk_621 = readl(&slcr_base->clk_621_true) & 1;
	div = (reg & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
	srcsel = (reg & CLK_CTRL_SRCSEL_MASK) >> CLK_CTRL_SRCSEL_SHIFT;
	parent = __zynq_clk_cpu_get_parent(srcsel);

	/* cpu clocks */
	clks[cpu_6or4x_clk].reg = &slcr_base->arm_clk_ctrl;
	clks[cpu_6or4x_clk].parent = parent;
	clks[cpu_6or4x_clk].frequency = DIV_ROUND_CLOSEST(
	zynq_clk_get_rate(parent), div);
	clks[cpu_6or4x_clk].name = "cpu_6or4x";

	clks[cpu_3or2x_clk].reg = &slcr_base->arm_clk_ctrl;
	clks[cpu_3or2x_clk].parent = cpu_6or4x_clk;
	clks[cpu_3or2x_clk].frequency = zynq_clk_get_rate(cpu_6or4x_clk) / 2;
	clks[cpu_3or2x_clk].name = "cpu_3or2x";

	clks[cpu_2x_clk].reg = &slcr_base->arm_clk_ctrl;
	clks[cpu_2x_clk].parent = cpu_6or4x_clk;
	clks[cpu_2x_clk].frequency = zynq_clk_get_rate(cpu_6or4x_clk) /
	(2 + clk_621);
	clks[cpu_2x_clk].name = "cpu_2x";

	clks[cpu_1x_clk].reg = &slcr_base->arm_clk_ctrl;
	clks[cpu_1x_clk].parent = cpu_6or4x_clk;
	clks[cpu_1x_clk].frequency = zynq_clk_get_rate(cpu_6or4x_clk) /
	(4 + 2 * clk_621);
	clks[cpu_1x_clk].name = "cpu_1x";
	}

	/**
	* periph_calc_two_divs() - Calculate clock dividers
	* @cur_rate: Current clock rate
	* @tgt_rate: Target clock rate
	* @prate: Parent clock rate
	* @div0: First divider (output)
	* @div1: Second divider (output)
	* Returns the actual clock rate possible.
	*
	* Calculates clock dividers for clocks with two 6-bit dividers.
	*/
	static unsigned long periph_calc_two_divs(unsigned long cur_rate,
	unsigned long tgt_rate, unsigned long prate, u32 *div0,
	u32 *div1)
	{
	long err, best_err = (long)(~0UL >> 1);
	unsigned long rate, best_rate = 0;
	u32 d0, d1;

	for (d0 = 1; d0 <= ZYNQ_CLK_MAXDIV; d0++) {
	for (d1 = 1; d1 <= ZYNQ_CLK_MAXDIV >> 1; d1++) {
	rate = DIV_ROUND_CLOSEST(DIV_ROUND_CLOSEST(prate, d0),
	d1);
	err = abs(rate - tgt_rate);

	if (err < best_err) {
	*div0 = d0;
	*div1 = d1;
	best_err = err;
	best_rate = rate;
	}
	}
	}

	return best_rate;
	}

	/**
	* zynq_clk_periph_set_rate() - Set clock rate
	* @clk: Handle of the peripheral clock
	* @rate: New clock rate
	* Sets the clock frequency of @clk to @rate. Returns zero on success.
	*/
	static int zynq_clk_periph_set_rate(struct clk *clk,
	unsigned long rate)
	{
	u32 ctrl, div0 = 0, div1 = 0;
	unsigned long prate, new_rate, cur_rate = clk->frequency;

	ctrl = readl(clk->reg);
	prate = zynq_clk_get_rate(clk->parent);
	ctrl &= ~CLK_CTRL_DIV0_MASK;

	if (clk->flags & ZYNQ_CLK_FLAGS_HAS_2_DIVS) {
	ctrl &= ~CLK_CTRL_DIV1_MASK;
	new_rate = periph_calc_two_divs(cur_rate, rate, prate, &div0,
	&div1);
	ctrl \|= div1 << CLK_CTRL_DIV1_SHIFT;
	} else {
	div0 = DIV_ROUND_CLOSEST(prate, rate);
	div0 &= ZYNQ_CLK_MAXDIV;
	new_rate = DIV_ROUND_CLOSEST(rate, div0);
	}

	/* write new divs to hardware */
	ctrl \|= div0 << CLK_CTRL_DIV0_SHIFT;
	writel(ctrl, clk->reg);

	/* update frequency in clk framework */
	clk->frequency = new_rate;

	return 0;
	}

	/**
	* zynq_clk_periph_get_rate() - Get clock rate
	* @clk: Handle of the peripheral clock
	* Returns the current clock rate of @clk.
	*/
	static unsigned long zynq_clk_periph_get_rate(struct clk *clk)
	{
	u32 clk_ctrl = readl(clk->reg);
	u32 div0 = (clk_ctrl & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
	u32 div1 = 1;

	if (clk->flags & ZYNQ_CLK_FLAGS_HAS_2_DIVS)
	div1 = (clk_ctrl & CLK_CTRL_DIV1_MASK) >> CLK_CTRL_DIV1_SHIFT;

	/* a register value of zero == division by 1 */
	if (!div0)
	div0 = 1;
	if (!div1)
	div1 = 1;

	return
	DIV_ROUND_CLOSEST(
	DIV_ROUND_CLOSEST(zynq_clk_get_rate(clk->parent), div0),
	div1);
	}

	/**
	* __zynq_clk_periph_get_parent() - Decode clock multiplexer
	* @srcsel: Mux select value
	* Returns the clock identifier associated with the selected mux input.
	*/
	static enum zynq_clk __zynq_clk_periph_get_parent(u32 srcsel)
	{
	switch (srcsel) {
	case ZYNQ_CLKMUX_SEL_0:
	case ZYNQ_CLKMUX_SEL_1:
	return iopll_clk;
	case ZYNQ_CLKMUX_SEL_2:
	return armpll_clk;
	case ZYNQ_CLKMUX_SEL_3:
	return ddrpll_clk;
	default:
	return 0;
	}
	}

	/**
	* zynq_clk_periph_get_parent() - Decode clock multiplexer
	* @clk: Clock handle
	* Returns the clock identifier associated with the selected mux input.
	*/
	static enum zynq_clk zynq_clk_periph_get_parent(struct clk *clk)
	{
	u32 clk_ctrl = readl(clk->reg);
	u32 srcsel = (clk_ctrl & CLK_CTRL_SRCSEL_MASK) >> CLK_CTRL_SRCSEL_SHIFT;

	return __zynq_clk_periph_get_parent(srcsel);
	}

	/**
	* zynq_clk_register_periph_clk() - Set up a peripheral clock with the framework
	* @clk: Pointer to struct clk for the clock
	* @ctrl: Clock control register
	* @name: PLL name
	* @two_divs: Indicates whether the clock features one or two dividers
	*/
	static int zynq_clk_register_periph_clk(struct clk clk, u32 ctrl, char *name,
	bool two_divs)
	{
	clk->name = name;
	clk->reg = ctrl;
	if (two_divs)
	clk->flags = ZYNQ_CLK_FLAGS_HAS_2_DIVS;
	clk->parent = zynq_clk_periph_get_parent(clk);
	clk->frequency = zynq_clk_periph_get_rate(clk);
	clk->ops.get_rate = zynq_clk_periph_get_rate;
	clk->ops.set_rate = zynq_clk_periph_set_rate;

	return 0;
	}

	static void init_periph_clocks(void)
	{
	zynq_clk_register_periph_clk(&clks[gem0_clk], &slcr_base->gem0_clk_ctrl,
	"gem0", 1);
	zynq_clk_register_periph_clk(&clks[gem1_clk], &slcr_base->gem1_clk_ctrl,
	"gem1", 1);

	zynq_clk_register_periph_clk(&clks[smc_clk], &slcr_base->smc_clk_ctrl,
	"smc", 0);

	zynq_clk_register_periph_clk(&clks[lqspi_clk],
	&slcr_base->lqspi_clk_ctrl, "lqspi", 0);

	zynq_clk_register_periph_clk(&clks[sdio0_clk],
	&slcr_base->sdio_clk_ctrl, "sdio0", 0);
	zynq_clk_register_periph_clk(&clks[sdio1_clk],
	&slcr_base->sdio_clk_ctrl, "sdio1", 0);

	zynq_clk_register_periph_clk(&clks[spi0_clk], &slcr_base->spi_clk_ctrl,
	"spi0", 0);
	zynq_clk_register_periph_clk(&clks[spi1_clk], &slcr_base->spi_clk_ctrl,
	"spi1", 0);

	zynq_clk_register_periph_clk(&clks[uart0_clk],
	&slcr_base->uart_clk_ctrl, "uart0", 0);
	zynq_clk_register_periph_clk(&clks[uart1_clk],
	&slcr_base->uart_clk_ctrl, "uart1", 0);

	zynq_clk_register_periph_clk(&clks[dbg_trc_clk],
	&slcr_base->dbg_clk_ctrl, "dbg_trc", 0);
	zynq_clk_register_periph_clk(&clks[dbg_apb_clk],
	&slcr_base->dbg_clk_ctrl, "dbg_apb", 0);

	zynq_clk_register_periph_clk(&clks[pcap_clk],
	&slcr_base->pcap_clk_ctrl, "pcap", 0);

	zynq_clk_register_periph_clk(&clks[fclk0_clk],
	&slcr_base->fpga0_clk_ctrl, "fclk0", 1);
	zynq_clk_register_periph_clk(&clks[fclk1_clk],
	&slcr_base->fpga1_clk_ctrl, "fclk1", 1);
	zynq_clk_register_periph_clk(&clks[fclk2_clk],
	&slcr_base->fpga2_clk_ctrl, "fclk2", 1);
	zynq_clk_register_periph_clk(&clks[fclk3_clk],
	&slcr_base->fpga3_clk_ctrl, "fclk3", 1);
	}

	/**
	* zynq_clk_register_aper_clk() - Set up a APER clock with the framework
	* @clk: Pointer to struct clk for the clock
	* @ctrl: Clock control register
	* @name: PLL name
	*/
	static void zynq_clk_register_aper_clk(struct clk clk, u32 ctrl, char *name)
	{
	clk->name = name;
	clk->reg = ctrl;
	clk->parent = cpu_1x_clk;
	clk->frequency = zynq_clk_get_rate(clk->parent);
	}

	static void init_aper_clocks(void)
	{
	zynq_clk_register_aper_clk(&clks[usb0_aper_clk],
	&slcr_base->aper_clk_ctrl, "usb0_aper");
	zynq_clk_register_aper_clk(&clks[usb1_aper_clk],
	&slcr_base->aper_clk_ctrl, "usb1_aper");

	zynq_clk_register_aper_clk(&clks[gem0_aper_clk],
	&slcr_base->aper_clk_ctrl, "gem0_aper");
	zynq_clk_register_aper_clk(&clks[gem1_aper_clk],
	&slcr_base->aper_clk_ctrl, "gem1_aper");

	zynq_clk_register_aper_clk(&clks[sdio0_aper_clk],
	&slcr_base->aper_clk_ctrl, "sdio0_aper");
	zynq_clk_register_aper_clk(&clks[sdio1_aper_clk],
	&slcr_base->aper_clk_ctrl, "sdio1_aper");

	zynq_clk_register_aper_clk(&clks[spi0_aper_clk],
	&slcr_base->aper_clk_ctrl, "spi0_aper");
	zynq_clk_register_aper_clk(&clks[spi1_aper_clk],
	&slcr_base->aper_clk_ctrl, "spi1_aper");

	zynq_clk_register_aper_clk(&clks[can0_aper_clk],
	&slcr_base->aper_clk_ctrl, "can0_aper");
	zynq_clk_register_aper_clk(&clks[can1_aper_clk],
	&slcr_base->aper_clk_ctrl, "can1_aper");

	zynq_clk_register_aper_clk(&clks[i2c0_aper_clk],
	&slcr_base->aper_clk_ctrl, "i2c0_aper");
	zynq_clk_register_aper_clk(&clks[i2c1_aper_clk],
	&slcr_base->aper_clk_ctrl, "i2c1_aper");

	zynq_clk_register_aper_clk(&clks[uart0_aper_clk],
	&slcr_base->aper_clk_ctrl, "uart0_aper");
	zynq_clk_register_aper_clk(&clks[uart1_aper_clk],
	&slcr_base->aper_clk_ctrl, "uart1_aper");

	zynq_clk_register_aper_clk(&clks[gpio_aper_clk],
	&slcr_base->aper_clk_ctrl, "gpio_aper");

	zynq_clk_register_aper_clk(&clks[lqspi_aper_clk],
	&slcr_base->aper_clk_ctrl, "lqspi_aper");

	zynq_clk_register_aper_clk(&clks[smc_aper_clk],
	&slcr_base->aper_clk_ctrl, "smc_aper");
	}

	/**
	* __zynq_clk_pll_get_rate() - Get PLL rate
	* @addr: Address of the PLL's control register
	* Returns the current PLL output rate.
	*/
	static unsigned long __zynq_clk_pll_get_rate(u32 *addr)
	{
	u32 reg, mul, bypass;

	reg = readl(addr);
	bypass = reg & PLLCTRL_BPFORCE_MASK;
	if (bypass)
	mul = 1;
	else
	mul = (reg & PLLCTRL_FBDIV_MASK) >> PLLCTRL_FBDIV_SHIFT;

	return CONFIG_ZYNQ_PS_CLK_FREQ * mul;
	}

	/**
	* zynq_clk_pll_get_rate() - Get PLL rate
	* @pll: Handle of the PLL
	* Returns the current clock rate of @pll.
	*/
	static unsigned long zynq_clk_pll_get_rate(struct clk *pll)
	{
	return __zynq_clk_pll_get_rate(pll->reg);
	}

	/**
	* zynq_clk_register_pll() - Set up a PLL with the framework
	* @clk: Pointer to struct clk for the PLL
	* @ctrl: PLL control register
	* @name: PLL name
	* @prate: PLL input clock rate
	*/
	static void zynq_clk_register_pll(struct clk clk, u32 ctrl, char *name,
	unsigned long prate)
	{
	clk->name = name;
	clk->reg = ctrl;
	clk->frequency = zynq_clk_pll_get_rate(clk);
	clk->ops.get_rate = zynq_clk_pll_get_rate;
	}

	/**
	* clkid_2_register() - Get clock control register
	* @id: Clock identifier of one of the PLLs
	* Returns the address of the requested PLL's control register.
	*/
	static u32 *clkid_2_register(enum zynq_clk id)
	{
	switch (id) {
	case armpll_clk:
	return &slcr_base->arm_pll_ctrl;
	case ddrpll_clk:
	return &slcr_base->ddr_pll_ctrl;
	case iopll_clk:
	return &slcr_base->io_pll_ctrl;
	default:
	return &slcr_base->io_pll_ctrl;
	}
	}

	/* API */
	/**
	* zynq_clk_early_init() - Early init for the clock framework
	*
	* This function is called from before relocation and sets up the CPU clock
	* frequency in the global data struct.
	*/
	void zynq_clk_early_init(void)
	{
	u32 reg = readl(&slcr_base->arm_clk_ctrl);
	u32 div = (reg & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
	u32 srcsel = (reg & CLK_CTRL_SRCSEL_MASK) >> CLK_CTRL_SRCSEL_SHIFT;
	enum zynq_clk parent = __zynq_clk_cpu_get_parent(srcsel);
	u32 *pllreg = clkid_2_register(parent);
	unsigned long prate = __zynq_clk_pll_get_rate(pllreg);

	if (!div)
	div = 1;

	gd->cpu_clk = DIV_ROUND_CLOSEST(prate, div);
	}

	/**
	* get_uart_clk() - Get UART input frequency
	* @dev_index: UART ID
	* Returns UART input clock frequency in Hz.
	*
	* Compared to zynq_clk_get_rate() this function is designed to work before
	* relocation and can be called when the serial UART is set up.
	*/
	unsigned long get_uart_clk(int dev_index)
	{
	u32 reg = readl(&slcr_base->uart_clk_ctrl);
	u32 div = (reg & CLK_CTRL_DIV0_MASK) >> CLK_CTRL_DIV0_SHIFT;
	u32 srcsel = (reg & CLK_CTRL_SRCSEL_MASK) >> CLK_CTRL_SRCSEL_SHIFT;
	enum zynq_clk parent = __zynq_clk_periph_get_parent(srcsel);
	u32 *pllreg = clkid_2_register(parent);
	unsigned long prate = __zynq_clk_pll_get_rate(pllreg);

	if (!div)
	div = 1;

	return DIV_ROUND_CLOSEST(prate, div);
	}

	/**
	* set_cpu_clk_info() - Initialize clock framework
	* Always returns zero.
	*
	* This function is called from common code after relocation and sets up the
	* clock framework. The framework must not be used before this function had been
	* called.
	*/
	int set_cpu_clk_info(void)
	{
	zynq_clk_register_pll(&clks[armpll_clk], &slcr_base->arm_pll_ctrl,
	"armpll", CONFIG_ZYNQ_PS_CLK_FREQ);
	zynq_clk_register_pll(&clks[ddrpll_clk], &slcr_base->ddr_pll_ctrl,
	"ddrpll", CONFIG_ZYNQ_PS_CLK_FREQ);
	zynq_clk_register_pll(&clks[iopll_clk], &slcr_base->io_pll_ctrl,
	"iopll", CONFIG_ZYNQ_PS_CLK_FREQ);

	init_ddr_clocks();
	init_cpu_clocks();
	init_periph_clocks();
	init_aper_clocks();

	gd->bd->bi_arm_freq = gd->cpu_clk / 1000000;
	gd->bd->bi_dsp_freq = 0;

	return 0;
	}

	/**
	* zynq_clk_get_rate() - Get clock rate
	* @clk: Clock identifier
	* Returns the current clock rate of @clk on success or zero for an invalid
	* clock id.
	*/
	unsigned long zynq_clk_get_rate(enum zynq_clk clk)
	{
	if (clk < 0 \|\| clk >= clk_max)
	return 0;

	return clks[clk].frequency;
	}

	/**
	* zynq_clk_set_rate() - Set clock rate
	* @clk: Clock identifier
	* @rate: Requested clock rate
	* Passes on the return value from the clock's set_rate() function or negative
	* errno.
	*/
	int zynq_clk_set_rate(enum zynq_clk clk, unsigned long rate)
	{
	if (clk < 0 \|\| clk >= clk_max)
	return -ENODEV;

	if (clks[clk].ops.set_rate)
	return clks[clk].ops.set_rate(&clks[clk], rate);

	return -ENXIO;
	}

	/**
	* zynq_clk_get_name() - Get clock name
	* @clk: Clock identifier
	* Returns the name of @clk.
	*/
	const char *zynq_clk_get_name(enum zynq_clk clk)
	{
	return clks[clk].name;
	}

	/**
	* soc_clk_dump() - Print clock frequencies
	* Returns zero on success
	*
	* Implementation for the clk dump command.
	*/
	int soc_clk_dump(void)
	{
	int i;

	printf("clk\t\tfrequency\n");
	for (i = 0; i < clk_max; i++) {
	const char *name = zynq_clk_get_name(i);
	if (name)
	printf("%10s%20lu\n", name, zynq_clk_get_rate(i));
	}

	return 0;
	}