forked from Minki/linux
fcaf20360a
Based on 1 normalized pattern(s): the code contained herein is licensed under the gnu general public license you may obtain a copy of the gnu general public license version 2 or later at the following locations http www opensource org licenses gpl license html http www gnu org copyleft gpl html extracted by the scancode license scanner the SPDX license identifier GPL-2.0-or-later has been chosen to replace the boilerplate/reference in 161 file(s). Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Reviewed-by: Richard Fontana <rfontana@redhat.com> Reviewed-by: Allison Randal <allison@lohutok.net> Reviewed-by: Kate Stewart <kstewart@linuxfoundation.org> Cc: linux-spdx@vger.kernel.org Link: https://lkml.kernel.org/r/20190527070033.383790741@linutronix.de Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
250 lines
9.9 KiB
C
250 lines
9.9 KiB
C
// SPDX-License-Identifier: GPL-2.0-or-later
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/*
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* Copyright 2012 Freescale Semiconductor, Inc.
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*/
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#include <linux/clk/mxs.h>
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#include <linux/clkdev.h>
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#include <linux/clk.h>
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#include <linux/clk-provider.h>
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#include <linux/err.h>
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#include <linux/init.h>
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#include <linux/io.h>
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#include <linux/of.h>
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#include <linux/of_address.h>
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#include "clk.h"
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static void __iomem *clkctrl;
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#define CLKCTRL clkctrl
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#define PLL0CTRL0 (CLKCTRL + 0x0000)
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#define PLL1CTRL0 (CLKCTRL + 0x0020)
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#define PLL2CTRL0 (CLKCTRL + 0x0040)
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#define CPU (CLKCTRL + 0x0050)
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#define HBUS (CLKCTRL + 0x0060)
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#define XBUS (CLKCTRL + 0x0070)
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#define XTAL (CLKCTRL + 0x0080)
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#define SSP0 (CLKCTRL + 0x0090)
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#define SSP1 (CLKCTRL + 0x00a0)
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#define SSP2 (CLKCTRL + 0x00b0)
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#define SSP3 (CLKCTRL + 0x00c0)
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#define GPMI (CLKCTRL + 0x00d0)
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#define SPDIF (CLKCTRL + 0x00e0)
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#define EMI (CLKCTRL + 0x00f0)
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#define SAIF0 (CLKCTRL + 0x0100)
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#define SAIF1 (CLKCTRL + 0x0110)
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#define LCDIF (CLKCTRL + 0x0120)
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#define ETM (CLKCTRL + 0x0130)
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#define ENET (CLKCTRL + 0x0140)
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#define FLEXCAN (CLKCTRL + 0x0160)
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#define FRAC0 (CLKCTRL + 0x01b0)
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#define FRAC1 (CLKCTRL + 0x01c0)
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#define CLKSEQ (CLKCTRL + 0x01d0)
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#define BP_CPU_INTERRUPT_WAIT 12
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#define BP_SAIF_DIV_FRAC_EN 16
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#define BP_ENET_DIV_TIME 21
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#define BP_ENET_SLEEP 31
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#define BP_CLKSEQ_BYPASS_SAIF0 0
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#define BP_CLKSEQ_BYPASS_SSP0 3
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#define BP_FRAC0_IO1FRAC 16
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#define BP_FRAC0_IO0FRAC 24
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static void __iomem *digctrl;
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#define DIGCTRL digctrl
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#define BP_SAIF_CLKMUX 10
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/*
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* HW_SAIF_CLKMUX_SEL:
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* DIRECT(0x0): SAIF0 clock pins selected for SAIF0 input clocks, and SAIF1
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* clock pins selected for SAIF1 input clocks.
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* CROSSINPUT(0x1): SAIF1 clock inputs selected for SAIF0 input clocks, and
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* SAIF0 clock inputs selected for SAIF1 input clocks.
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* EXTMSTR0(0x2): SAIF0 clock pin selected for both SAIF0 and SAIF1 input
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* clocks.
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* EXTMSTR1(0x3): SAIF1 clock pin selected for both SAIF0 and SAIF1 input
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* clocks.
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*/
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int mxs_saif_clkmux_select(unsigned int clkmux)
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{
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if (clkmux > 0x3)
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return -EINVAL;
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writel_relaxed(0x3 << BP_SAIF_CLKMUX, DIGCTRL + CLR);
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writel_relaxed(clkmux << BP_SAIF_CLKMUX, DIGCTRL + SET);
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return 0;
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}
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static void __init clk_misc_init(void)
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{
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u32 val;
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/* Gate off cpu clock in WFI for power saving */
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writel_relaxed(1 << BP_CPU_INTERRUPT_WAIT, CPU + SET);
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/* 0 is a bad default value for a divider */
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writel_relaxed(1 << BP_ENET_DIV_TIME, ENET + SET);
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/* Clear BYPASS for SAIF */
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writel_relaxed(0x3 << BP_CLKSEQ_BYPASS_SAIF0, CLKSEQ + CLR);
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/* SAIF has to use frac div for functional operation */
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val = readl_relaxed(SAIF0);
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val |= 1 << BP_SAIF_DIV_FRAC_EN;
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writel_relaxed(val, SAIF0);
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val = readl_relaxed(SAIF1);
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val |= 1 << BP_SAIF_DIV_FRAC_EN;
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writel_relaxed(val, SAIF1);
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/* Extra fec clock setting */
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val = readl_relaxed(ENET);
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val &= ~(1 << BP_ENET_SLEEP);
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writel_relaxed(val, ENET);
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/*
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* Source ssp clock from ref_io than ref_xtal,
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* as ref_xtal only provides 24 MHz as maximum.
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*/
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writel_relaxed(0xf << BP_CLKSEQ_BYPASS_SSP0, CLKSEQ + CLR);
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/*
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* 480 MHz seems too high to be ssp clock source directly,
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* so set frac0 to get a 288 MHz ref_io0 and ref_io1.
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*/
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val = readl_relaxed(FRAC0);
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val &= ~((0x3f << BP_FRAC0_IO0FRAC) | (0x3f << BP_FRAC0_IO1FRAC));
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val |= (30 << BP_FRAC0_IO0FRAC) | (30 << BP_FRAC0_IO1FRAC);
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writel_relaxed(val, FRAC0);
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}
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static const char *const sel_cpu[] __initconst = { "ref_cpu", "ref_xtal", };
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static const char *const sel_io0[] __initconst = { "ref_io0", "ref_xtal", };
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static const char *const sel_io1[] __initconst = { "ref_io1", "ref_xtal", };
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static const char *const sel_pix[] __initconst = { "ref_pix", "ref_xtal", };
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static const char *const sel_gpmi[] __initconst = { "ref_gpmi", "ref_xtal", };
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static const char *const sel_pll0[] __initconst = { "pll0", "ref_xtal", };
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static const char *const cpu_sels[] __initconst = { "cpu_pll", "cpu_xtal", };
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static const char *const emi_sels[] __initconst = { "emi_pll", "emi_xtal", };
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static const char *const ptp_sels[] __initconst = { "ref_xtal", "pll0", };
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enum imx28_clk {
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ref_xtal, pll0, pll1, pll2, ref_cpu, ref_emi, ref_io0, ref_io1,
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ref_pix, ref_hsadc, ref_gpmi, saif0_sel, saif1_sel, gpmi_sel,
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ssp0_sel, ssp1_sel, ssp2_sel, ssp3_sel, emi_sel, etm_sel,
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lcdif_sel, cpu, ptp_sel, cpu_pll, cpu_xtal, hbus, xbus,
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ssp0_div, ssp1_div, ssp2_div, ssp3_div, gpmi_div, emi_pll,
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emi_xtal, lcdif_div, etm_div, ptp, saif0_div, saif1_div,
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clk32k_div, rtc, lradc, spdif_div, clk32k, pwm, uart, ssp0,
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ssp1, ssp2, ssp3, gpmi, spdif, emi, saif0, saif1, lcdif, etm,
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fec, can0, can1, usb0, usb1, usb0_phy, usb1_phy, enet_out,
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clk_max
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};
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static struct clk *clks[clk_max];
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static struct clk_onecell_data clk_data;
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static enum imx28_clk clks_init_on[] __initdata = {
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cpu, hbus, xbus, emi, uart,
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};
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static void __init mx28_clocks_init(struct device_node *np)
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{
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struct device_node *dcnp;
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u32 i;
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dcnp = of_find_compatible_node(NULL, NULL, "fsl,imx28-digctl");
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digctrl = of_iomap(dcnp, 0);
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WARN_ON(!digctrl);
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of_node_put(dcnp);
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clkctrl = of_iomap(np, 0);
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WARN_ON(!clkctrl);
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clk_misc_init();
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clks[ref_xtal] = mxs_clk_fixed("ref_xtal", 24000000);
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clks[pll0] = mxs_clk_pll("pll0", "ref_xtal", PLL0CTRL0, 17, 480000000);
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clks[pll1] = mxs_clk_pll("pll1", "ref_xtal", PLL1CTRL0, 17, 480000000);
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clks[pll2] = mxs_clk_pll("pll2", "ref_xtal", PLL2CTRL0, 23, 50000000);
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clks[ref_cpu] = mxs_clk_ref("ref_cpu", "pll0", FRAC0, 0);
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clks[ref_emi] = mxs_clk_ref("ref_emi", "pll0", FRAC0, 1);
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clks[ref_io1] = mxs_clk_ref("ref_io1", "pll0", FRAC0, 2);
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clks[ref_io0] = mxs_clk_ref("ref_io0", "pll0", FRAC0, 3);
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clks[ref_pix] = mxs_clk_ref("ref_pix", "pll0", FRAC1, 0);
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clks[ref_hsadc] = mxs_clk_ref("ref_hsadc", "pll0", FRAC1, 1);
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clks[ref_gpmi] = mxs_clk_ref("ref_gpmi", "pll0", FRAC1, 2);
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clks[saif0_sel] = mxs_clk_mux("saif0_sel", CLKSEQ, 0, 1, sel_pll0, ARRAY_SIZE(sel_pll0));
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clks[saif1_sel] = mxs_clk_mux("saif1_sel", CLKSEQ, 1, 1, sel_pll0, ARRAY_SIZE(sel_pll0));
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clks[gpmi_sel] = mxs_clk_mux("gpmi_sel", CLKSEQ, 2, 1, sel_gpmi, ARRAY_SIZE(sel_gpmi));
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clks[ssp0_sel] = mxs_clk_mux("ssp0_sel", CLKSEQ, 3, 1, sel_io0, ARRAY_SIZE(sel_io0));
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clks[ssp1_sel] = mxs_clk_mux("ssp1_sel", CLKSEQ, 4, 1, sel_io0, ARRAY_SIZE(sel_io0));
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clks[ssp2_sel] = mxs_clk_mux("ssp2_sel", CLKSEQ, 5, 1, sel_io1, ARRAY_SIZE(sel_io1));
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clks[ssp3_sel] = mxs_clk_mux("ssp3_sel", CLKSEQ, 6, 1, sel_io1, ARRAY_SIZE(sel_io1));
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clks[emi_sel] = mxs_clk_mux("emi_sel", CLKSEQ, 7, 1, emi_sels, ARRAY_SIZE(emi_sels));
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clks[etm_sel] = mxs_clk_mux("etm_sel", CLKSEQ, 8, 1, sel_cpu, ARRAY_SIZE(sel_cpu));
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clks[lcdif_sel] = mxs_clk_mux("lcdif_sel", CLKSEQ, 14, 1, sel_pix, ARRAY_SIZE(sel_pix));
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clks[cpu] = mxs_clk_mux("cpu", CLKSEQ, 18, 1, cpu_sels, ARRAY_SIZE(cpu_sels));
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clks[ptp_sel] = mxs_clk_mux("ptp_sel", ENET, 19, 1, ptp_sels, ARRAY_SIZE(ptp_sels));
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clks[cpu_pll] = mxs_clk_div("cpu_pll", "ref_cpu", CPU, 0, 6, 28);
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clks[cpu_xtal] = mxs_clk_div("cpu_xtal", "ref_xtal", CPU, 16, 10, 29);
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clks[hbus] = mxs_clk_div("hbus", "cpu", HBUS, 0, 5, 31);
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clks[xbus] = mxs_clk_div("xbus", "ref_xtal", XBUS, 0, 10, 31);
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clks[ssp0_div] = mxs_clk_div("ssp0_div", "ssp0_sel", SSP0, 0, 9, 29);
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clks[ssp1_div] = mxs_clk_div("ssp1_div", "ssp1_sel", SSP1, 0, 9, 29);
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clks[ssp2_div] = mxs_clk_div("ssp2_div", "ssp2_sel", SSP2, 0, 9, 29);
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clks[ssp3_div] = mxs_clk_div("ssp3_div", "ssp3_sel", SSP3, 0, 9, 29);
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clks[gpmi_div] = mxs_clk_div("gpmi_div", "gpmi_sel", GPMI, 0, 10, 29);
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clks[emi_pll] = mxs_clk_div("emi_pll", "ref_emi", EMI, 0, 6, 28);
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clks[emi_xtal] = mxs_clk_div("emi_xtal", "ref_xtal", EMI, 8, 4, 29);
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clks[lcdif_div] = mxs_clk_div("lcdif_div", "lcdif_sel", LCDIF, 0, 13, 29);
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clks[etm_div] = mxs_clk_div("etm_div", "etm_sel", ETM, 0, 7, 29);
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clks[ptp] = mxs_clk_div("ptp", "ptp_sel", ENET, 21, 6, 27);
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clks[saif0_div] = mxs_clk_frac("saif0_div", "saif0_sel", SAIF0, 0, 16, 29);
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clks[saif1_div] = mxs_clk_frac("saif1_div", "saif1_sel", SAIF1, 0, 16, 29);
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clks[clk32k_div] = mxs_clk_fixed_factor("clk32k_div", "ref_xtal", 1, 750);
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clks[rtc] = mxs_clk_fixed_factor("rtc", "ref_xtal", 1, 768);
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clks[lradc] = mxs_clk_fixed_factor("lradc", "clk32k", 1, 16);
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clks[spdif_div] = mxs_clk_fixed_factor("spdif_div", "pll0", 1, 4);
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clks[clk32k] = mxs_clk_gate("clk32k", "clk32k_div", XTAL, 26);
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clks[pwm] = mxs_clk_gate("pwm", "ref_xtal", XTAL, 29);
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clks[uart] = mxs_clk_gate("uart", "ref_xtal", XTAL, 31);
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clks[ssp0] = mxs_clk_gate("ssp0", "ssp0_div", SSP0, 31);
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clks[ssp1] = mxs_clk_gate("ssp1", "ssp1_div", SSP1, 31);
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clks[ssp2] = mxs_clk_gate("ssp2", "ssp2_div", SSP2, 31);
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clks[ssp3] = mxs_clk_gate("ssp3", "ssp3_div", SSP3, 31);
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clks[gpmi] = mxs_clk_gate("gpmi", "gpmi_div", GPMI, 31);
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clks[spdif] = mxs_clk_gate("spdif", "spdif_div", SPDIF, 31);
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clks[emi] = mxs_clk_gate("emi", "emi_sel", EMI, 31);
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clks[saif0] = mxs_clk_gate("saif0", "saif0_div", SAIF0, 31);
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clks[saif1] = mxs_clk_gate("saif1", "saif1_div", SAIF1, 31);
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clks[lcdif] = mxs_clk_gate("lcdif", "lcdif_div", LCDIF, 31);
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clks[etm] = mxs_clk_gate("etm", "etm_div", ETM, 31);
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clks[fec] = mxs_clk_gate("fec", "hbus", ENET, 30);
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clks[can0] = mxs_clk_gate("can0", "ref_xtal", FLEXCAN, 30);
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clks[can1] = mxs_clk_gate("can1", "ref_xtal", FLEXCAN, 28);
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clks[usb0] = mxs_clk_gate("usb0", "usb0_phy", DIGCTRL, 2);
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clks[usb1] = mxs_clk_gate("usb1", "usb1_phy", DIGCTRL, 16);
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clks[usb0_phy] = clk_register_gate(NULL, "usb0_phy", "pll0", 0, PLL0CTRL0, 18, 0, &mxs_lock);
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clks[usb1_phy] = clk_register_gate(NULL, "usb1_phy", "pll1", 0, PLL1CTRL0, 18, 0, &mxs_lock);
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clks[enet_out] = clk_register_gate(NULL, "enet_out", "pll2", 0, ENET, 18, 0, &mxs_lock);
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for (i = 0; i < ARRAY_SIZE(clks); i++)
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if (IS_ERR(clks[i])) {
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pr_err("i.MX28 clk %d: register failed with %ld\n",
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i, PTR_ERR(clks[i]));
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return;
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}
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clk_data.clks = clks;
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clk_data.clk_num = ARRAY_SIZE(clks);
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of_clk_add_provider(np, of_clk_src_onecell_get, &clk_data);
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clk_register_clkdev(clks[enet_out], NULL, "enet_out");
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for (i = 0; i < ARRAY_SIZE(clks_init_on); i++)
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clk_prepare_enable(clks[clks_init_on[i]]);
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}
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CLK_OF_DECLARE(imx28_clkctrl, "fsl,imx28-clkctrl", mx28_clocks_init);
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