mirror of
https://github.com/AsahiLinux/u-boot
synced 2024-12-25 12:33:41 +00:00
de77811589
Restructure clock manager driver in the preparation to support A10. Move the Gen5 specific code to _gen5 files. - Change all uint32_t to u32 and change to use macro BIT(n) for bit shift. - Check return value from wait_for_bit(). So change return type to int for cm_write_with_phase() and cm_basic_init(). Signed-off-by: Ley Foon Tan <ley.foon.tan@intel.com>
524 lines
15 KiB
C
524 lines
15 KiB
C
/*
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* Copyright (C) 2013-2017 Altera Corporation <www.altera.com>
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*
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* SPDX-License-Identifier: GPL-2.0+
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*/
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#include <common.h>
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#include <asm/io.h>
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#include <asm/arch/clock_manager.h>
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#include <wait_bit.h>
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DECLARE_GLOBAL_DATA_PTR;
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static const struct socfpga_clock_manager *clock_manager_base =
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(struct socfpga_clock_manager *)SOCFPGA_CLKMGR_ADDRESS;
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/*
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* function to write the bypass register which requires a poll of the
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* busy bit
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*/
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static void cm_write_bypass(u32 val)
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{
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writel(val, &clock_manager_base->bypass);
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cm_wait_for_fsm();
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}
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/* function to write the ctrl register which requires a poll of the busy bit */
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static void cm_write_ctrl(u32 val)
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{
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writel(val, &clock_manager_base->ctrl);
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cm_wait_for_fsm();
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}
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/* function to write a clock register that has phase information */
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static int cm_write_with_phase(u32 value, u32 reg_address, u32 mask)
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{
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int ret;
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/* poll until phase is zero */
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ret = wait_for_bit(__func__, (const u32 *)reg_address, mask,
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false, 20000, false);
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if (ret)
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return ret;
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writel(value, reg_address);
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return wait_for_bit(__func__, (const u32 *)reg_address, mask,
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false, 20000, false);
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}
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/*
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* Setup clocks while making no assumptions about previous state of the clocks.
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*
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* Start by being paranoid and gate all sw managed clocks
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* Put all plls in bypass
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* Put all plls VCO registers back to reset value (bandgap power down).
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* Put peripheral and main pll src to reset value to avoid glitch.
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* Delay 5 us.
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* Deassert bandgap power down and set numerator and denominator
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* Start 7 us timer.
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* set internal dividers
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* Wait for 7 us timer.
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* Enable plls
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* Set external dividers while plls are locking
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* Wait for pll lock
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* Assert/deassert outreset all.
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* Take all pll's out of bypass
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* Clear safe mode
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* set source main and peripheral clocks
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* Ungate clocks
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*/
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int cm_basic_init(const struct cm_config * const cfg)
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{
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unsigned long end;
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int ret;
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/* Start by being paranoid and gate all sw managed clocks */
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/*
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* We need to disable nandclk
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* and then do another apb access before disabling
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* gatting off the rest of the periperal clocks.
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*/
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writel(~CLKMGR_PERPLLGRP_EN_NANDCLK_MASK &
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readl(&clock_manager_base->per_pll.en),
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&clock_manager_base->per_pll.en);
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/* DO NOT GATE OFF DEBUG CLOCKS & BRIDGE CLOCKS */
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writel(CLKMGR_MAINPLLGRP_EN_DBGTIMERCLK_MASK |
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CLKMGR_MAINPLLGRP_EN_DBGTRACECLK_MASK |
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CLKMGR_MAINPLLGRP_EN_DBGCLK_MASK |
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CLKMGR_MAINPLLGRP_EN_DBGATCLK_MASK |
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CLKMGR_MAINPLLGRP_EN_S2FUSER0CLK_MASK |
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CLKMGR_MAINPLLGRP_EN_L4MPCLK_MASK,
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&clock_manager_base->main_pll.en);
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writel(0, &clock_manager_base->sdr_pll.en);
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/* now we can gate off the rest of the peripheral clocks */
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writel(0, &clock_manager_base->per_pll.en);
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/* Put all plls in bypass */
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cm_write_bypass(CLKMGR_BYPASS_PERPLL | CLKMGR_BYPASS_SDRPLL |
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CLKMGR_BYPASS_MAINPLL);
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/* Put all plls VCO registers back to reset value. */
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writel(CLKMGR_MAINPLLGRP_VCO_RESET_VALUE &
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~CLKMGR_MAINPLLGRP_VCO_REGEXTSEL_MASK,
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&clock_manager_base->main_pll.vco);
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writel(CLKMGR_PERPLLGRP_VCO_RESET_VALUE &
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~CLKMGR_PERPLLGRP_VCO_REGEXTSEL_MASK,
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&clock_manager_base->per_pll.vco);
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writel(CLKMGR_SDRPLLGRP_VCO_RESET_VALUE &
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~CLKMGR_SDRPLLGRP_VCO_REGEXTSEL_MASK,
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&clock_manager_base->sdr_pll.vco);
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/*
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* The clocks to the flash devices and the L4_MAIN clocks can
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* glitch when coming out of safe mode if their source values
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* are different from their reset value. So the trick it to
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* put them back to their reset state, and change input
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* after exiting safe mode but before ungating the clocks.
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*/
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writel(CLKMGR_PERPLLGRP_SRC_RESET_VALUE,
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&clock_manager_base->per_pll.src);
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writel(CLKMGR_MAINPLLGRP_L4SRC_RESET_VALUE,
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&clock_manager_base->main_pll.l4src);
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/* read back for the required 5 us delay. */
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readl(&clock_manager_base->main_pll.vco);
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readl(&clock_manager_base->per_pll.vco);
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readl(&clock_manager_base->sdr_pll.vco);
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/*
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* We made sure bgpwr down was assert for 5 us. Now deassert BG PWR DN
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* with numerator and denominator.
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*/
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writel(cfg->main_vco_base, &clock_manager_base->main_pll.vco);
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writel(cfg->peri_vco_base, &clock_manager_base->per_pll.vco);
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writel(cfg->sdram_vco_base, &clock_manager_base->sdr_pll.vco);
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/*
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* Time starts here. Must wait 7 us from
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* BGPWRDN_SET(0) to VCO_ENABLE_SET(1).
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*/
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end = timer_get_us() + 7;
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/* main mpu */
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writel(cfg->mpuclk, &clock_manager_base->main_pll.mpuclk);
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/* altera group mpuclk */
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writel(cfg->altera_grp_mpuclk, &clock_manager_base->altera.mpuclk);
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/* main main clock */
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writel(cfg->mainclk, &clock_manager_base->main_pll.mainclk);
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/* main for dbg */
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writel(cfg->dbgatclk, &clock_manager_base->main_pll.dbgatclk);
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/* main for cfgs2fuser0clk */
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writel(cfg->cfg2fuser0clk,
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&clock_manager_base->main_pll.cfgs2fuser0clk);
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/* Peri emac0 50 MHz default to RMII */
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writel(cfg->emac0clk, &clock_manager_base->per_pll.emac0clk);
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/* Peri emac1 50 MHz default to RMII */
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writel(cfg->emac1clk, &clock_manager_base->per_pll.emac1clk);
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/* Peri QSPI */
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writel(cfg->mainqspiclk, &clock_manager_base->main_pll.mainqspiclk);
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writel(cfg->perqspiclk, &clock_manager_base->per_pll.perqspiclk);
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/* Peri pernandsdmmcclk */
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writel(cfg->mainnandsdmmcclk,
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&clock_manager_base->main_pll.mainnandsdmmcclk);
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writel(cfg->pernandsdmmcclk,
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&clock_manager_base->per_pll.pernandsdmmcclk);
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/* Peri perbaseclk */
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writel(cfg->perbaseclk, &clock_manager_base->per_pll.perbaseclk);
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/* Peri s2fuser1clk */
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writel(cfg->s2fuser1clk, &clock_manager_base->per_pll.s2fuser1clk);
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/* 7 us must have elapsed before we can enable the VCO */
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while (timer_get_us() < end)
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;
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/* Enable vco */
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/* main pll vco */
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writel(cfg->main_vco_base | CLKMGR_MAINPLLGRP_VCO_EN,
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&clock_manager_base->main_pll.vco);
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/* periferal pll */
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writel(cfg->peri_vco_base | CLKMGR_MAINPLLGRP_VCO_EN,
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&clock_manager_base->per_pll.vco);
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/* sdram pll vco */
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writel(cfg->sdram_vco_base | CLKMGR_MAINPLLGRP_VCO_EN,
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&clock_manager_base->sdr_pll.vco);
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/* L3 MP and L3 SP */
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writel(cfg->maindiv, &clock_manager_base->main_pll.maindiv);
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writel(cfg->dbgdiv, &clock_manager_base->main_pll.dbgdiv);
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writel(cfg->tracediv, &clock_manager_base->main_pll.tracediv);
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/* L4 MP, L4 SP, can0, and can1 */
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writel(cfg->perdiv, &clock_manager_base->per_pll.div);
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writel(cfg->gpiodiv, &clock_manager_base->per_pll.gpiodiv);
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cm_wait_for_lock(LOCKED_MASK);
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/* write the sdram clock counters before toggling outreset all */
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writel(cfg->ddrdqsclk & CLKMGR_SDRPLLGRP_DDRDQSCLK_CNT_MASK,
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&clock_manager_base->sdr_pll.ddrdqsclk);
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writel(cfg->ddr2xdqsclk & CLKMGR_SDRPLLGRP_DDR2XDQSCLK_CNT_MASK,
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&clock_manager_base->sdr_pll.ddr2xdqsclk);
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writel(cfg->ddrdqclk & CLKMGR_SDRPLLGRP_DDRDQCLK_CNT_MASK,
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&clock_manager_base->sdr_pll.ddrdqclk);
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writel(cfg->s2fuser2clk & CLKMGR_SDRPLLGRP_S2FUSER2CLK_CNT_MASK,
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&clock_manager_base->sdr_pll.s2fuser2clk);
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/*
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* after locking, but before taking out of bypass
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* assert/deassert outresetall
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*/
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u32 mainvco = readl(&clock_manager_base->main_pll.vco);
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/* assert main outresetall */
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writel(mainvco | CLKMGR_MAINPLLGRP_VCO_OUTRESETALL_MASK,
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&clock_manager_base->main_pll.vco);
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u32 periphvco = readl(&clock_manager_base->per_pll.vco);
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/* assert pheriph outresetall */
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writel(periphvco | CLKMGR_PERPLLGRP_VCO_OUTRESETALL_MASK,
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&clock_manager_base->per_pll.vco);
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/* assert sdram outresetall */
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writel(cfg->sdram_vco_base | CLKMGR_MAINPLLGRP_VCO_EN|
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CLKMGR_SDRPLLGRP_VCO_OUTRESETALL,
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&clock_manager_base->sdr_pll.vco);
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/* deassert main outresetall */
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writel(mainvco & ~CLKMGR_MAINPLLGRP_VCO_OUTRESETALL_MASK,
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&clock_manager_base->main_pll.vco);
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/* deassert pheriph outresetall */
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writel(periphvco & ~CLKMGR_PERPLLGRP_VCO_OUTRESETALL_MASK,
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&clock_manager_base->per_pll.vco);
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/* deassert sdram outresetall */
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writel(cfg->sdram_vco_base | CLKMGR_MAINPLLGRP_VCO_EN,
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&clock_manager_base->sdr_pll.vco);
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/*
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* now that we've toggled outreset all, all the clocks
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* are aligned nicely; so we can change any phase.
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*/
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ret = cm_write_with_phase(cfg->ddrdqsclk,
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(u32)&clock_manager_base->sdr_pll.ddrdqsclk,
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CLKMGR_SDRPLLGRP_DDRDQSCLK_PHASE_MASK);
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if (ret)
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return ret;
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/* SDRAM DDR2XDQSCLK */
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ret = cm_write_with_phase(cfg->ddr2xdqsclk,
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(u32)&clock_manager_base->sdr_pll.ddr2xdqsclk,
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CLKMGR_SDRPLLGRP_DDR2XDQSCLK_PHASE_MASK);
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if (ret)
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return ret;
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ret = cm_write_with_phase(cfg->ddrdqclk,
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(u32)&clock_manager_base->sdr_pll.ddrdqclk,
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CLKMGR_SDRPLLGRP_DDRDQCLK_PHASE_MASK);
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if (ret)
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return ret;
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ret = cm_write_with_phase(cfg->s2fuser2clk,
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(u32)&clock_manager_base->sdr_pll.s2fuser2clk,
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CLKMGR_SDRPLLGRP_S2FUSER2CLK_PHASE_MASK);
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if (ret)
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return ret;
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/* Take all three PLLs out of bypass when safe mode is cleared. */
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cm_write_bypass(0);
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/* clear safe mode */
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cm_write_ctrl(readl(&clock_manager_base->ctrl) | CLKMGR_CTRL_SAFEMODE);
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/*
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* now that safe mode is clear with clocks gated
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* it safe to change the source mux for the flashes the the L4_MAIN
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*/
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writel(cfg->persrc, &clock_manager_base->per_pll.src);
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writel(cfg->l4src, &clock_manager_base->main_pll.l4src);
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/* Now ungate non-hw-managed clocks */
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writel(~0, &clock_manager_base->main_pll.en);
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writel(~0, &clock_manager_base->per_pll.en);
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writel(~0, &clock_manager_base->sdr_pll.en);
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/* Clear the loss of lock bits (write 1 to clear) */
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writel(CLKMGR_INTER_SDRPLLLOST_MASK | CLKMGR_INTER_PERPLLLOST_MASK |
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CLKMGR_INTER_MAINPLLLOST_MASK,
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&clock_manager_base->inter);
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return 0;
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}
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static unsigned int cm_get_main_vco_clk_hz(void)
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{
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u32 reg, clock;
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/* get the main VCO clock */
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reg = readl(&clock_manager_base->main_pll.vco);
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clock = cm_get_osc_clk_hz(1);
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clock /= ((reg & CLKMGR_MAINPLLGRP_VCO_DENOM_MASK) >>
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CLKMGR_MAINPLLGRP_VCO_DENOM_OFFSET) + 1;
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clock *= ((reg & CLKMGR_MAINPLLGRP_VCO_NUMER_MASK) >>
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CLKMGR_MAINPLLGRP_VCO_NUMER_OFFSET) + 1;
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return clock;
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}
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static unsigned int cm_get_per_vco_clk_hz(void)
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{
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u32 reg, clock = 0;
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/* identify PER PLL clock source */
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reg = readl(&clock_manager_base->per_pll.vco);
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reg = (reg & CLKMGR_PERPLLGRP_VCO_SSRC_MASK) >>
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CLKMGR_PERPLLGRP_VCO_SSRC_OFFSET;
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if (reg == CLKMGR_VCO_SSRC_EOSC1)
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clock = cm_get_osc_clk_hz(1);
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else if (reg == CLKMGR_VCO_SSRC_EOSC2)
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clock = cm_get_osc_clk_hz(2);
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else if (reg == CLKMGR_VCO_SSRC_F2S)
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clock = cm_get_f2s_per_ref_clk_hz();
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/* get the PER VCO clock */
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reg = readl(&clock_manager_base->per_pll.vco);
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clock /= ((reg & CLKMGR_PERPLLGRP_VCO_DENOM_MASK) >>
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CLKMGR_PERPLLGRP_VCO_DENOM_OFFSET) + 1;
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clock *= ((reg & CLKMGR_PERPLLGRP_VCO_NUMER_MASK) >>
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CLKMGR_PERPLLGRP_VCO_NUMER_OFFSET) + 1;
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return clock;
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}
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unsigned long cm_get_mpu_clk_hz(void)
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{
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u32 reg, clock;
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clock = cm_get_main_vco_clk_hz();
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/* get the MPU clock */
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reg = readl(&clock_manager_base->altera.mpuclk);
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clock /= (reg + 1);
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reg = readl(&clock_manager_base->main_pll.mpuclk);
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clock /= (reg + 1);
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return clock;
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}
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unsigned long cm_get_sdram_clk_hz(void)
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{
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u32 reg, clock = 0;
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/* identify SDRAM PLL clock source */
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reg = readl(&clock_manager_base->sdr_pll.vco);
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reg = (reg & CLKMGR_SDRPLLGRP_VCO_SSRC_MASK) >>
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CLKMGR_SDRPLLGRP_VCO_SSRC_OFFSET;
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if (reg == CLKMGR_VCO_SSRC_EOSC1)
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clock = cm_get_osc_clk_hz(1);
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else if (reg == CLKMGR_VCO_SSRC_EOSC2)
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clock = cm_get_osc_clk_hz(2);
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else if (reg == CLKMGR_VCO_SSRC_F2S)
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clock = cm_get_f2s_sdr_ref_clk_hz();
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/* get the SDRAM VCO clock */
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reg = readl(&clock_manager_base->sdr_pll.vco);
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clock /= ((reg & CLKMGR_SDRPLLGRP_VCO_DENOM_MASK) >>
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CLKMGR_SDRPLLGRP_VCO_DENOM_OFFSET) + 1;
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clock *= ((reg & CLKMGR_SDRPLLGRP_VCO_NUMER_MASK) >>
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CLKMGR_SDRPLLGRP_VCO_NUMER_OFFSET) + 1;
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/* get the SDRAM (DDR_DQS) clock */
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reg = readl(&clock_manager_base->sdr_pll.ddrdqsclk);
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reg = (reg & CLKMGR_SDRPLLGRP_DDRDQSCLK_CNT_MASK) >>
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CLKMGR_SDRPLLGRP_DDRDQSCLK_CNT_OFFSET;
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clock /= (reg + 1);
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return clock;
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}
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unsigned int cm_get_l4_sp_clk_hz(void)
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{
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u32 reg, clock = 0;
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/* identify the source of L4 SP clock */
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reg = readl(&clock_manager_base->main_pll.l4src);
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reg = (reg & CLKMGR_MAINPLLGRP_L4SRC_L4SP) >>
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CLKMGR_MAINPLLGRP_L4SRC_L4SP_OFFSET;
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if (reg == CLKMGR_L4_SP_CLK_SRC_MAINPLL) {
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clock = cm_get_main_vco_clk_hz();
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/* get the clock prior L4 SP divider (main clk) */
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reg = readl(&clock_manager_base->altera.mainclk);
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clock /= (reg + 1);
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reg = readl(&clock_manager_base->main_pll.mainclk);
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clock /= (reg + 1);
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} else if (reg == CLKMGR_L4_SP_CLK_SRC_PERPLL) {
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clock = cm_get_per_vco_clk_hz();
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/* get the clock prior L4 SP divider (periph_base_clk) */
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reg = readl(&clock_manager_base->per_pll.perbaseclk);
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clock /= (reg + 1);
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}
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/* get the L4 SP clock which supplied to UART */
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reg = readl(&clock_manager_base->main_pll.maindiv);
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reg = (reg & CLKMGR_MAINPLLGRP_MAINDIV_L4SPCLK_MASK) >>
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CLKMGR_MAINPLLGRP_MAINDIV_L4SPCLK_OFFSET;
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clock = clock / (1 << reg);
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return clock;
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}
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unsigned int cm_get_mmc_controller_clk_hz(void)
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{
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u32 reg, clock = 0;
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/* identify the source of MMC clock */
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reg = readl(&clock_manager_base->per_pll.src);
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reg = (reg & CLKMGR_PERPLLGRP_SRC_SDMMC_MASK) >>
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CLKMGR_PERPLLGRP_SRC_SDMMC_OFFSET;
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if (reg == CLKMGR_SDMMC_CLK_SRC_F2S) {
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clock = cm_get_f2s_per_ref_clk_hz();
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} else if (reg == CLKMGR_SDMMC_CLK_SRC_MAIN) {
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clock = cm_get_main_vco_clk_hz();
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/* get the SDMMC clock */
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reg = readl(&clock_manager_base->main_pll.mainnandsdmmcclk);
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clock /= (reg + 1);
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} else if (reg == CLKMGR_SDMMC_CLK_SRC_PER) {
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clock = cm_get_per_vco_clk_hz();
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/* get the SDMMC clock */
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reg = readl(&clock_manager_base->per_pll.pernandsdmmcclk);
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clock /= (reg + 1);
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}
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/* further divide by 4 as we have fixed divider at wrapper */
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clock /= 4;
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return clock;
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}
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unsigned int cm_get_qspi_controller_clk_hz(void)
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{
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u32 reg, clock = 0;
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/* identify the source of QSPI clock */
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reg = readl(&clock_manager_base->per_pll.src);
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reg = (reg & CLKMGR_PERPLLGRP_SRC_QSPI_MASK) >>
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CLKMGR_PERPLLGRP_SRC_QSPI_OFFSET;
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if (reg == CLKMGR_QSPI_CLK_SRC_F2S) {
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clock = cm_get_f2s_per_ref_clk_hz();
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} else if (reg == CLKMGR_QSPI_CLK_SRC_MAIN) {
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clock = cm_get_main_vco_clk_hz();
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/* get the qspi clock */
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reg = readl(&clock_manager_base->main_pll.mainqspiclk);
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clock /= (reg + 1);
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} else if (reg == CLKMGR_QSPI_CLK_SRC_PER) {
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clock = cm_get_per_vco_clk_hz();
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/* get the qspi clock */
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reg = readl(&clock_manager_base->per_pll.perqspiclk);
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clock /= (reg + 1);
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}
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return clock;
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}
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unsigned int cm_get_spi_controller_clk_hz(void)
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{
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u32 reg, clock = 0;
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clock = cm_get_per_vco_clk_hz();
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/* get the clock prior L4 SP divider (periph_base_clk) */
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reg = readl(&clock_manager_base->per_pll.perbaseclk);
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clock /= (reg + 1);
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return clock;
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}
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void cm_print_clock_quick_summary(void)
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{
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printf("MPU %10ld kHz\n", cm_get_mpu_clk_hz() / 1000);
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printf("DDR %10ld kHz\n", cm_get_sdram_clk_hz() / 1000);
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printf("EOSC1 %8d kHz\n", cm_get_osc_clk_hz(1) / 1000);
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printf("EOSC2 %8d kHz\n", cm_get_osc_clk_hz(2) / 1000);
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printf("F2S_SDR_REF %8d kHz\n", cm_get_f2s_sdr_ref_clk_hz() / 1000);
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printf("F2S_PER_REF %8d kHz\n", cm_get_f2s_per_ref_clk_hz() / 1000);
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printf("MMC %8d kHz\n", cm_get_mmc_controller_clk_hz() / 1000);
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printf("QSPI %8d kHz\n", cm_get_qspi_controller_clk_hz() / 1000);
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printf("UART %8d kHz\n", cm_get_l4_sp_clk_hz() / 1000);
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printf("SPI %8d kHz\n", cm_get_spi_controller_clk_hz() / 1000);
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}
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