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ef76ebb1ef
The maximum device and arm speeds can be determined by reading EFUSE_BOOTROM register. As there is already a framework for reading this register, adding support for all possible speeds on k2g devices. Signed-off-by: Lokesh Vutla <lokeshvutla@ti.com> Signed-off-by: Nishanth Menon <nm@ti.com> Reviewed-by: Tom Rini <trini@konsulko.com>
421 lines
9.8 KiB
C
421 lines
9.8 KiB
C
/*
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* Keystone2: pll initialization
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*
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* (C) Copyright 2012-2014
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* Texas Instruments Incorporated, <www.ti.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/arch/clock.h>
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#include <asm/arch/clock_defs.h>
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/* DEV and ARM speed definitions as specified in DEVSPEED register */
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int __weak speeds[DEVSPEED_NUMSPDS] = {
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SPD1000,
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SPD1200,
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SPD1350,
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SPD1400,
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SPD1500,
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SPD1400,
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SPD1350,
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SPD1200,
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SPD1000,
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SPD800,
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};
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const struct keystone_pll_regs keystone_pll_regs[] = {
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[CORE_PLL] = {KS2_MAINPLLCTL0, KS2_MAINPLLCTL1},
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[PASS_PLL] = {KS2_PASSPLLCTL0, KS2_PASSPLLCTL1},
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[TETRIS_PLL] = {KS2_ARMPLLCTL0, KS2_ARMPLLCTL1},
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[DDR3A_PLL] = {KS2_DDR3APLLCTL0, KS2_DDR3APLLCTL1},
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[DDR3B_PLL] = {KS2_DDR3BPLLCTL0, KS2_DDR3BPLLCTL1},
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[UART_PLL] = {KS2_UARTPLLCTL0, KS2_UARTPLLCTL1},
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};
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inline void pll_pa_clk_sel(void)
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{
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setbits_le32(keystone_pll_regs[PASS_PLL].reg1, CFG_PLLCTL1_PAPLL_MASK);
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}
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static void wait_for_completion(const struct pll_init_data *data)
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{
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int i;
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for (i = 0; i < 100; i++) {
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sdelay(450);
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if (!(pllctl_reg_read(data->pll, stat) & PLLSTAT_GOSTAT_MASK))
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break;
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}
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}
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static inline void bypass_main_pll(const struct pll_init_data *data)
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{
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pllctl_reg_clrbits(data->pll, ctl, PLLCTL_PLLENSRC_MASK |
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PLLCTL_PLLEN_MASK);
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/* 4 cycles of reference clock CLKIN*/
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sdelay(340);
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}
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static void configure_mult_div(const struct pll_init_data *data)
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{
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u32 pllm, plld, bwadj;
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pllm = data->pll_m - 1;
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plld = (data->pll_d - 1) & CFG_PLLCTL0_PLLD_MASK;
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/* Program Multiplier */
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if (data->pll == MAIN_PLL)
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pllctl_reg_write(data->pll, mult, pllm & PLLM_MULT_LO_MASK);
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clrsetbits_le32(keystone_pll_regs[data->pll].reg0,
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CFG_PLLCTL0_PLLM_MASK,
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pllm << CFG_PLLCTL0_PLLM_SHIFT);
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/* Program BWADJ */
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bwadj = (data->pll_m - 1) >> 1; /* Divide pllm by 2 */
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clrsetbits_le32(keystone_pll_regs[data->pll].reg0,
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CFG_PLLCTL0_BWADJ_MASK,
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(bwadj << CFG_PLLCTL0_BWADJ_SHIFT) &
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CFG_PLLCTL0_BWADJ_MASK);
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bwadj = bwadj >> CFG_PLLCTL0_BWADJ_BITS;
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clrsetbits_le32(keystone_pll_regs[data->pll].reg1,
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CFG_PLLCTL1_BWADJ_MASK, bwadj);
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/* Program Divider */
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clrsetbits_le32(keystone_pll_regs[data->pll].reg0,
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CFG_PLLCTL0_PLLD_MASK, plld);
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}
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void configure_main_pll(const struct pll_init_data *data)
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{
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u32 tmp, pllod, i, alnctl_val = 0;
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u32 *offset;
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pllod = data->pll_od - 1;
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/* 100 micro sec for stabilization */
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sdelay(210000);
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tmp = pllctl_reg_read(data->pll, secctl);
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/* Check for Bypass */
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if (tmp & SECCTL_BYPASS_MASK) {
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setbits_le32(keystone_pll_regs[data->pll].reg1,
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CFG_PLLCTL1_ENSAT_MASK);
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bypass_main_pll(data);
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/* Powerdown and powerup Main Pll */
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pllctl_reg_setbits(data->pll, secctl, SECCTL_BYPASS_MASK);
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pllctl_reg_setbits(data->pll, ctl, PLLCTL_PLLPWRDN_MASK);
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/* 5 micro sec */
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sdelay(21000);
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pllctl_reg_clrbits(data->pll, ctl, PLLCTL_PLLPWRDN_MASK);
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} else {
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bypass_main_pll(data);
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}
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configure_mult_div(data);
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/* Program Output Divider */
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pllctl_reg_rmw(data->pll, secctl, SECCTL_OP_DIV_MASK,
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((pllod << SECCTL_OP_DIV_SHIFT) & SECCTL_OP_DIV_MASK));
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/* Program PLLDIVn */
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wait_for_completion(data);
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for (i = 0; i < PLLDIV_MAX; i++) {
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if (i < 3)
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offset = pllctl_reg(data->pll, div1) + i;
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else
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offset = pllctl_reg(data->pll, div4) + (i - 3);
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if (divn_val[i] != -1) {
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__raw_writel(divn_val[i] | PLLDIV_ENABLE_MASK, offset);
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alnctl_val |= BIT(i);
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}
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}
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if (alnctl_val) {
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pllctl_reg_setbits(data->pll, alnctl, alnctl_val);
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/*
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* Set GOSET bit in PLLCMD to initiate the GO operation
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* to change the divide
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*/
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pllctl_reg_setbits(data->pll, cmd, PLLSTAT_GOSTAT_MASK);
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wait_for_completion(data);
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}
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/* Reset PLL */
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pllctl_reg_setbits(data->pll, ctl, PLLCTL_PLLRST_MASK);
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sdelay(21000); /* Wait for a minimum of 7 us*/
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pllctl_reg_clrbits(data->pll, ctl, PLLCTL_PLLRST_MASK);
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sdelay(105000); /* Wait for PLL Lock time (min 50 us) */
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/* Enable PLL */
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pllctl_reg_clrbits(data->pll, secctl, SECCTL_BYPASS_MASK);
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pllctl_reg_setbits(data->pll, ctl, PLLCTL_PLLEN_MASK);
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}
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void configure_secondary_pll(const struct pll_init_data *data)
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{
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int pllod = data->pll_od - 1;
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/* Enable Bypass mode */
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setbits_le32(keystone_pll_regs[data->pll].reg1, CFG_PLLCTL1_ENSAT_MASK);
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setbits_le32(keystone_pll_regs[data->pll].reg0,
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CFG_PLLCTL0_BYPASS_MASK);
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/* Enable Glitch free bypass for ARM PLL */
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if (cpu_is_k2hk() && data->pll == TETRIS_PLL)
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clrbits_le32(KS2_MISC_CTRL, MISC_CTL1_ARM_PLL_EN);
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configure_mult_div(data);
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/* Program Output Divider */
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clrsetbits_le32(keystone_pll_regs[data->pll].reg0,
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CFG_PLLCTL0_CLKOD_MASK,
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(pllod << CFG_PLLCTL0_CLKOD_SHIFT) &
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CFG_PLLCTL0_CLKOD_MASK);
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/* Reset PLL */
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setbits_le32(keystone_pll_regs[data->pll].reg1, CFG_PLLCTL1_RST_MASK);
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/* Wait for 5 micro seconds */
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sdelay(21000);
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/* Select the Output of PASS PLL as input to PASS */
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if (data->pll == PASS_PLL && cpu_is_k2hk())
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pll_pa_clk_sel();
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/* Select the Output of ARM PLL as input to ARM */
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if (data->pll == TETRIS_PLL)
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setbits_le32(KS2_MISC_CTRL, MISC_CTL1_ARM_PLL_EN);
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clrbits_le32(keystone_pll_regs[data->pll].reg1, CFG_PLLCTL1_RST_MASK);
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/* Wait for 500 * REFCLK cucles * (PLLD + 1) */
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sdelay(105000);
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/* Switch to PLL mode */
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clrbits_le32(keystone_pll_regs[data->pll].reg0,
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CFG_PLLCTL0_BYPASS_MASK);
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}
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void init_pll(const struct pll_init_data *data)
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{
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if (data->pll == MAIN_PLL)
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configure_main_pll(data);
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else
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configure_secondary_pll(data);
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/*
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* This is required to provide a delay between multiple
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* consequent PPL configurations
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*/
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sdelay(210000);
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}
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void init_plls(void)
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{
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struct pll_init_data *data;
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int pll;
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for (pll = MAIN_PLL; pll < MAX_PLL_COUNT; pll++) {
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data = get_pll_init_data(pll);
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if (data)
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init_pll(data);
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}
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}
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static int get_max_speed(u32 val, u32 speed_supported, int *spds)
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{
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int speed;
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/* Left most setbit gives the speed */
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for (speed = DEVSPEED_NUMSPDS; speed >= 0; speed--) {
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if ((val & BIT(speed)) & speed_supported)
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return spds[speed];
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}
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/* If no bit is set, return minimum speed */
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if (cpu_is_k2g())
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return SPD200;
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else
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return SPD800;
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}
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static inline u32 read_efuse_bootrom(void)
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{
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if (cpu_is_k2hk() && (cpu_revision() <= 1))
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return __raw_readl(KS2_REV1_DEVSPEED);
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else
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return __raw_readl(KS2_EFUSE_BOOTROM);
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}
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int get_max_arm_speed(int *spds)
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{
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u32 armspeed = read_efuse_bootrom();
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armspeed = (armspeed & DEVSPEED_ARMSPEED_MASK) >>
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DEVSPEED_ARMSPEED_SHIFT;
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return get_max_speed(armspeed, ARM_SUPPORTED_SPEEDS, spds);
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}
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int get_max_dev_speed(int *spds)
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{
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u32 devspeed = read_efuse_bootrom();
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devspeed = (devspeed & DEVSPEED_DEVSPEED_MASK) >>
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DEVSPEED_DEVSPEED_SHIFT;
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return get_max_speed(devspeed, DEV_SUPPORTED_SPEEDS, spds);
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}
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/**
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* pll_freq_get - get pll frequency
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* @pll: pll identifier
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*/
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static unsigned long pll_freq_get(int pll)
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{
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unsigned long mult = 1, prediv = 1, output_div = 2;
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unsigned long ret;
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u32 tmp, reg;
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if (pll == MAIN_PLL) {
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ret = external_clk[sys_clk];
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if (pllctl_reg_read(pll, ctl) & PLLCTL_PLLEN_MASK) {
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/* PLL mode */
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tmp = __raw_readl(KS2_MAINPLLCTL0);
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prediv = (tmp & CFG_PLLCTL0_PLLD_MASK) + 1;
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mult = ((tmp & CFG_PLLCTL0_PLLM_HI_MASK) >>
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CFG_PLLCTL0_PLLM_SHIFT |
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(pllctl_reg_read(pll, mult) &
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PLLM_MULT_LO_MASK)) + 1;
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output_div = ((pllctl_reg_read(pll, secctl) &
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SECCTL_OP_DIV_MASK) >>
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SECCTL_OP_DIV_SHIFT) + 1;
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ret = ret / prediv / output_div * mult;
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}
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} else {
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switch (pll) {
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case PASS_PLL:
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ret = external_clk[pa_clk];
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reg = KS2_PASSPLLCTL0;
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break;
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case TETRIS_PLL:
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ret = external_clk[tetris_clk];
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reg = KS2_ARMPLLCTL0;
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break;
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case DDR3A_PLL:
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ret = external_clk[ddr3a_clk];
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reg = KS2_DDR3APLLCTL0;
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break;
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case DDR3B_PLL:
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ret = external_clk[ddr3b_clk];
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reg = KS2_DDR3BPLLCTL0;
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break;
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case UART_PLL:
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ret = external_clk[uart_clk];
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reg = KS2_UARTPLLCTL0;
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break;
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default:
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return 0;
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}
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tmp = __raw_readl(reg);
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if (!(tmp & CFG_PLLCTL0_BYPASS_MASK)) {
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/* Bypass disabled */
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prediv = (tmp & CFG_PLLCTL0_PLLD_MASK) + 1;
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mult = ((tmp & CFG_PLLCTL0_PLLM_MASK) >>
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CFG_PLLCTL0_PLLM_SHIFT) + 1;
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output_div = ((tmp & CFG_PLLCTL0_CLKOD_MASK) >>
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CFG_PLLCTL0_CLKOD_SHIFT) + 1;
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ret = ((ret / prediv) * mult) / output_div;
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}
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}
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return ret;
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}
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unsigned long clk_get_rate(unsigned int clk)
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{
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unsigned long freq = 0;
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switch (clk) {
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case core_pll_clk:
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freq = pll_freq_get(CORE_PLL);
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break;
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case pass_pll_clk:
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freq = pll_freq_get(PASS_PLL);
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break;
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case tetris_pll_clk:
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if (!cpu_is_k2e())
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freq = pll_freq_get(TETRIS_PLL);
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break;
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case ddr3a_pll_clk:
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freq = pll_freq_get(DDR3A_PLL);
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break;
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case ddr3b_pll_clk:
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if (cpu_is_k2hk())
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freq = pll_freq_get(DDR3B_PLL);
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break;
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case uart_pll_clk:
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if (cpu_is_k2g())
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freq = pll_freq_get(UART_PLL);
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break;
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case sys_clk0_1_clk:
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case sys_clk0_clk:
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freq = pll_freq_get(CORE_PLL) / pll0div_read(1);
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break;
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case sys_clk1_clk:
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return pll_freq_get(CORE_PLL) / pll0div_read(2);
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break;
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case sys_clk2_clk:
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freq = pll_freq_get(CORE_PLL) / pll0div_read(3);
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break;
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case sys_clk3_clk:
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freq = pll_freq_get(CORE_PLL) / pll0div_read(4);
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break;
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case sys_clk0_2_clk:
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freq = clk_get_rate(sys_clk0_clk) / 2;
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break;
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case sys_clk0_3_clk:
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freq = clk_get_rate(sys_clk0_clk) / 3;
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break;
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case sys_clk0_4_clk:
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freq = clk_get_rate(sys_clk0_clk) / 4;
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break;
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case sys_clk0_6_clk:
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freq = clk_get_rate(sys_clk0_clk) / 6;
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break;
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case sys_clk0_8_clk:
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freq = clk_get_rate(sys_clk0_clk) / 8;
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break;
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case sys_clk0_12_clk:
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freq = clk_get_rate(sys_clk0_clk) / 12;
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break;
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case sys_clk0_24_clk:
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freq = clk_get_rate(sys_clk0_clk) / 24;
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break;
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case sys_clk1_3_clk:
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freq = clk_get_rate(sys_clk1_clk) / 3;
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break;
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case sys_clk1_4_clk:
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freq = clk_get_rate(sys_clk1_clk) / 4;
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break;
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case sys_clk1_6_clk:
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freq = clk_get_rate(sys_clk1_clk) / 6;
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break;
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case sys_clk1_12_clk:
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freq = clk_get_rate(sys_clk1_clk) / 12;
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break;
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default:
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break;
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}
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return freq;
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}
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