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After acking the requested frequency, should wait the ack bit clear by DDR controller and check the DFS interrupt for next request polling. Otherwise, the next polling of request bit will get previous value that DDR controller have not cleared it, so a wrong request frequency is used. Reviewed-by: Peng Fan <peng.fan@nxp.com> Signed-off-by: Ye Li <ye.li@nxp.com> Signed-off-by: Peng Fan <peng.fan@nxp.com>
266 lines
8.5 KiB
C
266 lines
8.5 KiB
C
// SPDX-License-Identifier: GPL-2.0+ OR MIT
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/*
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* Copyright 2021 NXP
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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.h>
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#include <asm/arch/ddr.h>
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#include <asm/arch/imx-regs.h>
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#define DENALI_CTL_00 (DDR_CTL_BASE_ADDR + 4 * 0)
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#define CTL_START 0x1
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#define DENALI_CTL_03 (DDR_CTL_BASE_ADDR + 4 * 3)
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#define DENALI_CTL_197 (DDR_CTL_BASE_ADDR + 4 * 197)
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#define DENALI_CTL_250 (DDR_CTL_BASE_ADDR + 4 * 250)
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#define DENALI_CTL_251 (DDR_CTL_BASE_ADDR + 4 * 251)
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#define DENALI_CTL_266 (DDR_CTL_BASE_ADDR + 4 * 266)
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#define DFI_INIT_COMPLETE 0x2
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#define DENALI_CTL_614 (DDR_CTL_BASE_ADDR + 4 * 614)
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#define DENALI_CTL_615 (DDR_CTL_BASE_ADDR + 4 * 615)
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#define DENALI_PI_00 (DDR_PI_BASE_ADDR + 4 * 0)
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#define PI_START 0x1
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#define DENALI_PI_04 (DDR_PI_BASE_ADDR + 4 * 4)
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#define DENALI_PI_11 (DDR_PI_BASE_ADDR + 4 * 11)
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#define DENALI_PI_12 (DDR_PI_BASE_ADDR + 4 * 12)
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#define DENALI_CTL_23 (DDR_CTL_BASE_ADDR + 4 * 23)
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#define DENALI_CTL_25 (DDR_CTL_BASE_ADDR + 4 * 25)
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#define DENALI_PHY_1624 (DDR_PHY_BASE_ADDR + 4 * 1624)
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#define DENALI_PHY_1537 (DDR_PHY_BASE_ADDR + 4 * 1537)
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#define PHY_FREQ_SEL_MULTICAST_EN(X) ((X) << 8)
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#define PHY_FREQ_SEL_INDEX(X) ((X) << 16)
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#define DENALI_PHY_1547 (DDR_PHY_BASE_ADDR + 4 * 1547)
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#define DENALI_PHY_1555 (DDR_PHY_BASE_ADDR + 4 * 1555)
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#define DENALI_PHY_1564 (DDR_PHY_BASE_ADDR + 4 * 1564)
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#define DENALI_PHY_1565 (DDR_PHY_BASE_ADDR + 4 * 1565)
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static void ddr_enable_pll_bypass(void)
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{
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u32 reg_val;
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/* PI_INIT_LVL_EN=0x0 (DENALI_PI_04) */
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reg_val = readl(DENALI_PI_04) & ~0x1;
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writel(reg_val, DENALI_PI_04);
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/* PI_FREQ_MAP=0x1 (DENALI_PI_12) */
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writel(0x1, DENALI_PI_12);
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/* PI_INIT_WORK_FREQ=0x0 (DENALI_PI_11) */
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reg_val = readl(DENALI_PI_11) & ~(0x1f << 8);
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writel(reg_val, DENALI_PI_11);
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/* DFIBUS_FREQ_INIT=0x0 (DENALI_CTL_23) */
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reg_val = readl(DENALI_CTL_23) & ~(0x3 << 24);
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writel(reg_val, DENALI_CTL_23);
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/* PHY_LP4_BOOT_DISABLE=0x0 (DENALI_PHY_1547) */
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reg_val = readl(DENALI_PHY_1547) & ~(0x1 << 8);
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writel(reg_val, DENALI_PHY_1547);
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/* PHY_PLL_BYPASS=0x1 (DENALI_PHY_1624) */
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reg_val = readl(DENALI_PHY_1624) | 0x1;
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writel(reg_val, DENALI_PHY_1624);
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/* PHY_LP4_BOOT_PLL_BYPASS to 0x1 (DENALI_PHY_1555) */
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reg_val = readl(DENALI_PHY_1555) | 0x1;
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writel(reg_val, DENALI_PHY_1555);
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/* FREQ_CHANGE_TYPE_F0 = 0x0/FREQ_CHANGE_TYPE_F1 = 0x1/FREQ_CHANGE_TYPE_F2 = 0x2 */
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reg_val = 0x020100;
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writel(reg_val, DENALI_CTL_25);
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}
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int ddr_calibration(unsigned int fsp_table[3])
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{
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u32 reg_val;
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u32 int_status_init, phy_freq_req, phy_freq_type;
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u32 lock_0, lock_1, lock_2;
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u32 freq_chg_pt, freq_chg_cnt;
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if (IS_ENABLED(CONFIG_IMX8ULP_DRAM_PHY_PLL_BYPASS)) {
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ddr_enable_pll_bypass();
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freq_chg_cnt = 0;
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freq_chg_pt = 0;
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} else {
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reg_val = readl(DENALI_CTL_250);
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if (((reg_val >> 16) & 0x3) == 1)
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freq_chg_cnt = 2;
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else
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freq_chg_cnt = 3;
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reg_val = readl(DENALI_PI_12);
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if (reg_val == 0x3) {
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freq_chg_pt = 1;
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} else if (reg_val == 0x7) {
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freq_chg_pt = 2;
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} else {
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printf("frequency map(0x%x) is wrong, please check!\r\n", reg_val);
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return -1;
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}
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}
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/* Assert PI_START parameter and then assert START parameter in Controller. */
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reg_val = readl(DENALI_PI_00) | PI_START;
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writel(reg_val, DENALI_PI_00);
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reg_val = readl(DENALI_CTL_00) | CTL_START;
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writel(reg_val, DENALI_CTL_00);
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/* Poll for init_done_bit in Controller interrupt status register (INT_STATUS_INIT) */
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do {
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if (!freq_chg_cnt) {
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int_status_init = (readl(DENALI_CTL_266) >> 8) & 0xff;
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/* DDR subsystem is ready for traffic. */
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if (int_status_init & DFI_INIT_COMPLETE) {
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debug("complete\n");
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break;
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}
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}
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/*
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* During leveling, PHY will request for freq change and SoC clock logic
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* should provide requested frequency
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* Polling SIM LPDDR_CTRL2 Bit phy_freq_chg_req until be 1'b1
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*/
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reg_val = readl(AVD_SIM_LPDDR_CTRL2);
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/* DFS interrupt is set */
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phy_freq_req = ((reg_val >> 7) & 0x1) && ((reg_val >> 15) & 0x1);
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if (phy_freq_req) {
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phy_freq_type = reg_val & 0x1F;
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if (phy_freq_type == 0x00) {
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debug("Poll for freq_chg_req on SIM register and change to F0 frequency.\n");
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set_ddr_clk(fsp_table[phy_freq_type] >> 1);
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/* Write 1'b1 at LPDDR_CTRL2 bit phy_freq_cfg_ack */
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reg_val = readl(AVD_SIM_LPDDR_CTRL2);
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writel(reg_val | (0x1 << 6), AVD_SIM_LPDDR_CTRL2);
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} else if (phy_freq_type == 0x01) {
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debug("Poll for freq_chg_req on SIM register and change to F1 frequency.\n");
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set_ddr_clk(fsp_table[phy_freq_type] >> 1);
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/* Write 1'b1 at LPDDR_CTRL2 bit phy_freq_cfg_ack */
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reg_val = readl(AVD_SIM_LPDDR_CTRL2);
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writel(reg_val | (0x1 << 6), AVD_SIM_LPDDR_CTRL2);
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if (freq_chg_pt == 1)
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freq_chg_cnt--;
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} else if (phy_freq_type == 0x02) {
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debug("Poll for freq_chg_req on SIM register and change to F2 frequency.\n");
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set_ddr_clk(fsp_table[phy_freq_type] >> 1);
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/* Write 1'b1 at LPDDR_CTRL2 bit phy_freq_cfg_ack */
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reg_val = readl(AVD_SIM_LPDDR_CTRL2);
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writel(reg_val | (0x1 << 6), AVD_SIM_LPDDR_CTRL2);
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if (freq_chg_pt == 2)
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freq_chg_cnt--;
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}
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/* Hardware clear the ack on falling edge of LPDDR_CTRL2:phy_freq_chg_reg */
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/* Ensure the ack is clear before starting to poll request again */
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while ((readl(AVD_SIM_LPDDR_CTRL2) & BIT(6)))
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;
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}
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} while (1);
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/* Check PLL lock status */
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lock_0 = readl(DENALI_PHY_1564) & 0xffff;
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lock_1 = (readl(DENALI_PHY_1564) >> 16) & 0xffff;
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lock_2 = readl(DENALI_PHY_1565) & 0xffff;
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if ((lock_0 & 0x3) != 0x3 || (lock_1 & 0x3) != 0x3 || (lock_2 & 0x3) != 0x3) {
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debug("De-Skew PLL failed to lock\n");
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debug("lock_0=0x%x, lock_1=0x%x, lock_2=0x%x\n", lock_0, lock_1, lock_2);
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return -1;
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}
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debug("De-Skew PLL is locked and ready\n");
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return 0;
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}
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static void save_dram_config(struct dram_timing_info2 *timing_info, unsigned long saved_timing_base)
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{
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int i = 0;
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struct dram_timing_info2 *saved_timing = (struct dram_timing_info2 *)saved_timing_base;
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struct dram_cfg_param *cfg;
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saved_timing->ctl_cfg_num = timing_info->ctl_cfg_num;
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saved_timing->phy_f1_cfg_num = timing_info->phy_f1_cfg_num;
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saved_timing->phy_f2_cfg_num = timing_info->phy_f2_cfg_num;
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/* save the fsp table */
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for (i = 0; i < 3; i++)
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saved_timing->fsp_table[i] = timing_info->fsp_table[i];
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cfg = (struct dram_cfg_param *)(saved_timing_base +
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sizeof(*timing_info));
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/* save ctl config */
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saved_timing->ctl_cfg = cfg;
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for (i = 0; i < timing_info->ctl_cfg_num; i++) {
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cfg->reg = timing_info->ctl_cfg[i].reg;
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cfg->val = timing_info->ctl_cfg[i].val;
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cfg++;
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}
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/* save phy f1 config */
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saved_timing->phy_f1_cfg = cfg;
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for (i = 0; i < timing_info->phy_f1_cfg_num; i++) {
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cfg->reg = timing_info->phy_f1_cfg[i].reg;
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cfg->val = timing_info->phy_f1_cfg[i].val;
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cfg++;
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}
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/* save phy f2 config */
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saved_timing->phy_f2_cfg = cfg;
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for (i = 0; i < timing_info->phy_f2_cfg_num; i++) {
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cfg->reg = timing_info->phy_f2_cfg[i].reg;
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cfg->val = timing_info->phy_f2_cfg[i].val;
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cfg++;
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}
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}
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int ddr_init(struct dram_timing_info2 *dram_timing)
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{
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int i;
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if (IS_ENABLED(CONFIG_IMX8ULP_DRAM_PHY_PLL_BYPASS)) {
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/* Use PLL bypass for boot freq */
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/* Since PLL can't generate the double freq, Need ddr clock to generate it. */
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set_ddr_clk(dram_timing->fsp_table[0]); /* Set to boot freq */
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setbits_le32(AVD_SIM_BASE_ADDR, 0x1); /* SIM_DDR_CTRL_DIV2_EN */
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} else {
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set_ddr_clk(dram_timing->fsp_table[0] >> 1); /* Set to boot freq */
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clrbits_le32(AVD_SIM_BASE_ADDR, 0x1); /* SIM_DDR_CTRL_DIV2_EN */
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}
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/* save the dram config into sram for low power mode */
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save_dram_config(dram_timing, CONFIG_SAVED_DRAM_TIMING_BASE);
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/* Initialize CTL registers */
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for (i = 0; i < dram_timing->ctl_cfg_num; i++)
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writel(dram_timing->ctl_cfg[i].val, (ulong)dram_timing->ctl_cfg[i].reg);
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/* Initialize PI registers */
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for (i = 0; i < dram_timing->pi_cfg_num; i++)
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writel(dram_timing->pi_cfg[i].val, (ulong)dram_timing->pi_cfg[i].reg);
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/* Write PHY regiters for all 3 frequency points (48Mhz/384Mhz/528Mhz): f1_index=0 */
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writel(PHY_FREQ_SEL_MULTICAST_EN(1) | PHY_FREQ_SEL_INDEX(0), DENALI_PHY_1537);
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for (i = 0; i < dram_timing->phy_f1_cfg_num; i++)
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writel(dram_timing->phy_f1_cfg[i].val, (ulong)dram_timing->phy_f1_cfg[i].reg);
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/* Write PHY regiters for freqency point 2 (528Mhz): f2_index=1 */
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writel(PHY_FREQ_SEL_MULTICAST_EN(0) | PHY_FREQ_SEL_INDEX(1), DENALI_PHY_1537);
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for (i = 0; i < dram_timing->phy_f2_cfg_num; i++)
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writel(dram_timing->phy_f2_cfg[i].val, (ulong)dram_timing->phy_f2_cfg[i].reg);
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/* Re-enable MULTICAST mode */
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writel(PHY_FREQ_SEL_MULTICAST_EN(1) | PHY_FREQ_SEL_INDEX(0), DENALI_PHY_1537);
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return ddr_calibration(dram_timing->fsp_table);
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}
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