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aa6e94deab
The rest of the unmigrated CONFIG symbols in the CONFIG_SYS_SDRAM namespace do not easily transition to Kconfig. In many cases they likely should come from the device tree instead. Move these out of CONFIG namespace and in to CFG namespace. Signed-off-by: Tom Rini <trini@konsulko.com> Reviewed-by: Simon Glass <sjg@chromium.org>
865 lines
27 KiB
C
865 lines
27 KiB
C
// SPDX-License-Identifier: GPL-2.0+
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/*
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* DDR3 mem setup file for board based on EXYNOS5
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*
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* Copyright (C) 2012 Samsung Electronics
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*/
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#include <common.h>
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#include <config.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/cpu.h>
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#include <asm/arch/dmc.h>
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#include <asm/arch/power.h>
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#include "common_setup.h"
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#include "exynos5_setup.h"
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#include "clock_init.h"
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#define TIMEOUT_US 10000
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#define NUM_BYTE_LANES 4
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#define DEFAULT_DQS 8
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#define DEFAULT_DQS_X4 ((DEFAULT_DQS << 24) || (DEFAULT_DQS << 16) \
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|| (DEFAULT_DQS << 8) || (DEFAULT_DQS << 0))
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#ifdef CONFIG_EXYNOS5250
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static void reset_phy_ctrl(void)
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{
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struct exynos5_clock *clk =
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(struct exynos5_clock *)samsung_get_base_clock();
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writel(DDR3PHY_CTRL_PHY_RESET_OFF, &clk->lpddr3phy_ctrl);
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writel(DDR3PHY_CTRL_PHY_RESET, &clk->lpddr3phy_ctrl);
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}
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int ddr3_mem_ctrl_init(struct mem_timings *mem, int reset)
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{
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unsigned int val;
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struct exynos5_phy_control *phy0_ctrl, *phy1_ctrl;
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struct exynos5_dmc *dmc;
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int i;
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phy0_ctrl = (struct exynos5_phy_control *)samsung_get_base_dmc_phy();
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phy1_ctrl = (struct exynos5_phy_control *)(samsung_get_base_dmc_phy()
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+ DMC_OFFSET);
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dmc = (struct exynos5_dmc *)samsung_get_base_dmc_ctrl();
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if (reset)
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reset_phy_ctrl();
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/* Set Impedance Output Driver */
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val = (mem->impedance << CA_CK_DRVR_DS_OFFSET) |
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(mem->impedance << CA_CKE_DRVR_DS_OFFSET) |
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(mem->impedance << CA_CS_DRVR_DS_OFFSET) |
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(mem->impedance << CA_ADR_DRVR_DS_OFFSET);
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writel(val, &phy0_ctrl->phy_con39);
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writel(val, &phy1_ctrl->phy_con39);
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/* Set Read Latency and Burst Length for PHY0 and PHY1 */
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val = (mem->ctrl_bstlen << PHY_CON42_CTRL_BSTLEN_SHIFT) |
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(mem->ctrl_rdlat << PHY_CON42_CTRL_RDLAT_SHIFT);
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writel(val, &phy0_ctrl->phy_con42);
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writel(val, &phy1_ctrl->phy_con42);
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/* ZQ Calibration */
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if (dmc_config_zq(mem, &phy0_ctrl->phy_con16, &phy1_ctrl->phy_con16,
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&phy0_ctrl->phy_con17, &phy1_ctrl->phy_con17))
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return SETUP_ERR_ZQ_CALIBRATION_FAILURE;
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/* DQ Signal */
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writel(mem->phy0_pulld_dqs, &phy0_ctrl->phy_con14);
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writel(mem->phy1_pulld_dqs, &phy1_ctrl->phy_con14);
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writel(mem->concontrol | (mem->rd_fetch << CONCONTROL_RD_FETCH_SHIFT)
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| (mem->dfi_init_start << CONCONTROL_DFI_INIT_START_SHIFT),
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&dmc->concontrol);
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update_reset_dll(&dmc->phycontrol0, DDR_MODE_DDR3);
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/* DQS Signal */
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writel(mem->phy0_dqs, &phy0_ctrl->phy_con4);
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writel(mem->phy1_dqs, &phy1_ctrl->phy_con4);
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writel(mem->phy0_dq, &phy0_ctrl->phy_con6);
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writel(mem->phy1_dq, &phy1_ctrl->phy_con6);
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writel(mem->phy0_tFS, &phy0_ctrl->phy_con10);
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writel(mem->phy1_tFS, &phy1_ctrl->phy_con10);
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val = (mem->ctrl_start_point << PHY_CON12_CTRL_START_POINT_SHIFT) |
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(mem->ctrl_inc << PHY_CON12_CTRL_INC_SHIFT) |
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(mem->ctrl_dll_on << PHY_CON12_CTRL_DLL_ON_SHIFT) |
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(mem->ctrl_ref << PHY_CON12_CTRL_REF_SHIFT);
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writel(val, &phy0_ctrl->phy_con12);
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writel(val, &phy1_ctrl->phy_con12);
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/* Start DLL locking */
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writel(val | (mem->ctrl_start << PHY_CON12_CTRL_START_SHIFT),
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&phy0_ctrl->phy_con12);
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writel(val | (mem->ctrl_start << PHY_CON12_CTRL_START_SHIFT),
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&phy1_ctrl->phy_con12);
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update_reset_dll(&dmc->phycontrol0, DDR_MODE_DDR3);
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writel(mem->concontrol | (mem->rd_fetch << CONCONTROL_RD_FETCH_SHIFT),
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&dmc->concontrol);
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/* Memory Channel Inteleaving Size */
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writel(mem->iv_size, &dmc->ivcontrol);
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writel(mem->memconfig, &dmc->memconfig0);
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writel(mem->memconfig, &dmc->memconfig1);
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writel(mem->membaseconfig0, &dmc->membaseconfig0);
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writel(mem->membaseconfig1, &dmc->membaseconfig1);
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/* Precharge Configuration */
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writel(mem->prechconfig_tp_cnt << PRECHCONFIG_TP_CNT_SHIFT,
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&dmc->prechconfig);
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/* Power Down mode Configuration */
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writel(mem->dpwrdn_cyc << PWRDNCONFIG_DPWRDN_CYC_SHIFT |
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mem->dsref_cyc << PWRDNCONFIG_DSREF_CYC_SHIFT,
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&dmc->pwrdnconfig);
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/* TimingRow, TimingData, TimingPower and Timingaref
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* values as per Memory AC parameters
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*/
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writel(mem->timing_ref, &dmc->timingref);
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writel(mem->timing_row, &dmc->timingrow);
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writel(mem->timing_data, &dmc->timingdata);
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writel(mem->timing_power, &dmc->timingpower);
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/* Send PALL command */
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dmc_config_prech(mem, &dmc->directcmd);
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/* Send NOP, MRS and ZQINIT commands */
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dmc_config_mrs(mem, &dmc->directcmd);
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if (mem->gate_leveling_enable) {
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val = PHY_CON0_RESET_VAL;
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val |= P0_CMD_EN;
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writel(val, &phy0_ctrl->phy_con0);
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writel(val, &phy1_ctrl->phy_con0);
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val = PHY_CON2_RESET_VAL;
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val |= INIT_DESKEW_EN;
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writel(val, &phy0_ctrl->phy_con2);
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writel(val, &phy1_ctrl->phy_con2);
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val = PHY_CON0_RESET_VAL;
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val |= P0_CMD_EN;
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val |= BYTE_RDLVL_EN;
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writel(val, &phy0_ctrl->phy_con0);
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writel(val, &phy1_ctrl->phy_con0);
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val = (mem->ctrl_start_point <<
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PHY_CON12_CTRL_START_POINT_SHIFT) |
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(mem->ctrl_inc << PHY_CON12_CTRL_INC_SHIFT) |
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(mem->ctrl_force << PHY_CON12_CTRL_FORCE_SHIFT) |
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(mem->ctrl_start << PHY_CON12_CTRL_START_SHIFT) |
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(mem->ctrl_ref << PHY_CON12_CTRL_REF_SHIFT);
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writel(val, &phy0_ctrl->phy_con12);
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writel(val, &phy1_ctrl->phy_con12);
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val = PHY_CON2_RESET_VAL;
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val |= INIT_DESKEW_EN;
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val |= RDLVL_GATE_EN;
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writel(val, &phy0_ctrl->phy_con2);
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writel(val, &phy1_ctrl->phy_con2);
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val = PHY_CON0_RESET_VAL;
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val |= P0_CMD_EN;
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val |= BYTE_RDLVL_EN;
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val |= CTRL_SHGATE;
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writel(val, &phy0_ctrl->phy_con0);
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writel(val, &phy1_ctrl->phy_con0);
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val = PHY_CON1_RESET_VAL;
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val &= ~(CTRL_GATEDURADJ_MASK);
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writel(val, &phy0_ctrl->phy_con1);
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writel(val, &phy1_ctrl->phy_con1);
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writel(CTRL_RDLVL_GATE_ENABLE, &dmc->rdlvl_config);
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i = TIMEOUT_US;
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while ((readl(&dmc->phystatus) &
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(RDLVL_COMPLETE_CHO | RDLVL_COMPLETE_CH1)) !=
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(RDLVL_COMPLETE_CHO | RDLVL_COMPLETE_CH1) && i > 0) {
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/*
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* TODO(waihong): Comment on how long this take to
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* timeout
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*/
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sdelay(100);
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i--;
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}
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if (!i)
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return SETUP_ERR_RDLV_COMPLETE_TIMEOUT;
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writel(CTRL_RDLVL_GATE_DISABLE, &dmc->rdlvl_config);
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writel(0, &phy0_ctrl->phy_con14);
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writel(0, &phy1_ctrl->phy_con14);
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val = (mem->ctrl_start_point <<
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PHY_CON12_CTRL_START_POINT_SHIFT) |
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(mem->ctrl_inc << PHY_CON12_CTRL_INC_SHIFT) |
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(mem->ctrl_force << PHY_CON12_CTRL_FORCE_SHIFT) |
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(mem->ctrl_start << PHY_CON12_CTRL_START_SHIFT) |
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(mem->ctrl_dll_on << PHY_CON12_CTRL_DLL_ON_SHIFT) |
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(mem->ctrl_ref << PHY_CON12_CTRL_REF_SHIFT);
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writel(val, &phy0_ctrl->phy_con12);
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writel(val, &phy1_ctrl->phy_con12);
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update_reset_dll(&dmc->phycontrol0, DDR_MODE_DDR3);
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}
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/* Send PALL command */
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dmc_config_prech(mem, &dmc->directcmd);
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writel(mem->memcontrol, &dmc->memcontrol);
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/* Set DMC Concontrol and enable auto-refresh counter */
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writel(mem->concontrol | (mem->rd_fetch << CONCONTROL_RD_FETCH_SHIFT)
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| (mem->aref_en << CONCONTROL_AREF_EN_SHIFT), &dmc->concontrol);
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return 0;
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}
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#endif
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#ifdef CONFIG_EXYNOS5420
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/**
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* RAM address to use in the test.
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*
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* We'll use 4 words at this address and 4 at this address + 0x80 (Ares
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* interleaves channels every 128 bytes). This will allow us to evaluate all of
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* the chips in a 1 chip per channel (2GB) system and half the chips in a 2
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* chip per channel (4GB) system. We can't test the 2nd chip since we need to
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* do tests before the 2nd chip is enabled. Looking at the 2nd chip isn't
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* critical because the 1st and 2nd chip have very similar timings (they'd
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* better have similar timings, since there's only a single adjustment that is
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* shared by both chips).
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*/
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const unsigned int test_addr = CFG_SYS_SDRAM_BASE;
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/* Test pattern with which RAM will be tested */
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static const unsigned int test_pattern[] = {
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0x5a5a5a5a,
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0xa5a5a5a5,
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0xf0f0f0f0,
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0x0f0f0f0f,
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};
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/**
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* This function is a test vector for sw read leveling,
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* it compares the read data with the written data.
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*
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* @param ch DMC channel number
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* @param byte_lane which DQS byte offset,
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* possible values are 0,1,2,3
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* Return: TRUE if memory was good, FALSE if not.
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*/
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static bool dmc_valid_window_test_vector(int ch, int byte_lane)
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{
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unsigned int read_data;
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unsigned int mask;
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int i;
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mask = 0xFF << (8 * byte_lane);
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for (i = 0; i < ARRAY_SIZE(test_pattern); i++) {
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read_data = readl(test_addr + i * 4 + ch * 0x80);
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if ((read_data & mask) != (test_pattern[i] & mask))
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return false;
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}
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return true;
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}
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/**
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* This function returns current read offset value.
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*
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* @param phy_ctrl pointer to the current phy controller
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*/
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static unsigned int dmc_get_read_offset_value(struct exynos5420_phy_control
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*phy_ctrl)
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{
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return readl(&phy_ctrl->phy_con4);
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}
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/**
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* This function performs resync, so that slave DLL is updated.
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*
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* @param phy_ctrl pointer to the current phy controller
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*/
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static void ddr_phy_set_do_resync(struct exynos5420_phy_control *phy_ctrl)
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{
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setbits_le32(&phy_ctrl->phy_con10, PHY_CON10_CTRL_OFFSETR3);
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clrbits_le32(&phy_ctrl->phy_con10, PHY_CON10_CTRL_OFFSETR3);
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}
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/**
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* This function sets read offset value register with 'offset'.
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*
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* ...we also call call ddr_phy_set_do_resync().
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*
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* @param phy_ctrl pointer to the current phy controller
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* @param offset offset to read DQS
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*/
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static void dmc_set_read_offset_value(struct exynos5420_phy_control *phy_ctrl,
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unsigned int offset)
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{
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writel(offset, &phy_ctrl->phy_con4);
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ddr_phy_set_do_resync(phy_ctrl);
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}
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/**
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* Convert a 2s complement byte to a byte with a sign bit.
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*
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* NOTE: you shouldn't use normal math on the number returned by this function.
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* As an example, -10 = 0xf6. After this function -10 = 0x8a. If you wanted
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* to do math and get the average of 10 and -10 (should be 0):
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* 0x8a + 0xa = 0x94 (-108)
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* 0x94 / 2 = 0xca (-54)
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* ...and 0xca = sign bit plus 0x4a, or -74
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*
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* Also note that you lose the ability to represent -128 since there are two
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* representations of 0.
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*
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* @param b The byte to convert in two's complement.
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* Return: The 7-bit value + sign bit.
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*/
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unsigned char make_signed_byte(signed char b)
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{
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if (b < 0)
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return 0x80 | -b;
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else
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return b;
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}
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/**
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* Test various shifts starting at 'start' and going to 'end'.
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*
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* For each byte lane, we'll walk through shift starting at 'start' and going
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* to 'end' (inclusive). When we are finally able to read the test pattern
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* we'll store the value in the results array.
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*
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* @param phy_ctrl pointer to the current phy controller
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* @param ch channel number
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* @param start the start shift. -127 to 127
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* @param end the end shift. -127 to 127
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* @param results we'll store results for each byte lane.
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*/
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void test_shifts(struct exynos5420_phy_control *phy_ctrl, int ch,
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int start, int end, int results[NUM_BYTE_LANES])
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{
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int incr = (start < end) ? 1 : -1;
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int byte_lane;
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for (byte_lane = 0; byte_lane < NUM_BYTE_LANES; byte_lane++) {
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int shift;
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dmc_set_read_offset_value(phy_ctrl, DEFAULT_DQS_X4);
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results[byte_lane] = DEFAULT_DQS;
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for (shift = start; shift != (end + incr); shift += incr) {
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unsigned int byte_offsetr;
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unsigned int offsetr;
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byte_offsetr = make_signed_byte(shift);
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offsetr = dmc_get_read_offset_value(phy_ctrl);
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offsetr &= ~(0xFF << (8 * byte_lane));
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offsetr |= (byte_offsetr << (8 * byte_lane));
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dmc_set_read_offset_value(phy_ctrl, offsetr);
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if (dmc_valid_window_test_vector(ch, byte_lane)) {
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results[byte_lane] = shift;
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break;
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}
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}
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}
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}
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/**
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* This function performs SW read leveling to compensate DQ-DQS skew at
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* receiver it first finds the optimal read offset value on each DQS
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* then applies the value to PHY.
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*
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* Read offset value has its min margin and max margin. If read offset
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* value exceeds its min or max margin, read data will have corruption.
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* To avoid this we are doing sw read leveling.
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*
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* SW read leveling is:
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* 1> Finding offset value's left_limit and right_limit
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* 2> and calculate its center value
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* 3> finally programs that center value to PHY
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* 4> then PHY gets its optimal offset value.
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*
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* @param phy_ctrl pointer to the current phy controller
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* @param ch channel number
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* @param coarse_lock_val The coarse lock value read from PHY_CON13.
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* (0 - 0x7f)
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*/
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static void software_find_read_offset(struct exynos5420_phy_control *phy_ctrl,
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int ch, unsigned int coarse_lock_val)
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{
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unsigned int offsetr_cent;
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int byte_lane;
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int left_limit;
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int right_limit;
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int left[NUM_BYTE_LANES];
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int right[NUM_BYTE_LANES];
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int i;
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/* Fill the memory with test patterns */
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for (i = 0; i < ARRAY_SIZE(test_pattern); i++)
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writel(test_pattern[i], test_addr + i * 4 + ch * 0x80);
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/* Figure out the limits we'll test with; keep -127 < limit < 127 */
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left_limit = DEFAULT_DQS - coarse_lock_val;
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right_limit = DEFAULT_DQS + coarse_lock_val;
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if (right_limit > 127)
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right_limit = 127;
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/* Fill in the location where reads were OK from left and right */
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test_shifts(phy_ctrl, ch, left_limit, right_limit, left);
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test_shifts(phy_ctrl, ch, right_limit, left_limit, right);
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/* Make a final value by taking the center between the left and right */
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offsetr_cent = 0;
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for (byte_lane = 0; byte_lane < NUM_BYTE_LANES; byte_lane++) {
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int temp_center;
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unsigned int vmwc;
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temp_center = (left[byte_lane] + right[byte_lane]) / 2;
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vmwc = make_signed_byte(temp_center);
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offsetr_cent |= vmwc << (8 * byte_lane);
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}
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dmc_set_read_offset_value(phy_ctrl, offsetr_cent);
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}
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int ddr3_mem_ctrl_init(struct mem_timings *mem, int reset)
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{
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struct exynos5420_clock *clk =
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(struct exynos5420_clock *)samsung_get_base_clock();
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struct exynos5420_power *power =
|
|
(struct exynos5420_power *)samsung_get_base_power();
|
|
struct exynos5420_phy_control *phy0_ctrl, *phy1_ctrl;
|
|
struct exynos5420_dmc *drex0, *drex1;
|
|
struct exynos5420_tzasc *tzasc0, *tzasc1;
|
|
struct exynos5_power *pmu;
|
|
uint32_t val, n_lock_r, n_lock_w_phy0, n_lock_w_phy1;
|
|
uint32_t lock0_info, lock1_info;
|
|
int chip;
|
|
int i;
|
|
|
|
phy0_ctrl = (struct exynos5420_phy_control *)samsung_get_base_dmc_phy();
|
|
phy1_ctrl = (struct exynos5420_phy_control *)(samsung_get_base_dmc_phy()
|
|
+ DMC_OFFSET);
|
|
drex0 = (struct exynos5420_dmc *)samsung_get_base_dmc_ctrl();
|
|
drex1 = (struct exynos5420_dmc *)(samsung_get_base_dmc_ctrl()
|
|
+ DMC_OFFSET);
|
|
tzasc0 = (struct exynos5420_tzasc *)samsung_get_base_dmc_tzasc();
|
|
tzasc1 = (struct exynos5420_tzasc *)(samsung_get_base_dmc_tzasc()
|
|
+ DMC_OFFSET);
|
|
pmu = (struct exynos5_power *)EXYNOS5420_POWER_BASE;
|
|
|
|
if (CONFIG_NR_DRAM_BANKS > 4) {
|
|
/* Need both controllers. */
|
|
mem->memcontrol |= DMC_MEMCONTROL_NUM_CHIP_2;
|
|
mem->chips_per_channel = 2;
|
|
mem->chips_to_configure = 2;
|
|
} else {
|
|
/* 2GB requires a single controller */
|
|
mem->memcontrol |= DMC_MEMCONTROL_NUM_CHIP_1;
|
|
}
|
|
|
|
/* Enable PAUSE for DREX */
|
|
setbits_le32(&clk->pause, ENABLE_BIT);
|
|
|
|
/* Enable BYPASS mode */
|
|
setbits_le32(&clk->bpll_con1, BYPASS_EN);
|
|
|
|
writel(MUX_BPLL_SEL_FOUTBPLL, &clk->src_cdrex);
|
|
do {
|
|
val = readl(&clk->mux_stat_cdrex);
|
|
val &= BPLL_SEL_MASK;
|
|
} while (val != FOUTBPLL);
|
|
|
|
clrbits_le32(&clk->bpll_con1, BYPASS_EN);
|
|
|
|
/* Specify the DDR memory type as DDR3 */
|
|
val = readl(&phy0_ctrl->phy_con0);
|
|
val &= ~(PHY_CON0_CTRL_DDR_MODE_MASK << PHY_CON0_CTRL_DDR_MODE_SHIFT);
|
|
val |= (DDR_MODE_DDR3 << PHY_CON0_CTRL_DDR_MODE_SHIFT);
|
|
writel(val, &phy0_ctrl->phy_con0);
|
|
|
|
val = readl(&phy1_ctrl->phy_con0);
|
|
val &= ~(PHY_CON0_CTRL_DDR_MODE_MASK << PHY_CON0_CTRL_DDR_MODE_SHIFT);
|
|
val |= (DDR_MODE_DDR3 << PHY_CON0_CTRL_DDR_MODE_SHIFT);
|
|
writel(val, &phy1_ctrl->phy_con0);
|
|
|
|
/* Set Read Latency and Burst Length for PHY0 and PHY1 */
|
|
val = (mem->ctrl_bstlen << PHY_CON42_CTRL_BSTLEN_SHIFT) |
|
|
(mem->ctrl_rdlat << PHY_CON42_CTRL_RDLAT_SHIFT);
|
|
writel(val, &phy0_ctrl->phy_con42);
|
|
writel(val, &phy1_ctrl->phy_con42);
|
|
|
|
val = readl(&phy0_ctrl->phy_con26);
|
|
val &= ~(T_WRDATA_EN_MASK << T_WRDATA_EN_OFFSET);
|
|
val |= (T_WRDATA_EN_DDR3 << T_WRDATA_EN_OFFSET);
|
|
writel(val, &phy0_ctrl->phy_con26);
|
|
|
|
val = readl(&phy1_ctrl->phy_con26);
|
|
val &= ~(T_WRDATA_EN_MASK << T_WRDATA_EN_OFFSET);
|
|
val |= (T_WRDATA_EN_DDR3 << T_WRDATA_EN_OFFSET);
|
|
writel(val, &phy1_ctrl->phy_con26);
|
|
|
|
/*
|
|
* Set Driver strength for CK, CKE, CS & CA to 0x7
|
|
* Set Driver strength for Data Slice 0~3 to 0x7
|
|
*/
|
|
val = (0x7 << CA_CK_DRVR_DS_OFFSET) | (0x7 << CA_CKE_DRVR_DS_OFFSET) |
|
|
(0x7 << CA_CS_DRVR_DS_OFFSET) | (0x7 << CA_ADR_DRVR_DS_OFFSET);
|
|
val |= (0x7 << DA_3_DS_OFFSET) | (0x7 << DA_2_DS_OFFSET) |
|
|
(0x7 << DA_1_DS_OFFSET) | (0x7 << DA_0_DS_OFFSET);
|
|
writel(val, &phy0_ctrl->phy_con39);
|
|
writel(val, &phy1_ctrl->phy_con39);
|
|
|
|
/* ZQ Calibration */
|
|
if (dmc_config_zq(mem, &phy0_ctrl->phy_con16, &phy1_ctrl->phy_con16,
|
|
&phy0_ctrl->phy_con17, &phy1_ctrl->phy_con17))
|
|
return SETUP_ERR_ZQ_CALIBRATION_FAILURE;
|
|
|
|
clrbits_le32(&phy0_ctrl->phy_con16, ZQ_CLK_DIV_EN);
|
|
clrbits_le32(&phy1_ctrl->phy_con16, ZQ_CLK_DIV_EN);
|
|
|
|
/* DQ Signal */
|
|
val = readl(&phy0_ctrl->phy_con14);
|
|
val |= mem->phy0_pulld_dqs;
|
|
writel(val, &phy0_ctrl->phy_con14);
|
|
val = readl(&phy1_ctrl->phy_con14);
|
|
val |= mem->phy1_pulld_dqs;
|
|
writel(val, &phy1_ctrl->phy_con14);
|
|
|
|
val = MEM_TERM_EN | PHY_TERM_EN;
|
|
writel(val, &drex0->phycontrol0);
|
|
writel(val, &drex1->phycontrol0);
|
|
|
|
writel(mem->concontrol |
|
|
(mem->dfi_init_start << CONCONTROL_DFI_INIT_START_SHIFT) |
|
|
(mem->rd_fetch << CONCONTROL_RD_FETCH_SHIFT),
|
|
&drex0->concontrol);
|
|
writel(mem->concontrol |
|
|
(mem->dfi_init_start << CONCONTROL_DFI_INIT_START_SHIFT) |
|
|
(mem->rd_fetch << CONCONTROL_RD_FETCH_SHIFT),
|
|
&drex1->concontrol);
|
|
|
|
do {
|
|
val = readl(&drex0->phystatus);
|
|
} while ((val & DFI_INIT_COMPLETE) != DFI_INIT_COMPLETE);
|
|
do {
|
|
val = readl(&drex1->phystatus);
|
|
} while ((val & DFI_INIT_COMPLETE) != DFI_INIT_COMPLETE);
|
|
|
|
clrbits_le32(&drex0->concontrol, DFI_INIT_START);
|
|
clrbits_le32(&drex1->concontrol, DFI_INIT_START);
|
|
|
|
update_reset_dll(&drex0->phycontrol0, DDR_MODE_DDR3);
|
|
update_reset_dll(&drex1->phycontrol0, DDR_MODE_DDR3);
|
|
|
|
/*
|
|
* Set Base Address:
|
|
* 0x2000_0000 ~ 0x5FFF_FFFF
|
|
* 0x6000_0000 ~ 0x9FFF_FFFF
|
|
*/
|
|
/* MEMBASECONFIG0 */
|
|
val = DMC_MEMBASECONFIGX_CHIP_BASE(DMC_CHIP_BASE_0) |
|
|
DMC_MEMBASECONFIGX_CHIP_MASK(DMC_CHIP_MASK);
|
|
writel(val, &tzasc0->membaseconfig0);
|
|
writel(val, &tzasc1->membaseconfig0);
|
|
|
|
/* MEMBASECONFIG1 */
|
|
val = DMC_MEMBASECONFIGX_CHIP_BASE(DMC_CHIP_BASE_1) |
|
|
DMC_MEMBASECONFIGX_CHIP_MASK(DMC_CHIP_MASK);
|
|
writel(val, &tzasc0->membaseconfig1);
|
|
writel(val, &tzasc1->membaseconfig1);
|
|
|
|
/*
|
|
* Memory Channel Inteleaving Size
|
|
* Ares Channel interleaving = 128 bytes
|
|
*/
|
|
/* MEMCONFIG0/1 */
|
|
writel(mem->memconfig, &tzasc0->memconfig0);
|
|
writel(mem->memconfig, &tzasc1->memconfig0);
|
|
writel(mem->memconfig, &tzasc0->memconfig1);
|
|
writel(mem->memconfig, &tzasc1->memconfig1);
|
|
|
|
/* Precharge Configuration */
|
|
writel(mem->prechconfig_tp_cnt << PRECHCONFIG_TP_CNT_SHIFT,
|
|
&drex0->prechconfig0);
|
|
writel(mem->prechconfig_tp_cnt << PRECHCONFIG_TP_CNT_SHIFT,
|
|
&drex1->prechconfig0);
|
|
|
|
/*
|
|
* TimingRow, TimingData, TimingPower and Timingaref
|
|
* values as per Memory AC parameters
|
|
*/
|
|
writel(mem->timing_ref, &drex0->timingref);
|
|
writel(mem->timing_ref, &drex1->timingref);
|
|
writel(mem->timing_row, &drex0->timingrow0);
|
|
writel(mem->timing_row, &drex1->timingrow0);
|
|
writel(mem->timing_data, &drex0->timingdata0);
|
|
writel(mem->timing_data, &drex1->timingdata0);
|
|
writel(mem->timing_power, &drex0->timingpower0);
|
|
writel(mem->timing_power, &drex1->timingpower0);
|
|
|
|
if (reset) {
|
|
/*
|
|
* Send NOP, MRS and ZQINIT commands
|
|
* Sending MRS command will reset the DRAM. We should not be
|
|
* resetting the DRAM after resume, this will lead to memory
|
|
* corruption as DRAM content is lost after DRAM reset
|
|
*/
|
|
dmc_config_mrs(mem, &drex0->directcmd);
|
|
dmc_config_mrs(mem, &drex1->directcmd);
|
|
}
|
|
|
|
/*
|
|
* Get PHY_CON13 from both phys. Gate CLKM around reading since
|
|
* PHY_CON13 is glitchy when CLKM is running. We're paranoid and
|
|
* wait until we get a "fine lock", though a coarse lock is probably
|
|
* OK (we only use the coarse numbers below). We try to gate the
|
|
* clock for as short a time as possible in case SDRAM is somehow
|
|
* sensitive. sdelay(10) in the loop is arbitrary to make sure
|
|
* there is some time for PHY_CON13 to get updated. In practice
|
|
* no delay appears to be needed.
|
|
*/
|
|
val = readl(&clk->gate_bus_cdrex);
|
|
while (true) {
|
|
writel(val & ~0x1, &clk->gate_bus_cdrex);
|
|
lock0_info = readl(&phy0_ctrl->phy_con13);
|
|
writel(val, &clk->gate_bus_cdrex);
|
|
|
|
if ((lock0_info & CTRL_FINE_LOCKED) == CTRL_FINE_LOCKED)
|
|
break;
|
|
|
|
sdelay(10);
|
|
}
|
|
while (true) {
|
|
writel(val & ~0x2, &clk->gate_bus_cdrex);
|
|
lock1_info = readl(&phy1_ctrl->phy_con13);
|
|
writel(val, &clk->gate_bus_cdrex);
|
|
|
|
if ((lock1_info & CTRL_FINE_LOCKED) == CTRL_FINE_LOCKED)
|
|
break;
|
|
|
|
sdelay(10);
|
|
}
|
|
|
|
if (!reset) {
|
|
/*
|
|
* During Suspend-Resume & S/W-Reset, as soon as PMU releases
|
|
* pad retention, CKE goes high. This causes memory contents
|
|
* not to be retained during DRAM initialization. Therfore,
|
|
* there is a new control register(0x100431e8[28]) which lets us
|
|
* release pad retention and retain the memory content until the
|
|
* initialization is complete.
|
|
*/
|
|
writel(PAD_RETENTION_DRAM_COREBLK_VAL,
|
|
&power->pad_retention_dram_coreblk_option);
|
|
do {
|
|
val = readl(&power->pad_retention_dram_status);
|
|
} while (val != 0x1);
|
|
|
|
/*
|
|
* CKE PAD retention disables DRAM self-refresh mode.
|
|
* Send auto refresh command for DRAM refresh.
|
|
*/
|
|
for (i = 0; i < 128; i++) {
|
|
for (chip = 0; chip < mem->chips_to_configure; chip++) {
|
|
writel(DIRECT_CMD_REFA |
|
|
(chip << DIRECT_CMD_CHIP_SHIFT),
|
|
&drex0->directcmd);
|
|
writel(DIRECT_CMD_REFA |
|
|
(chip << DIRECT_CMD_CHIP_SHIFT),
|
|
&drex1->directcmd);
|
|
}
|
|
}
|
|
}
|
|
|
|
if (mem->gate_leveling_enable) {
|
|
writel(PHY_CON0_RESET_VAL, &phy0_ctrl->phy_con0);
|
|
writel(PHY_CON0_RESET_VAL, &phy1_ctrl->phy_con0);
|
|
|
|
setbits_le32(&phy0_ctrl->phy_con0, P0_CMD_EN);
|
|
setbits_le32(&phy1_ctrl->phy_con0, P0_CMD_EN);
|
|
|
|
val = PHY_CON2_RESET_VAL;
|
|
val |= INIT_DESKEW_EN;
|
|
writel(val, &phy0_ctrl->phy_con2);
|
|
writel(val, &phy1_ctrl->phy_con2);
|
|
|
|
val = readl(&phy0_ctrl->phy_con1);
|
|
val |= (RDLVL_PASS_ADJ_VAL << RDLVL_PASS_ADJ_OFFSET);
|
|
writel(val, &phy0_ctrl->phy_con1);
|
|
|
|
val = readl(&phy1_ctrl->phy_con1);
|
|
val |= (RDLVL_PASS_ADJ_VAL << RDLVL_PASS_ADJ_OFFSET);
|
|
writel(val, &phy1_ctrl->phy_con1);
|
|
|
|
n_lock_w_phy0 = (lock0_info & CTRL_LOCK_COARSE_MASK) >> 2;
|
|
n_lock_r = readl(&phy0_ctrl->phy_con12);
|
|
n_lock_r &= ~CTRL_DLL_ON;
|
|
n_lock_r |= n_lock_w_phy0;
|
|
writel(n_lock_r, &phy0_ctrl->phy_con12);
|
|
|
|
n_lock_w_phy1 = (lock1_info & CTRL_LOCK_COARSE_MASK) >> 2;
|
|
n_lock_r = readl(&phy1_ctrl->phy_con12);
|
|
n_lock_r &= ~CTRL_DLL_ON;
|
|
n_lock_r |= n_lock_w_phy1;
|
|
writel(n_lock_r, &phy1_ctrl->phy_con12);
|
|
|
|
val = (0x3 << DIRECT_CMD_BANK_SHIFT) | 0x4;
|
|
for (chip = 0; chip < mem->chips_to_configure; chip++) {
|
|
writel(val | (chip << DIRECT_CMD_CHIP_SHIFT),
|
|
&drex0->directcmd);
|
|
writel(val | (chip << DIRECT_CMD_CHIP_SHIFT),
|
|
&drex1->directcmd);
|
|
}
|
|
|
|
setbits_le32(&phy0_ctrl->phy_con2, RDLVL_GATE_EN);
|
|
setbits_le32(&phy1_ctrl->phy_con2, RDLVL_GATE_EN);
|
|
|
|
setbits_le32(&phy0_ctrl->phy_con0, CTRL_SHGATE);
|
|
setbits_le32(&phy1_ctrl->phy_con0, CTRL_SHGATE);
|
|
|
|
val = readl(&phy0_ctrl->phy_con1);
|
|
val &= ~(CTRL_GATEDURADJ_MASK);
|
|
writel(val, &phy0_ctrl->phy_con1);
|
|
|
|
val = readl(&phy1_ctrl->phy_con1);
|
|
val &= ~(CTRL_GATEDURADJ_MASK);
|
|
writel(val, &phy1_ctrl->phy_con1);
|
|
|
|
writel(CTRL_RDLVL_GATE_ENABLE, &drex0->rdlvl_config);
|
|
i = TIMEOUT_US;
|
|
while (((readl(&drex0->phystatus) & RDLVL_COMPLETE_CHO) !=
|
|
RDLVL_COMPLETE_CHO) && (i > 0)) {
|
|
/*
|
|
* TODO(waihong): Comment on how long this take to
|
|
* timeout
|
|
*/
|
|
sdelay(100);
|
|
i--;
|
|
}
|
|
if (!i)
|
|
return SETUP_ERR_RDLV_COMPLETE_TIMEOUT;
|
|
writel(CTRL_RDLVL_GATE_DISABLE, &drex0->rdlvl_config);
|
|
|
|
writel(CTRL_RDLVL_GATE_ENABLE, &drex1->rdlvl_config);
|
|
i = TIMEOUT_US;
|
|
while (((readl(&drex1->phystatus) & RDLVL_COMPLETE_CHO) !=
|
|
RDLVL_COMPLETE_CHO) && (i > 0)) {
|
|
/*
|
|
* TODO(waihong): Comment on how long this take to
|
|
* timeout
|
|
*/
|
|
sdelay(100);
|
|
i--;
|
|
}
|
|
if (!i)
|
|
return SETUP_ERR_RDLV_COMPLETE_TIMEOUT;
|
|
writel(CTRL_RDLVL_GATE_DISABLE, &drex1->rdlvl_config);
|
|
|
|
writel(0, &phy0_ctrl->phy_con14);
|
|
writel(0, &phy1_ctrl->phy_con14);
|
|
|
|
val = (0x3 << DIRECT_CMD_BANK_SHIFT);
|
|
for (chip = 0; chip < mem->chips_to_configure; chip++) {
|
|
writel(val | (chip << DIRECT_CMD_CHIP_SHIFT),
|
|
&drex0->directcmd);
|
|
writel(val | (chip << DIRECT_CMD_CHIP_SHIFT),
|
|
&drex1->directcmd);
|
|
}
|
|
|
|
/* Common Settings for Leveling */
|
|
val = PHY_CON12_RESET_VAL;
|
|
writel((val + n_lock_w_phy0), &phy0_ctrl->phy_con12);
|
|
writel((val + n_lock_w_phy1), &phy1_ctrl->phy_con12);
|
|
|
|
setbits_le32(&phy0_ctrl->phy_con2, DLL_DESKEW_EN);
|
|
setbits_le32(&phy1_ctrl->phy_con2, DLL_DESKEW_EN);
|
|
}
|
|
|
|
/*
|
|
* Do software read leveling
|
|
*
|
|
* Do this before we turn on auto refresh since the auto refresh can
|
|
* be in conflict with the resync operation that's part of setting
|
|
* read leveling.
|
|
*/
|
|
if (!reset) {
|
|
/* restore calibrated value after resume */
|
|
dmc_set_read_offset_value(phy0_ctrl, readl(&pmu->pmu_spare1));
|
|
dmc_set_read_offset_value(phy1_ctrl, readl(&pmu->pmu_spare2));
|
|
} else {
|
|
software_find_read_offset(phy0_ctrl, 0,
|
|
CTRL_LOCK_COARSE(lock0_info));
|
|
software_find_read_offset(phy1_ctrl, 1,
|
|
CTRL_LOCK_COARSE(lock1_info));
|
|
/* save calibrated value to restore after resume */
|
|
writel(dmc_get_read_offset_value(phy0_ctrl), &pmu->pmu_spare1);
|
|
writel(dmc_get_read_offset_value(phy1_ctrl), &pmu->pmu_spare2);
|
|
}
|
|
|
|
/* Send PALL command */
|
|
dmc_config_prech(mem, &drex0->directcmd);
|
|
dmc_config_prech(mem, &drex1->directcmd);
|
|
|
|
writel(mem->memcontrol, &drex0->memcontrol);
|
|
writel(mem->memcontrol, &drex1->memcontrol);
|
|
|
|
/*
|
|
* Set DMC Concontrol: Enable auto-refresh counter, provide
|
|
* read data fetch cycles and enable DREX auto set powerdown
|
|
* for input buffer of I/O in none read memory state.
|
|
*/
|
|
writel(mem->concontrol | (mem->aref_en << CONCONTROL_AREF_EN_SHIFT) |
|
|
(mem->rd_fetch << CONCONTROL_RD_FETCH_SHIFT)|
|
|
DMC_CONCONTROL_IO_PD_CON(0x2),
|
|
&drex0->concontrol);
|
|
writel(mem->concontrol | (mem->aref_en << CONCONTROL_AREF_EN_SHIFT) |
|
|
(mem->rd_fetch << CONCONTROL_RD_FETCH_SHIFT)|
|
|
DMC_CONCONTROL_IO_PD_CON(0x2),
|
|
&drex1->concontrol);
|
|
|
|
/*
|
|
* Enable Clock Gating Control for DMC
|
|
* this saves around 25 mw dmc power as compared to the power
|
|
* consumption without these bits enabled
|
|
*/
|
|
setbits_le32(&drex0->cgcontrol, DMC_INTERNAL_CG);
|
|
setbits_le32(&drex1->cgcontrol, DMC_INTERNAL_CG);
|
|
|
|
/*
|
|
* As per Exynos5800 UM ver 0.00 section 17.13.2.1
|
|
* CONCONTROL register bit 3 [update_mode], Exynos5800 does not
|
|
* support the PHY initiated update. And it is recommended to set
|
|
* this field to 1'b1 during initialization
|
|
*
|
|
* When we apply PHY-initiated mode, DLL lock value is determined
|
|
* once at DMC init time and not updated later when we change the MIF
|
|
* voltage based on ASV group in kernel. Applying MC-initiated mode
|
|
* makes sure that DLL tracing is ON so that silicon is able to
|
|
* compensate the voltage variation.
|
|
*/
|
|
val = readl(&drex0->concontrol);
|
|
val |= CONCONTROL_UPDATE_MODE;
|
|
writel(val, &drex0->concontrol);
|
|
val = readl(&drex1->concontrol);
|
|
val |= CONCONTROL_UPDATE_MODE;
|
|
writel(val, &drex1->concontrol);
|
|
|
|
return 0;
|
|
}
|
|
#endif
|