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https://github.com/AsahiLinux/u-boot
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4361220dae
For ECC enabled DDR, we use EDMA to reset all memory values to 0. For K2E/L/H/K the priv ID of 8 was indicative of ARM, but that is not the case for K2G, where it is 1. Unfortunately, ddr3 code had hard coded the privID and had missed identification previously. Fix the same, else unforeseen behavior can be expected in our reset of DDR contents to 0 for ECC enablement. Signed-off-by: Nishanth Menon <nm@ti.com> Signed-off-by: Lokesh Vutla <lokeshvutla@ti.com> Reviewed-by: Tom Rini <trini@konsulko.com>
428 lines
12 KiB
C
428 lines
12 KiB
C
/*
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* Keystone2: DDR3 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 <asm/io.h>
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#include <common.h>
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#include <asm/arch/msmc.h>
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#include <asm/arch/ddr3.h>
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#include <asm/arch/psc_defs.h>
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#include <asm/ti-common/ti-edma3.h>
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#define DDR3_EDMA_BLK_SIZE_SHIFT 10
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#define DDR3_EDMA_BLK_SIZE (1 << DDR3_EDMA_BLK_SIZE_SHIFT)
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#define DDR3_EDMA_BCNT 0x8000
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#define DDR3_EDMA_CCNT 1
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#define DDR3_EDMA_XF_SIZE (DDR3_EDMA_BLK_SIZE * DDR3_EDMA_BCNT)
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#define DDR3_EDMA_SLOT_NUM 1
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void ddr3_init_ddrphy(u32 base, struct ddr3_phy_config *phy_cfg)
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{
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unsigned int tmp;
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while ((__raw_readl(base + KS2_DDRPHY_PGSR0_OFFSET)
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& 0x00000001) != 0x00000001)
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;
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__raw_writel(phy_cfg->pllcr, base + KS2_DDRPHY_PLLCR_OFFSET);
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tmp = __raw_readl(base + KS2_DDRPHY_PGCR1_OFFSET);
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tmp &= ~(phy_cfg->pgcr1_mask);
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tmp |= phy_cfg->pgcr1_val;
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__raw_writel(tmp, base + KS2_DDRPHY_PGCR1_OFFSET);
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__raw_writel(phy_cfg->ptr0, base + KS2_DDRPHY_PTR0_OFFSET);
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__raw_writel(phy_cfg->ptr1, base + KS2_DDRPHY_PTR1_OFFSET);
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__raw_writel(phy_cfg->ptr3, base + KS2_DDRPHY_PTR3_OFFSET);
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__raw_writel(phy_cfg->ptr4, base + KS2_DDRPHY_PTR4_OFFSET);
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tmp = __raw_readl(base + KS2_DDRPHY_DCR_OFFSET);
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tmp &= ~(phy_cfg->dcr_mask);
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tmp |= phy_cfg->dcr_val;
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__raw_writel(tmp, base + KS2_DDRPHY_DCR_OFFSET);
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__raw_writel(phy_cfg->dtpr0, base + KS2_DDRPHY_DTPR0_OFFSET);
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__raw_writel(phy_cfg->dtpr1, base + KS2_DDRPHY_DTPR1_OFFSET);
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__raw_writel(phy_cfg->dtpr2, base + KS2_DDRPHY_DTPR2_OFFSET);
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__raw_writel(phy_cfg->mr0, base + KS2_DDRPHY_MR0_OFFSET);
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__raw_writel(phy_cfg->mr1, base + KS2_DDRPHY_MR1_OFFSET);
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if (!cpu_is_k2g())
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__raw_writel(phy_cfg->mr2, base + KS2_DDRPHY_MR2_OFFSET);
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__raw_writel(phy_cfg->dtcr, base + KS2_DDRPHY_DTCR_OFFSET);
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__raw_writel(phy_cfg->pgcr2, base + KS2_DDRPHY_PGCR2_OFFSET);
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__raw_writel(phy_cfg->zq0cr1, base + KS2_DDRPHY_ZQ0CR1_OFFSET);
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__raw_writel(phy_cfg->zq1cr1, base + KS2_DDRPHY_ZQ1CR1_OFFSET);
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__raw_writel(phy_cfg->zq2cr1, base + KS2_DDRPHY_ZQ2CR1_OFFSET);
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__raw_writel(phy_cfg->pir_v1, base + KS2_DDRPHY_PIR_OFFSET);
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while ((__raw_readl(base + KS2_DDRPHY_PGSR0_OFFSET) & 0x1) != 0x1)
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;
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if (cpu_is_k2g()) {
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setbits_le32(base + KS2_DDRPHY_DATX8_4_OFFSET, 0x1);
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clrbits_le32(base + KS2_DDRPHY_DATX8_5_OFFSET, 0x1);
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clrbits_le32(base + KS2_DDRPHY_DATX8_6_OFFSET, 0x1);
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clrbits_le32(base + KS2_DDRPHY_DATX8_7_OFFSET, 0x1);
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clrbits_le32(base + KS2_DDRPHY_DATX8_8_OFFSET, 0x1);
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}
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__raw_writel(phy_cfg->pir_v2, base + KS2_DDRPHY_PIR_OFFSET);
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while ((__raw_readl(base + KS2_DDRPHY_PGSR0_OFFSET) & 0x1) != 0x1)
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;
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}
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void ddr3_init_ddremif(u32 base, struct ddr3_emif_config *emif_cfg)
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{
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__raw_writel(emif_cfg->sdcfg, base + KS2_DDR3_SDCFG_OFFSET);
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__raw_writel(emif_cfg->sdtim1, base + KS2_DDR3_SDTIM1_OFFSET);
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__raw_writel(emif_cfg->sdtim2, base + KS2_DDR3_SDTIM2_OFFSET);
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__raw_writel(emif_cfg->sdtim3, base + KS2_DDR3_SDTIM3_OFFSET);
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__raw_writel(emif_cfg->sdtim4, base + KS2_DDR3_SDTIM4_OFFSET);
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__raw_writel(emif_cfg->zqcfg, base + KS2_DDR3_ZQCFG_OFFSET);
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__raw_writel(emif_cfg->sdrfc, base + KS2_DDR3_SDRFC_OFFSET);
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}
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int ddr3_ecc_support_rmw(u32 base)
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{
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u32 value = __raw_readl(base + KS2_DDR3_MIDR_OFFSET);
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/* Check the DDR3 controller ID reg if the controllers
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supports ECC RMW or not */
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if (value == 0x40461C02)
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return 1;
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return 0;
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}
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static void ddr3_ecc_config(u32 base, u32 value)
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{
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u32 data;
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__raw_writel(value, base + KS2_DDR3_ECC_CTRL_OFFSET);
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udelay(100000); /* delay required to synchronize across clock domains */
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if (value & KS2_DDR3_ECC_EN) {
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/* Clear the 1-bit error count */
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data = __raw_readl(base + KS2_DDR3_ONE_BIT_ECC_ERR_CNT_OFFSET);
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__raw_writel(data, base + KS2_DDR3_ONE_BIT_ECC_ERR_CNT_OFFSET);
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/* enable the ECC interrupt */
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__raw_writel(KS2_DDR3_1B_ECC_ERR_SYS | KS2_DDR3_2B_ECC_ERR_SYS |
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KS2_DDR3_WR_ECC_ERR_SYS,
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base + KS2_DDR3_ECC_INT_ENABLE_SET_SYS_OFFSET);
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/* Clear the ECC error interrupt status */
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__raw_writel(KS2_DDR3_1B_ECC_ERR_SYS | KS2_DDR3_2B_ECC_ERR_SYS |
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KS2_DDR3_WR_ECC_ERR_SYS,
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base + KS2_DDR3_ECC_INT_STATUS_OFFSET);
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}
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}
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static void ddr3_reset_data(u32 base, u32 ddr3_size)
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{
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u32 mpax[2];
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u32 seg_num;
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u32 seg, blks, dst, edma_blks;
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struct edma3_slot_config slot;
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struct edma3_channel_config edma_channel;
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u32 edma_src[DDR3_EDMA_BLK_SIZE/4] __aligned(16) = {0, };
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/* Setup an edma to copy the 1k block to the entire DDR */
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puts("\nClear entire DDR3 memory to enable ECC\n");
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/* save the SES MPAX regs */
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if (cpu_is_k2g())
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msmc_get_ses_mpax(K2G_MSMC_SEGMENT_ARM, 0, mpax);
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else
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msmc_get_ses_mpax(K2HKLE_MSMC_SEGMENT_ARM, 0, mpax);
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/* setup edma slot 1 configuration */
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slot.opt = EDMA3_SLOPT_TRANS_COMP_INT_ENB |
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EDMA3_SLOPT_COMP_CODE(0) |
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EDMA3_SLOPT_STATIC | EDMA3_SLOPT_AB_SYNC;
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slot.bcnt = DDR3_EDMA_BCNT;
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slot.acnt = DDR3_EDMA_BLK_SIZE;
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slot.ccnt = DDR3_EDMA_CCNT;
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slot.src_bidx = 0;
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slot.dst_bidx = DDR3_EDMA_BLK_SIZE;
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slot.src_cidx = 0;
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slot.dst_cidx = 0;
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slot.link = EDMA3_PARSET_NULL_LINK;
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slot.bcntrld = 0;
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edma3_slot_configure(KS2_EDMA0_BASE, DDR3_EDMA_SLOT_NUM, &slot);
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/* configure quik edma channel */
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edma_channel.slot = DDR3_EDMA_SLOT_NUM;
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edma_channel.chnum = 0;
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edma_channel.complete_code = 0;
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/* event trigger after dst update */
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edma_channel.trigger_slot_word = EDMA3_TWORD(dst);
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qedma3_start(KS2_EDMA0_BASE, &edma_channel);
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/* DDR3 size in segments (4KB seg size) */
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seg_num = ddr3_size << (30 - KS2_MSMC_SEG_SIZE_SHIFT);
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for (seg = 0; seg < seg_num; seg += KS2_MSMC_MAP_SEG_NUM) {
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/* map 2GB 36-bit DDR address to 32-bit DDR address in EMIF
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access slave interface so that edma driver can access */
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if (cpu_is_k2g()) {
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msmc_map_ses_segment(K2G_MSMC_SEGMENT_ARM, 0,
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base >> KS2_MSMC_SEG_SIZE_SHIFT,
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KS2_MSMC_DST_SEG_BASE + seg,
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MPAX_SEG_2G);
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} else {
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msmc_map_ses_segment(K2HKLE_MSMC_SEGMENT_ARM, 0,
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base >> KS2_MSMC_SEG_SIZE_SHIFT,
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KS2_MSMC_DST_SEG_BASE + seg,
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MPAX_SEG_2G);
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}
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if ((seg_num - seg) > KS2_MSMC_MAP_SEG_NUM)
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edma_blks = KS2_MSMC_MAP_SEG_NUM <<
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(KS2_MSMC_SEG_SIZE_SHIFT
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- DDR3_EDMA_BLK_SIZE_SHIFT);
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else
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edma_blks = (seg_num - seg) << (KS2_MSMC_SEG_SIZE_SHIFT
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- DDR3_EDMA_BLK_SIZE_SHIFT);
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/* Use edma driver to scrub 2GB DDR memory */
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for (dst = base, blks = 0; blks < edma_blks;
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blks += DDR3_EDMA_BCNT, dst += DDR3_EDMA_XF_SIZE) {
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edma3_set_src_addr(KS2_EDMA0_BASE,
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edma_channel.slot, (u32)edma_src);
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edma3_set_dest_addr(KS2_EDMA0_BASE,
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edma_channel.slot, (u32)dst);
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while (edma3_check_for_transfer(KS2_EDMA0_BASE,
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&edma_channel))
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udelay(10);
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}
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}
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qedma3_stop(KS2_EDMA0_BASE, &edma_channel);
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/* restore the SES MPAX regs */
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if (cpu_is_k2g())
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msmc_set_ses_mpax(K2G_MSMC_SEGMENT_ARM, 0, mpax);
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else
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msmc_set_ses_mpax(K2HKLE_MSMC_SEGMENT_ARM, 0, mpax);
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}
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static void ddr3_ecc_init_range(u32 base)
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{
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u32 ecc_val = KS2_DDR3_ECC_EN;
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u32 rmw = ddr3_ecc_support_rmw(base);
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if (rmw)
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ecc_val |= KS2_DDR3_ECC_RMW_EN;
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__raw_writel(0, base + KS2_DDR3_ECC_ADDR_RANGE1_OFFSET);
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ddr3_ecc_config(base, ecc_val);
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}
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void ddr3_enable_ecc(u32 base, int test)
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{
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u32 ecc_val = KS2_DDR3_ECC_ENABLE;
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u32 rmw = ddr3_ecc_support_rmw(base);
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if (test)
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ecc_val |= KS2_DDR3_ECC_ADDR_RNG_1_EN;
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if (!rmw) {
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if (!test)
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/* by default, disable ecc when rmw = 0 and no
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ecc test */
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ecc_val = 0;
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} else {
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ecc_val |= KS2_DDR3_ECC_RMW_EN;
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}
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ddr3_ecc_config(base, ecc_val);
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}
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void ddr3_disable_ecc(u32 base)
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{
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ddr3_ecc_config(base, 0);
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}
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#if defined(CONFIG_SOC_K2HK) || defined(CONFIG_SOC_K2L)
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static void cic_init(u32 base)
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{
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/* Disable CIC global interrupts */
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__raw_writel(0, base + KS2_CIC_GLOBAL_ENABLE);
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/* Set to normal mode, no nesting, no priority hold */
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__raw_writel(0, base + KS2_CIC_CTRL);
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__raw_writel(0, base + KS2_CIC_HOST_CTRL);
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/* Enable CIC global interrupts */
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__raw_writel(1, base + KS2_CIC_GLOBAL_ENABLE);
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}
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static void cic_map_cic_to_gic(u32 base, u32 chan_num, u32 irq_num)
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{
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/* Map the system interrupt to a CIC channel */
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__raw_writeb(chan_num, base + KS2_CIC_CHAN_MAP(0) + irq_num);
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/* Enable CIC system interrupt */
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__raw_writel(irq_num, base + KS2_CIC_SYS_ENABLE_IDX_SET);
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/* Enable CIC Host interrupt */
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__raw_writel(chan_num, base + KS2_CIC_HOST_ENABLE_IDX_SET);
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}
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static void ddr3_map_ecc_cic2_irq(u32 base)
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{
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cic_init(base);
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cic_map_cic_to_gic(base, KS2_CIC2_DDR3_ECC_CHAN_NUM,
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KS2_CIC2_DDR3_ECC_IRQ_NUM);
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}
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#endif
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void ddr3_init_ecc(u32 base, u32 ddr3_size)
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{
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if (!ddr3_ecc_support_rmw(base)) {
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ddr3_disable_ecc(base);
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return;
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}
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ddr3_ecc_init_range(base);
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ddr3_reset_data(CONFIG_SYS_SDRAM_BASE, ddr3_size);
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/* mapping DDR3 ECC system interrupt from CIC2 to GIC */
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#if defined(CONFIG_SOC_K2HK) || defined(CONFIG_SOC_K2L)
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ddr3_map_ecc_cic2_irq(KS2_CIC2_BASE);
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#endif
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ddr3_enable_ecc(base, 0);
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}
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void ddr3_check_ecc_int(u32 base)
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{
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char *env;
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int ecc_test = 0;
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u32 value = __raw_readl(base + KS2_DDR3_ECC_INT_STATUS_OFFSET);
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env = getenv("ecc_test");
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if (env)
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ecc_test = simple_strtol(env, NULL, 0);
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if (value & KS2_DDR3_WR_ECC_ERR_SYS)
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puts("DDR3 ECC write error interrupted\n");
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if (value & KS2_DDR3_2B_ECC_ERR_SYS) {
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puts("DDR3 ECC 2-bit error interrupted\n");
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if (!ecc_test) {
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puts("Reseting the device ...\n");
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reset_cpu(0);
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}
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}
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value = __raw_readl(base + KS2_DDR3_ONE_BIT_ECC_ERR_CNT_OFFSET);
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if (value) {
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printf("1-bit ECC err count: 0x%x\n", value);
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value = __raw_readl(base +
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KS2_DDR3_ONE_BIT_ECC_ERR_ADDR_LOG_OFFSET);
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printf("1-bit ECC err address log: 0x%x\n", value);
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}
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}
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void ddr3_reset_ddrphy(void)
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{
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u32 tmp;
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/* Assert DDR3A PHY reset */
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tmp = readl(KS2_DDR3APLLCTL1);
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tmp |= KS2_DDR3_PLLCTRL_PHY_RESET;
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writel(tmp, KS2_DDR3APLLCTL1);
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/* wait 10us to catch the reset */
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udelay(10);
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/* Release DDR3A PHY reset */
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tmp = readl(KS2_DDR3APLLCTL1);
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tmp &= ~KS2_DDR3_PLLCTRL_PHY_RESET;
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__raw_writel(tmp, KS2_DDR3APLLCTL1);
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}
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#ifdef CONFIG_SOC_K2HK
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/**
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* ddr3_reset_workaround - reset workaround in case if leveling error
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* detected for PG 1.0 and 1.1 k2hk SoCs
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*/
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void ddr3_err_reset_workaround(void)
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{
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unsigned int tmp;
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unsigned int tmp_a;
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unsigned int tmp_b;
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/*
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* Check for PGSR0 error bits of DDR3 PHY.
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* Check for WLERR, QSGERR, WLAERR,
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* RDERR, WDERR, REERR, WEERR error to see if they are set or not
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*/
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tmp_a = __raw_readl(KS2_DDR3A_DDRPHYC + KS2_DDRPHY_PGSR0_OFFSET);
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tmp_b = __raw_readl(KS2_DDR3B_DDRPHYC + KS2_DDRPHY_PGSR0_OFFSET);
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if (((tmp_a & 0x0FE00000) != 0) || ((tmp_b & 0x0FE00000) != 0)) {
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printf("DDR Leveling Error Detected!\n");
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printf("DDR3A PGSR0 = 0x%x\n", tmp_a);
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printf("DDR3B PGSR0 = 0x%x\n", tmp_b);
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/*
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* Write Keys to KICK registers to enable writes to registers
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* in boot config space
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*/
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__raw_writel(KS2_KICK0_MAGIC, KS2_KICK0);
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__raw_writel(KS2_KICK1_MAGIC, KS2_KICK1);
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/*
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* Move DDR3A Module out of reset isolation by setting
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* MDCTL23[12] = 0
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*/
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tmp_a = __raw_readl(KS2_PSC_BASE +
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PSC_REG_MDCTL(KS2_LPSC_EMIF4F_DDR3A));
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tmp_a = PSC_REG_MDCTL_SET_RESET_ISO(tmp_a, 0);
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__raw_writel(tmp_a, KS2_PSC_BASE +
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PSC_REG_MDCTL(KS2_LPSC_EMIF4F_DDR3A));
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/*
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* Move DDR3B Module out of reset isolation by setting
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* MDCTL24[12] = 0
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*/
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tmp_b = __raw_readl(KS2_PSC_BASE +
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PSC_REG_MDCTL(KS2_LPSC_EMIF4F_DDR3B));
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tmp_b = PSC_REG_MDCTL_SET_RESET_ISO(tmp_b, 0);
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__raw_writel(tmp_b, KS2_PSC_BASE +
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PSC_REG_MDCTL(KS2_LPSC_EMIF4F_DDR3B));
|
|
|
|
/*
|
|
* Write 0x5A69 Key to RSTCTRL[15:0] to unlock writes
|
|
* to RSTCTRL and RSTCFG
|
|
*/
|
|
tmp = __raw_readl(KS2_RSTCTRL);
|
|
tmp &= KS2_RSTCTRL_MASK;
|
|
tmp |= KS2_RSTCTRL_KEY;
|
|
__raw_writel(tmp, KS2_RSTCTRL);
|
|
|
|
/*
|
|
* Set PLL Controller to drive hard reset on SW trigger by
|
|
* setting RSTCFG[13] = 0
|
|
*/
|
|
tmp = __raw_readl(KS2_RSTCTRL_RSCFG);
|
|
tmp &= ~KS2_RSTYPE_PLL_SOFT;
|
|
__raw_writel(tmp, KS2_RSTCTRL_RSCFG);
|
|
|
|
reset_cpu(0);
|
|
}
|
|
}
|
|
#endif
|