drivers/ram/rockchip/sdram_px30.c - platform/external/u-boot - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /*
  * (C) Copyright 2018 Rockchip Electronics Co., Ltd.
  */

 #include <common.h>
 #include <debug_uart.h>
 #include <dm.h>
 #include <ram.h>
 #include <syscon.h>
 #include <asm/io.h>
 #include <asm/arch-rockchip/clock.h>
 #include <asm/arch-rockchip/cru_px30.h>
 #include <asm/arch-rockchip/grf_px30.h>
 #include <asm/arch-rockchip/hardware.h>
 #include <asm/arch-rockchip/sdram.h>
 #include <asm/arch-rockchip/sdram_px30.h>

 struct dram_info {
 #ifdef CONFIG_TPL_BUILD
 	struct ddr_pctl_regs *pctl;
 	struct ddr_phy_regs *phy;
 	struct px30_cru *cru;
 	struct msch_regs *msch;
 	struct px30_ddr_grf_regs *ddr_grf;
 	struct px30_grf *grf;
 #endif
 	struct ram_info info;
 	struct px30_pmugrf *pmugrf;
 };

 #ifdef CONFIG_TPL_BUILD

 u8 ddr_cfg_2_rbc[] = {
 	/*
 	 * [6:4] max row: 13+n
 	 * [3]  bank(0:4bank,1:8bank)
 	 * [2:0]    col(10+n)
 	 */
 	((5 << 4) | (1 << 3) | 0), /* 0 */
 	((5 << 4) | (1 << 3) | 1), /* 1 */
 	((4 << 4) | (1 << 3) | 2), /* 2 */
 	((3 << 4) | (1 << 3) | 3), /* 3 */
 	((2 << 4) | (1 << 3) | 4), /* 4 */
 	((5 << 4) | (0 << 3) | 2), /* 5 */
 	((4 << 4) | (1 << 3) | 2), /* 6 */
 	/*((0<<3)|3),*/	 /* 12 for ddr4 */
 	/*((1<<3)|1),*/  /* 13 B,C exchange for rkvdec */
 };

 /*
  * for ddr4 if ddrconfig=7, upctl should set 7 and noc should
  * set to 1 for more efficient.
  * noc ddrconf, upctl addrmap
  * 1  7
  * 2  8
  * 3  9
  * 12 10
  * 5  11
  */
 u8 d4_rbc_2_d3_rbc[] = {
 	1, /* 7 */
 	2, /* 8 */
 	3, /* 9 */
 	12, /* 10 */
 	5, /* 11 */
 };

 /*
  * row higher than cs should be disabled by set to 0xf
  * rank addrmap calculate by real cap.
  */
 u32 addrmap[][8] = {
 	/* map0 map1,   map2,       map3,       map4,      map5
 	 * map6,        map7,       map8
 	 * -------------------------------------------------------
 	 * bk2-0       col 5-2     col 9-6    col 11-10   row 11-0
 	 * row 15-12   row 17-16   bg1,0
 	 * -------------------------------------------------------
 	 * 4,3,2       5-2         9-6                    6
 	 *                         3,2
 	 */
 	{0x00060606, 0x00000000, 0x1f1f0000, 0x00001f1f, 0x05050505,
 		0x05050505, 0x00000505, 0x3f3f}, /* 0 */
 	{0x00070707, 0x00000000, 0x1f000000, 0x00001f1f, 0x06060606,
 		0x06060606, 0x06060606, 0x3f3f}, /* 1 */
 	{0x00080808, 0x00000000, 0x00000000, 0x00001f1f, 0x07070707,
 		0x07070707, 0x00000f07, 0x3f3f}, /* 2 */
 	{0x00090909, 0x00000000, 0x00000000, 0x00001f00, 0x08080808,
 		0x08080808, 0x00000f0f, 0x3f3f}, /* 3 */
 	{0x000a0a0a, 0x00000000, 0x00000000, 0x00000000, 0x09090909,
 		0x0f090909, 0x00000f0f, 0x3f3f}, /* 4 */
 	{0x00080808, 0x00000000, 0x00000000, 0x00001f1f, 0x06060606,
 		0x06060606, 0x00000606, 0x3f3f}, /* 5 */
 	{0x00080808, 0x00000000, 0x00000000, 0x00001f1f, 0x07070707,
 		0x07070707, 0x00000f0f, 0x3f3f}, /* 6 */
 	{0x003f0808, 0x00000006, 0x1f1f0000, 0x00001f1f, 0x06060606,
 		0x06060606, 0x00000606, 0x0600}, /* 7 */
 	{0x003f0909, 0x00000007, 0x1f000000, 0x00001f1f, 0x07070707,
 		0x07070707, 0x00000f07, 0x0700}, /* 8 */
 	{0x003f0a0a, 0x01010100, 0x01010101, 0x00001f1f, 0x08080808,
 		0x08080808, 0x00000f0f, 0x0801}, /* 9 */
 	{0x003f0909, 0x01010100, 0x01010101, 0x00001f1f, 0x07070707,
 		0x07070707, 0x00000f07, 0x3f01}, /* 10 */
 	{0x003f0808, 0x00000007, 0x1f000000, 0x00001f1f, 0x06060606,
 		0x06060606, 0x00000606, 0x3f00}, /* 11 */
 	/* when ddr4 12 map to 10, when ddr3 12 unused */
 	{0x003f0909, 0x01010100, 0x01010101, 0x00001f1f, 0x07070707,
 		0x07070707, 0x00000f07, 0x3f01}, /* 10 */
 	{0x00070706, 0x00000000, 0x1f010000, 0x00001f1f, 0x06060606,
 		0x06060606, 0x00000606, 0x3f3f}, /* 13 */
 };

 #define PMUGRF_BASE_ADDR		0xFF010000
 #define CRU_BASE_ADDR			0xFF2B0000
 #define GRF_BASE_ADDR			0xFF140000
 #define DDRC_BASE_ADDR			0xFF600000
 #define DDR_PHY_BASE_ADDR		0xFF2A0000
 #define SERVER_MSCH0_BASE_ADDR		0xFF530000
 #define DDR_GRF_BASE_ADDR		0xff630000

 struct dram_info dram_info;

 struct px30_sdram_params sdram_configs[] = {
 #include	"sdram-px30-ddr3-detect-333.inc"
 };

 struct ddr_phy_skew skew = {
 #include	"sdram-px30-ddr_skew.inc"
 };

 static void rkclk_ddr_reset(struct dram_info *dram,
 			    u32 ctl_srstn, u32 ctl_psrstn,
 			    u32 phy_srstn, u32 phy_psrstn)
 {
 	writel(upctl2_srstn_req(ctl_srstn) | upctl2_psrstn_req(ctl_psrstn) |
 	       upctl2_asrstn_req(ctl_srstn),
 	       &dram->cru->softrst_con[1]);
 	writel(ddrphy_srstn_req(phy_srstn) | ddrphy_psrstn_req(phy_psrstn),
 	       &dram->cru->softrst_con[2]);
 }

 static void rkclk_set_dpll(struct dram_info *dram, unsigned int hz)
 {
 	unsigned int refdiv, postdiv1, postdiv2, fbdiv;
 	int delay = 1000;
 	u32 mhz = hz / MHz;

 	refdiv = 1;
 	if (mhz <= 300) {
 		postdiv1 = 4;
 		postdiv2 = 2;
 	} else if (mhz <= 400) {
 		postdiv1 = 6;
 		postdiv2 = 1;
 	} else if (mhz <= 600) {
 		postdiv1 = 4;
 		postdiv2 = 1;
 	} else if (mhz <= 800) {
 		postdiv1 = 3;
 		postdiv2 = 1;
 	} else if (mhz <= 1600) {
 		postdiv1 = 2;
 		postdiv2 = 1;
 	} else {
 		postdiv1 = 1;
 		postdiv2 = 1;
 	}
 	fbdiv = (mhz * refdiv * postdiv1 * postdiv2) / 24;

 	writel(DPLL_MODE(CLOCK_FROM_XIN_OSC), &dram->cru->mode);

 	writel(POSTDIV1(postdiv1) | FBDIV(fbdiv), &dram->cru->pll[1].con0);
 	writel(DSMPD(1) | POSTDIV2(postdiv2) | REFDIV(refdiv),
 	       &dram->cru->pll[1].con1);

 	while (delay > 0) {
 		udelay(1);
 		if (LOCK(readl(&dram->cru->pll[1].con1)))
 			break;
 		delay--;
 	}

 	writel(DPLL_MODE(CLOCK_FROM_PLL), &dram->cru->mode);
 }

 static void rkclk_configure_ddr(struct dram_info *dram,
 				struct px30_sdram_params *sdram_params)
 {
 	/* for inno ddr phy need 2*freq */
 	rkclk_set_dpll(dram,  sdram_params->base.ddr_freq * MHz * 2);
 }

 /* return ddrconfig value
  *       (-1), find ddrconfig fail
  *       other, the ddrconfig value
  * only support cs0_row >= cs1_row
  */
 static unsigned int calculate_ddrconfig(struct px30_sdram_params *sdram_params)
 {
 	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
 	u32 bw, die_bw, col, bank;
 	u32 i, tmp;
 	u32 ddrconf = -1;

 	bw = cap_info->bw;
 	die_bw = cap_info->dbw;
 	col = cap_info->col;
 	bank = cap_info->bk;

 	if (sdram_params->base.dramtype == DDR4) {
 		if (die_bw == 0)
 			ddrconf = 7 + bw;
 		else
 			ddrconf = 12 - bw;
 		ddrconf = d4_rbc_2_d3_rbc[ddrconf - 7];
 	} else {
 		tmp = ((bank - 2) << 3) | (col + bw - 10);
 		for (i = 0; i < 7; i++)
 			if ((ddr_cfg_2_rbc[i] & 0xf) == tmp) {
 				ddrconf = i;
 				break;
 			}
 		if (i > 6)
 			printascii("calculate ddrconfig error\n");
 	}

 	return ddrconf;
 }

 /*
  * calculate controller dram address map, and setting to register.
  * argument sdram_params->ch.ddrconf must be right value before
  * call this function.
  */
 static void set_ctl_address_map(struct dram_info *dram,
 				struct px30_sdram_params *sdram_params)
 {
 	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
 	void __iomem *pctl_base = dram->pctl;
 	u32 cs_pst, bg, max_row, ddrconf;
 	u32 i;

 	if (sdram_params->base.dramtype == DDR4)
 		/*
 		 * DDR4 8bit dram BG = 2(4bank groups),
 		 * 16bit dram BG = 1 (2 bank groups)
 		 */
 		bg = (cap_info->dbw == 0) ? 2 : 1;
 	else
 		bg = 0;

 	cs_pst = cap_info->bw + cap_info->col +
 		bg + cap_info->bk + cap_info->cs0_row;
 	if (cs_pst >= 32 || cap_info->rank == 1)
 		writel(0x1f, pctl_base + DDR_PCTL2_ADDRMAP0);
 	else
 		writel(cs_pst - 8, pctl_base + DDR_PCTL2_ADDRMAP0);

 	ddrconf = cap_info->ddrconfig;
 	if (sdram_params->base.dramtype == DDR4) {
 		for (i = 0; i < ARRAY_SIZE(d4_rbc_2_d3_rbc); i++) {
 			if (d4_rbc_2_d3_rbc[i] == ddrconf) {
 				ddrconf = 7 + i;
 				break;
 			}
 		}
 	}

 	sdram_copy_to_reg((u32 *)(pctl_base + DDR_PCTL2_ADDRMAP1),
 			  &addrmap[ddrconf][0], 8 * 4);
 	max_row = cs_pst - 1 - 8 - (addrmap[ddrconf][5] & 0xf);

 	if (max_row < 12)
 		printascii("set addrmap fail\n");
 	/* need to disable row ahead of rank by set to 0xf */
 	for (i = 17; i > max_row; i--)
 		clrsetbits_le32(pctl_base + DDR_PCTL2_ADDRMAP6 +
 			((i - 12) * 8 / 32) * 4,
 			0xf << ((i - 12) * 8 % 32),
 			0xf << ((i - 12) * 8 % 32));

 	if ((sdram_params->base.dramtype == LPDDR3 ||
 	     sdram_params->base.dramtype == LPDDR2) &&
 		 cap_info->row_3_4)
 		setbits_le32(pctl_base + DDR_PCTL2_ADDRMAP6, 1 << 31);
 	if (sdram_params->base.dramtype == DDR4 && cap_info->bw != 0x2)
 		setbits_le32(pctl_base + DDR_PCTL2_PCCFG, 1 << 8);
 }

 /*
  * rank = 1: cs0
  * rank = 2: cs1
  */
 int read_mr(struct dram_info *dram, u32 rank, u32 mr_num)
 {
 	void __iomem *ddr_grf_base = dram->ddr_grf;

 	pctl_read_mr(dram->pctl, rank, mr_num);

 	return (readl(ddr_grf_base + DDR_GRF_STATUS(0)) & 0xff);
 }

 #define MIN(a, b)	(((a) > (b)) ? (b) : (a))
 #define MAX(a, b)	(((a) > (b)) ? (a) : (b))
 static u32 check_rd_gate(struct dram_info *dram)
 {
 	void __iomem *phy_base = dram->phy;

 	u32 max_val = 0;
 	u32 min_val = 0xff;
 	u32 gate[4];
 	u32 i, bw;

 	bw = (readl(PHY_REG(phy_base, 0x0)) >> 4) & 0xf;
 	switch (bw) {
 	case 0x1:
 		bw = 1;
 		break;
 	case 0x3:
 		bw = 2;
 		break;
 	case 0xf:
 	default:
 		bw = 4;
 		break;
 	}

 	for (i = 0; i < bw; i++) {
 		gate[i] = readl(PHY_REG(phy_base, 0xfb + i));
 		max_val = MAX(max_val, gate[i]);
 		min_val = MIN(min_val, gate[i]);
 	}

 	if (max_val > 0x80 || min_val < 0x20)
 		return -1;
 	else
 		return 0;
 }

 static int data_training(struct dram_info *dram, u32 cs, u32 dramtype)
 {
 	void __iomem *pctl_base = dram->pctl;
 	u32 dis_auto_zq = 0;
 	u32 pwrctl;
 	u32 ret;

 	/* disable auto low-power */
 	pwrctl = readl(pctl_base + DDR_PCTL2_PWRCTL);
 	writel(0, pctl_base + DDR_PCTL2_PWRCTL);

 	dis_auto_zq = pctl_dis_zqcs_aref(dram->pctl);

 	ret = phy_data_training(dram->phy, cs, dramtype);

 	pctl_rest_zqcs_aref(dram->pctl, dis_auto_zq);

 	/* restore auto low-power */
 	writel(pwrctl, pctl_base + DDR_PCTL2_PWRCTL);

 	return ret;
 }

 static void dram_set_bw(struct dram_info *dram, u32 bw)
 {
 	phy_dram_set_bw(dram->phy, bw);
 }

 static void set_ddrconfig(struct dram_info *dram, u32 ddrconfig)
 {
 	writel(ddrconfig | (ddrconfig << 8), &dram->msch->deviceconf);
 	rk_clrsetreg(&dram->grf->soc_noc_con[1], 0x3 << 14, 0 << 14);
 }

 static void sdram_msch_config(struct msch_regs *msch,
 			      struct sdram_msch_timings *noc_timings,
 			      struct sdram_cap_info *cap_info,
 			      struct sdram_base_params *base)
 {
 	u64 cs_cap[2];

 	cs_cap[0] = sdram_get_cs_cap(cap_info, 0, base->dramtype);
 	cs_cap[1] = sdram_get_cs_cap(cap_info, 1, base->dramtype);
 	writel(((((cs_cap[1] >> 20) / 64) & 0xff) << 8) |
 			(((cs_cap[0] >> 20) / 64) & 0xff),
 			&msch->devicesize);

 	writel(noc_timings->ddrtiminga0.d32,
 	       &msch->ddrtiminga0);
 	writel(noc_timings->ddrtimingb0.d32,
 	       &msch->ddrtimingb0);
 	writel(noc_timings->ddrtimingc0.d32,
 	       &msch->ddrtimingc0);
 	writel(noc_timings->devtodev0.d32,
 	       &msch->devtodev0);
 	writel(noc_timings->ddrmode.d32, &msch->ddrmode);
 	writel(noc_timings->ddr4timing.d32,
 	       &msch->ddr4timing);
 	writel(noc_timings->agingx0, &msch->agingx0);
 	writel(noc_timings->agingx0, &msch->aging0);
 	writel(noc_timings->agingx0, &msch->aging1);
 	writel(noc_timings->agingx0, &msch->aging2);
 	writel(noc_timings->agingx0, &msch->aging3);
 }

 static void dram_all_config(struct dram_info *dram,
 			    struct px30_sdram_params *sdram_params)
 {
 	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
 	u32 sys_reg2 = 0;
 	u32 sys_reg3 = 0;

 	set_ddrconfig(dram, cap_info->ddrconfig);
 	sdram_org_config(cap_info, &sdram_params->base, &sys_reg2,
 			 &sys_reg3, 0);
 	writel(sys_reg2, &dram->pmugrf->os_reg[2]);
 	writel(sys_reg3, &dram->pmugrf->os_reg[3]);
 	sdram_msch_config(dram->msch, &sdram_params->ch.noc_timings, cap_info,
 			  &sdram_params->base);
 }

 static void enable_low_power(struct dram_info *dram,
 			     struct px30_sdram_params *sdram_params)
 {
 	void __iomem *pctl_base = dram->pctl;
 	void __iomem *phy_base = dram->phy;
 	void __iomem *ddr_grf_base = dram->ddr_grf;
 	u32 grf_lp_con;

 	/*
 	 * bit0: grf_upctl_axi_cg_en = 1 enable upctl2 axi clk auto gating
 	 * bit1: grf_upctl_apb_cg_en = 1 ungated axi,core clk for apb access
 	 * bit2: grf_upctl_core_cg_en = 1 enable upctl2 core clk auto gating
 	 * bit3: grf_selfref_type2_en = 0 disable core clk gating when type2 sr
 	 * bit4: grf_upctl_syscreq_cg_en = 1
 	 *       ungating coreclk when c_sysreq assert
 	 * bit8-11: grf_auto_sr_dly = 6
 	 */
 	writel(0x1f1f0617, &dram->ddr_grf->ddr_grf_con[1]);

 	if (sdram_params->base.dramtype == DDR4)
 		grf_lp_con = (0x7 << 16) | (1 << 1);
 	else if (sdram_params->base.dramtype == DDR3)
 		grf_lp_con = (0x7 << 16) | (1 << 0);
 	else
 		grf_lp_con = (0x7 << 16) | (1 << 2);

 	/* en lpckdis_en */
 	grf_lp_con = grf_lp_con | (0x1 << (9 + 16)) | (0x1 << 9);
 	writel(grf_lp_con, ddr_grf_base + DDR_GRF_LP_CON);

 	/* off digit module clock when enter power down */
 	setbits_le32(PHY_REG(phy_base, 7), 1 << 7);

 	/* enable sr, pd */
 	if (PD_IDLE == 0)
 		clrbits_le32(pctl_base + DDR_PCTL2_PWRCTL, (1 << 1));
 	else
 		setbits_le32(pctl_base + DDR_PCTL2_PWRCTL, (1 << 1));
 	if (SR_IDLE == 0)
 		clrbits_le32(pctl_base + DDR_PCTL2_PWRCTL, 1);
 	else
 		setbits_le32(pctl_base + DDR_PCTL2_PWRCTL, 1);
 	setbits_le32(pctl_base + DDR_PCTL2_PWRCTL, (1 << 3));
 }

 /*
  * pre_init: 0: pre init for dram cap detect
  * 1: detect correct cap(except cs1 row)info, than reinit
  * 2: after reinit, we detect cs1_row, if cs1_row not equal
  *    to cs0_row and cs is in middle on ddrconf map, we need
  *    to reinit dram, than set the correct ddrconf.
  */
 static int sdram_init_(struct dram_info *dram,
 		       struct px30_sdram_params *sdram_params, u32 pre_init)
 {
 	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
 	void __iomem *pctl_base = dram->pctl;

 	rkclk_ddr_reset(dram, 1, 1, 1, 1);
 	udelay(10);
 	/*
 	 * dereset ddr phy psrstn to config pll,
 	 * if using phy pll psrstn must be dereset
 	 * before config pll
 	 */
 	rkclk_ddr_reset(dram, 1, 1, 1, 0);
 	rkclk_configure_ddr(dram, sdram_params);

 	/* release phy srst to provide clk to ctrl */
 	rkclk_ddr_reset(dram, 1, 1, 0, 0);
 	udelay(10);
 	phy_soft_reset(dram->phy);
 	/* release ctrl presetn, and config ctl registers */
 	rkclk_ddr_reset(dram, 1, 0, 0, 0);
 	pctl_cfg(dram->pctl, &sdram_params->pctl_regs, SR_IDLE, PD_IDLE);
 	cap_info->ddrconfig = calculate_ddrconfig(sdram_params);
 	set_ctl_address_map(dram, sdram_params);
 	phy_cfg(dram->phy, &sdram_params->phy_regs, sdram_params->skew,
 		&sdram_params->base, cap_info->bw);

 	/* enable dfi_init_start to init phy after ctl srstn deassert */
 	setbits_le32(pctl_base + DDR_PCTL2_DFIMISC, (1 << 5) | (1 << 4));

 	rkclk_ddr_reset(dram, 0, 0, 0, 0);
 	/* wait for dfi_init_done and dram init complete */
 	while ((readl(pctl_base + DDR_PCTL2_STAT) & 0x7) == 0)
 		continue;

 	if (sdram_params->base.dramtype == LPDDR3)
 		pctl_write_mr(dram->pctl, 3, 11, 3, LPDDR3);

 	/* do ddr gate training */
 redo_cs0_training:
 	if (data_training(dram, 0, sdram_params->base.dramtype) != 0) {
 		if (pre_init != 0)
 			printascii("DTT cs0 error\n");
 		return -1;
 	}
 	if (check_rd_gate(dram)) {
 		printascii("re training cs0");
 		goto redo_cs0_training;
 	}

 	if (sdram_params->base.dramtype == LPDDR3) {
 		if ((read_mr(dram, 1, 8) & 0x3) != 0x3)
 			return -1;
 	} else if (sdram_params->base.dramtype == LPDDR2) {
 		if ((read_mr(dram, 1, 8) & 0x3) != 0x0)
 			return -1;
 	}
 	/* for px30: when 2cs, both 2 cs should be training */
 	if (pre_init != 0 && cap_info->rank == 2) {
 redo_cs1_training:
 		if (data_training(dram, 1, sdram_params->base.dramtype) != 0) {
 			printascii("DTT cs1 error\n");
 			return -1;
 		}
 		if (check_rd_gate(dram)) {
 			printascii("re training cs1");
 			goto redo_cs1_training;
 		}
 	}

 	if (sdram_params->base.dramtype == DDR4)
 		pctl_write_vrefdq(dram->pctl, 0x3, 5670,
 				  sdram_params->base.dramtype);

 	dram_all_config(dram, sdram_params);
 	enable_low_power(dram, sdram_params);

 	return 0;
 }

 static int dram_detect_cap(struct dram_info *dram,
 			   struct px30_sdram_params *sdram_params,
 			   unsigned char channel)
 {
 	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;

 	/*
 	 * for ddr3: ddrconf = 3
 	 * for ddr4: ddrconf = 12
 	 * for lpddr3: ddrconf = 3
 	 * default bw = 1
 	 */
 	u32 bk, bktmp;
 	u32 col, coltmp;
 	u32 rowtmp;
 	u32 cs;
 	u32 bw = 1;
 	u32 dram_type = sdram_params->base.dramtype;

 	if (dram_type != DDR4) {
 		/* detect col and bk for ddr3/lpddr3 */
 		coltmp = 12;
 		bktmp = 3;
 		if (dram_type == LPDDR2)
 			rowtmp = 15;
 		else
 			rowtmp = 16;

 		if (sdram_detect_col(cap_info, coltmp) != 0)
 			goto cap_err;
 		sdram_detect_bank(cap_info, coltmp, bktmp);
 		sdram_detect_dbw(cap_info, dram_type);
 	} else {
 		/* detect bg for ddr4 */
 		coltmp = 10;
 		bktmp = 4;
 		rowtmp = 17;

 		col = 10;
 		bk = 2;
 		cap_info->col = col;
 		cap_info->bk = bk;
 		sdram_detect_bg(cap_info, coltmp);
 	}

 	/* detect row */
 	if (sdram_detect_row(cap_info, coltmp, bktmp, rowtmp) != 0)
 		goto cap_err;

 	/* detect row_3_4 */
 	sdram_detect_row_3_4(cap_info, coltmp, bktmp);

 	/* bw and cs detect using data training */
 	if (data_training(dram, 1, dram_type) == 0)
 		cs = 1;
 	else
 		cs = 0;
 	cap_info->rank = cs + 1;

 	dram_set_bw(dram, 2);
 	if (data_training(dram, 0, dram_type) == 0)
 		bw = 2;
 	else
 		bw = 1;
 	cap_info->bw = bw;

 	cap_info->cs0_high16bit_row = cap_info->cs0_row;
 	if (cs) {
 		cap_info->cs1_row = cap_info->cs0_row;
 		cap_info->cs1_high16bit_row = cap_info->cs0_row;
 	} else {
 		cap_info->cs1_row = 0;
 		cap_info->cs1_high16bit_row = 0;
 	}

 	return 0;
 cap_err:
 	return -1;
 }

 /* return: 0 = success, other = fail */
 static int sdram_init_detect(struct dram_info *dram,
 			     struct px30_sdram_params *sdram_params)
 {
 	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
 	u32 ret;
 	u32 sys_reg = 0;
 	u32 sys_reg3 = 0;

 	if (sdram_init_(dram, sdram_params, 0) != 0)
 		return -1;

 	if (dram_detect_cap(dram, sdram_params, 0) != 0)
 		return -1;

 	/* modify bw, cs related timing */
 	pctl_remodify_sdram_params(&sdram_params->pctl_regs, cap_info,
 				   sdram_params->base.dramtype);
 	/* reinit sdram by real dram cap */
 	ret = sdram_init_(dram, sdram_params, 1);
 	if (ret != 0)
 		goto out;

 	/* redetect cs1 row */
 	sdram_detect_cs1_row(cap_info, sdram_params->base.dramtype);
 	if (cap_info->cs1_row) {
 		sys_reg = readl(&dram->pmugrf->os_reg[2]);
 		sys_reg3 = readl(&dram->pmugrf->os_reg[3]);
 		SYS_REG_ENC_CS1_ROW(cap_info->cs1_row,
 				    sys_reg, sys_reg3, 0);
 		writel(sys_reg, &dram->pmugrf->os_reg[2]);
 		writel(sys_reg3, &dram->pmugrf->os_reg[3]);
 	}

 	ret = sdram_detect_high_row(cap_info);

 out:
 	return ret;
 }

 struct px30_sdram_params
 		*get_default_sdram_config(void)
 {
 	sdram_configs[0].skew = &skew;

 	return &sdram_configs[0];
 }

 /* return: 0 = success, other = fail */
 int sdram_init(void)
 {
 	struct px30_sdram_params *sdram_params;
 	int ret = 0;

 	dram_info.phy = (void *)DDR_PHY_BASE_ADDR;
 	dram_info.pctl = (void *)DDRC_BASE_ADDR;
 	dram_info.grf = (void *)GRF_BASE_ADDR;
 	dram_info.cru = (void *)CRU_BASE_ADDR;
 	dram_info.msch = (void *)SERVER_MSCH0_BASE_ADDR;
 	dram_info.ddr_grf = (void *)DDR_GRF_BASE_ADDR;
 	dram_info.pmugrf = (void *)PMUGRF_BASE_ADDR;

 	sdram_params = get_default_sdram_config();
 	ret = sdram_init_detect(&dram_info, sdram_params);

 	if (ret)
 		goto error;

 	sdram_print_ddr_info(&sdram_params->ch.cap_info, &sdram_params->base);

 	printascii("out\n");
 	return ret;
 error:
 	return (-1);
 }
 #else

 static int px30_dmc_probe(struct udevice *dev)
 {
 	struct dram_info *priv = dev_get_priv(dev);

 	priv->pmugrf = syscon_get_first_range(ROCKCHIP_SYSCON_PMUGRF);
 	debug("%s: grf=%p\n", __func__, priv->pmugrf);
 	priv->info.base = CONFIG_SYS_SDRAM_BASE;
 	priv->info.size =
 		rockchip_sdram_size((phys_addr_t)&priv->pmugrf->os_reg[2]);

 	return 0;
 }

 static int px30_dmc_get_info(struct udevice *dev, struct ram_info *info)
 {
 	struct dram_info *priv = dev_get_priv(dev);

 	*info = priv->info;

 	return 0;
 }

 static struct ram_ops px30_dmc_ops = {
 	.get_info = px30_dmc_get_info,
 };

 static const struct udevice_id px30_dmc_ids[] = {
 	{ .compatible = "rockchip,px30-dmc" },
 	{ }
 };

 U_BOOT_DRIVER(dmc_px30) = {
 	.name = "rockchip_px30_dmc",
 	.id = UCLASS_RAM,
 	.of_match = px30_dmc_ids,
 	.ops = &px30_dmc_ops,
 	.probe = px30_dmc_probe,
 	.priv_auto_alloc_size = sizeof(struct dram_info),
 };
 #endif /* CONFIG_TPL_BUILD */
	// SPDX-License-Identifier: GPL-2.0
	/*
	* (C) Copyright 2018 Rockchip Electronics Co., Ltd.
	*/

	#include <common.h>
	#include <debug_uart.h>
	#include <dm.h>
	#include <ram.h>
	#include <syscon.h>
	#include <asm/io.h>
	#include <asm/arch-rockchip/clock.h>
	#include <asm/arch-rockchip/cru_px30.h>
	#include <asm/arch-rockchip/grf_px30.h>
	#include <asm/arch-rockchip/hardware.h>
	#include <asm/arch-rockchip/sdram.h>
	#include <asm/arch-rockchip/sdram_px30.h>

	struct dram_info {
	#ifdef CONFIG_TPL_BUILD
	struct ddr_pctl_regs *pctl;
	struct ddr_phy_regs *phy;
	struct px30_cru *cru;
	struct msch_regs *msch;
	struct px30_ddr_grf_regs *ddr_grf;
	struct px30_grf *grf;
	#endif
	struct ram_info info;
	struct px30_pmugrf *pmugrf;
	};

	#ifdef CONFIG_TPL_BUILD

	u8 ddr_cfg_2_rbc[] = {
	/*
	* [6:4] max row: 13+n
	* [3] bank(0:4bank,1:8bank)
	* [2:0] col(10+n)
	*/
	((5 << 4) \| (1 << 3) \| 0), /* 0 */
	((5 << 4) \| (1 << 3) \| 1), /* 1 */
	((4 << 4) \| (1 << 3) \| 2), /* 2 */
	((3 << 4) \| (1 << 3) \| 3), /* 3 */
	((2 << 4) \| (1 << 3) \| 4), /* 4 */
	((5 << 4) \| (0 << 3) \| 2), /* 5 */
	((4 << 4) \| (1 << 3) \| 2), /* 6 */
	/((0<<3)\|3),/ /* 12 for ddr4 */
	/((1<<3)\|1),/ /* 13 B,C exchange for rkvdec */
	};

	/*
	* for ddr4 if ddrconfig=7, upctl should set 7 and noc should
	* set to 1 for more efficient.
	* noc ddrconf, upctl addrmap
	* 1 7
	* 2 8
	* 3 9
	* 12 10
	* 5 11
	*/
	u8 d4_rbc_2_d3_rbc[] = {
	1, /* 7 */
	2, /* 8 */
	3, /* 9 */
	12, /* 10 */
	5, /* 11 */
	};

	/*
	* row higher than cs should be disabled by set to 0xf
	* rank addrmap calculate by real cap.
	*/
	u32 addrmap[][8] = {
	/* map0 map1, map2, map3, map4, map5
	* map6, map7, map8
	* -------------------------------------------------------
	* bk2-0 col 5-2 col 9-6 col 11-10 row 11-0
	* row 15-12 row 17-16 bg1,0
	* -------------------------------------------------------
	* 4,3,2 5-2 9-6 6
	* 3,2
	*/
	{0x00060606, 0x00000000, 0x1f1f0000, 0x00001f1f, 0x05050505,
	0x05050505, 0x00000505, 0x3f3f}, /* 0 */
	{0x00070707, 0x00000000, 0x1f000000, 0x00001f1f, 0x06060606,
	0x06060606, 0x06060606, 0x3f3f}, /* 1 */
	{0x00080808, 0x00000000, 0x00000000, 0x00001f1f, 0x07070707,
	0x07070707, 0x00000f07, 0x3f3f}, /* 2 */
	{0x00090909, 0x00000000, 0x00000000, 0x00001f00, 0x08080808,
	0x08080808, 0x00000f0f, 0x3f3f}, /* 3 */
	{0x000a0a0a, 0x00000000, 0x00000000, 0x00000000, 0x09090909,
	0x0f090909, 0x00000f0f, 0x3f3f}, /* 4 */
	{0x00080808, 0x00000000, 0x00000000, 0x00001f1f, 0x06060606,
	0x06060606, 0x00000606, 0x3f3f}, /* 5 */
	{0x00080808, 0x00000000, 0x00000000, 0x00001f1f, 0x07070707,
	0x07070707, 0x00000f0f, 0x3f3f}, /* 6 */
	{0x003f0808, 0x00000006, 0x1f1f0000, 0x00001f1f, 0x06060606,
	0x06060606, 0x00000606, 0x0600}, /* 7 */
	{0x003f0909, 0x00000007, 0x1f000000, 0x00001f1f, 0x07070707,
	0x07070707, 0x00000f07, 0x0700}, /* 8 */
	{0x003f0a0a, 0x01010100, 0x01010101, 0x00001f1f, 0x08080808,
	0x08080808, 0x00000f0f, 0x0801}, /* 9 */
	{0x003f0909, 0x01010100, 0x01010101, 0x00001f1f, 0x07070707,
	0x07070707, 0x00000f07, 0x3f01}, /* 10 */
	{0x003f0808, 0x00000007, 0x1f000000, 0x00001f1f, 0x06060606,
	0x06060606, 0x00000606, 0x3f00}, /* 11 */
	/* when ddr4 12 map to 10, when ddr3 12 unused */
	{0x003f0909, 0x01010100, 0x01010101, 0x00001f1f, 0x07070707,
	0x07070707, 0x00000f07, 0x3f01}, /* 10 */
	{0x00070706, 0x00000000, 0x1f010000, 0x00001f1f, 0x06060606,
	0x06060606, 0x00000606, 0x3f3f}, /* 13 */
	};

	#define PMUGRF_BASE_ADDR 0xFF010000
	#define CRU_BASE_ADDR 0xFF2B0000
	#define GRF_BASE_ADDR 0xFF140000
	#define DDRC_BASE_ADDR 0xFF600000
	#define DDR_PHY_BASE_ADDR 0xFF2A0000
	#define SERVER_MSCH0_BASE_ADDR 0xFF530000
	#define DDR_GRF_BASE_ADDR 0xff630000

	struct dram_info dram_info;

	struct px30_sdram_params sdram_configs[] = {
	#include "sdram-px30-ddr3-detect-333.inc"
	};

	struct ddr_phy_skew skew = {
	#include "sdram-px30-ddr_skew.inc"
	};

	static void rkclk_ddr_reset(struct dram_info *dram,
	u32 ctl_srstn, u32 ctl_psrstn,
	u32 phy_srstn, u32 phy_psrstn)
	{
	writel(upctl2_srstn_req(ctl_srstn) \| upctl2_psrstn_req(ctl_psrstn) \|
	upctl2_asrstn_req(ctl_srstn),
	&dram->cru->softrst_con[1]);
	writel(ddrphy_srstn_req(phy_srstn) \| ddrphy_psrstn_req(phy_psrstn),
	&dram->cru->softrst_con[2]);
	}

	static void rkclk_set_dpll(struct dram_info *dram, unsigned int hz)
	{
	unsigned int refdiv, postdiv1, postdiv2, fbdiv;
	int delay = 1000;
	u32 mhz = hz / MHz;

	refdiv = 1;
	if (mhz <= 300) {
	postdiv1 = 4;
	postdiv2 = 2;
	} else if (mhz <= 400) {
	postdiv1 = 6;
	postdiv2 = 1;
	} else if (mhz <= 600) {
	postdiv1 = 4;
	postdiv2 = 1;
	} else if (mhz <= 800) {
	postdiv1 = 3;
	postdiv2 = 1;
	} else if (mhz <= 1600) {
	postdiv1 = 2;
	postdiv2 = 1;
	} else {
	postdiv1 = 1;
	postdiv2 = 1;
	}
	fbdiv = (mhz * refdiv * postdiv1 * postdiv2) / 24;

	writel(DPLL_MODE(CLOCK_FROM_XIN_OSC), &dram->cru->mode);

	writel(POSTDIV1(postdiv1) \| FBDIV(fbdiv), &dram->cru->pll[1].con0);
	writel(DSMPD(1) \| POSTDIV2(postdiv2) \| REFDIV(refdiv),
	&dram->cru->pll[1].con1);

	while (delay > 0) {
	udelay(1);
	if (LOCK(readl(&dram->cru->pll[1].con1)))
	break;
	delay--;
	}

	writel(DPLL_MODE(CLOCK_FROM_PLL), &dram->cru->mode);
	}

	static void rkclk_configure_ddr(struct dram_info *dram,
	struct px30_sdram_params *sdram_params)
	{
	/* for inno ddr phy need 2freq /
	rkclk_set_dpll(dram, sdram_params->base.ddr_freq * MHz * 2);
	}

	/* return ddrconfig value
	* (-1), find ddrconfig fail
	* other, the ddrconfig value
	* only support cs0_row >= cs1_row
	*/
	static unsigned int calculate_ddrconfig(struct px30_sdram_params *sdram_params)
	{
	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
	u32 bw, die_bw, col, bank;
	u32 i, tmp;
	u32 ddrconf = -1;

	bw = cap_info->bw;
	die_bw = cap_info->dbw;
	col = cap_info->col;
	bank = cap_info->bk;

	if (sdram_params->base.dramtype == DDR4) {
	if (die_bw == 0)
	ddrconf = 7 + bw;
	else
	ddrconf = 12 - bw;
	ddrconf = d4_rbc_2_d3_rbc[ddrconf - 7];
	} else {
	tmp = ((bank - 2) << 3) \| (col + bw - 10);
	for (i = 0; i < 7; i++)
	if ((ddr_cfg_2_rbc[i] & 0xf) == tmp) {
	ddrconf = i;
	break;
	}
	if (i > 6)
	printascii("calculate ddrconfig error\n");
	}

	return ddrconf;
	}

	/*
	* calculate controller dram address map, and setting to register.
	* argument sdram_params->ch.ddrconf must be right value before
	* call this function.
	*/
	static void set_ctl_address_map(struct dram_info *dram,
	struct px30_sdram_params *sdram_params)
	{
	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
	void __iomem *pctl_base = dram->pctl;
	u32 cs_pst, bg, max_row, ddrconf;
	u32 i;

	if (sdram_params->base.dramtype == DDR4)
	/*
	* DDR4 8bit dram BG = 2(4bank groups),
	* 16bit dram BG = 1 (2 bank groups)
	*/
	bg = (cap_info->dbw == 0) ? 2 : 1;
	else
	bg = 0;

	cs_pst = cap_info->bw + cap_info->col +
	bg + cap_info->bk + cap_info->cs0_row;
	if (cs_pst >= 32 \|\| cap_info->rank == 1)
	writel(0x1f, pctl_base + DDR_PCTL2_ADDRMAP0);
	else
	writel(cs_pst - 8, pctl_base + DDR_PCTL2_ADDRMAP0);

	ddrconf = cap_info->ddrconfig;
	if (sdram_params->base.dramtype == DDR4) {
	for (i = 0; i < ARRAY_SIZE(d4_rbc_2_d3_rbc); i++) {
	if (d4_rbc_2_d3_rbc[i] == ddrconf) {
	ddrconf = 7 + i;
	break;
	}
	}
	}

	sdram_copy_to_reg((u32 *)(pctl_base + DDR_PCTL2_ADDRMAP1),
	&addrmap[ddrconf][0], 8 * 4);
	max_row = cs_pst - 1 - 8 - (addrmap[ddrconf][5] & 0xf);

	if (max_row < 12)
	printascii("set addrmap fail\n");
	/* need to disable row ahead of rank by set to 0xf */
	for (i = 17; i > max_row; i--)
	clrsetbits_le32(pctl_base + DDR_PCTL2_ADDRMAP6 +
	((i - 12) * 8 / 32) * 4,
	0xf << ((i - 12) * 8 % 32),
	0xf << ((i - 12) * 8 % 32));

	if ((sdram_params->base.dramtype == LPDDR3 \|\|
	sdram_params->base.dramtype == LPDDR2) &&
	cap_info->row_3_4)
	setbits_le32(pctl_base + DDR_PCTL2_ADDRMAP6, 1 << 31);
	if (sdram_params->base.dramtype == DDR4 && cap_info->bw != 0x2)
	setbits_le32(pctl_base + DDR_PCTL2_PCCFG, 1 << 8);
	}

	/*
	* rank = 1: cs0
	* rank = 2: cs1
	*/
	int read_mr(struct dram_info *dram, u32 rank, u32 mr_num)
	{
	void __iomem *ddr_grf_base = dram->ddr_grf;

	pctl_read_mr(dram->pctl, rank, mr_num);

	return (readl(ddr_grf_base + DDR_GRF_STATUS(0)) & 0xff);
	}

	#define MIN(a, b) (((a) > (b)) ? (b) : (a))
	#define MAX(a, b) (((a) > (b)) ? (a) : (b))
	static u32 check_rd_gate(struct dram_info *dram)
	{
	void __iomem *phy_base = dram->phy;

	u32 max_val = 0;
	u32 min_val = 0xff;
	u32 gate[4];
	u32 i, bw;

	bw = (readl(PHY_REG(phy_base, 0x0)) >> 4) & 0xf;
	switch (bw) {
	case 0x1:
	bw = 1;
	break;
	case 0x3:
	bw = 2;
	break;
	case 0xf:
	default:
	bw = 4;
	break;
	}

	for (i = 0; i < bw; i++) {
	gate[i] = readl(PHY_REG(phy_base, 0xfb + i));
	max_val = MAX(max_val, gate[i]);
	min_val = MIN(min_val, gate[i]);
	}

	if (max_val > 0x80 \|\| min_val < 0x20)
	return -1;
	else
	return 0;
	}

	static int data_training(struct dram_info *dram, u32 cs, u32 dramtype)
	{
	void __iomem *pctl_base = dram->pctl;
	u32 dis_auto_zq = 0;
	u32 pwrctl;
	u32 ret;

	/* disable auto low-power */
	pwrctl = readl(pctl_base + DDR_PCTL2_PWRCTL);
	writel(0, pctl_base + DDR_PCTL2_PWRCTL);

	dis_auto_zq = pctl_dis_zqcs_aref(dram->pctl);

	ret = phy_data_training(dram->phy, cs, dramtype);

	pctl_rest_zqcs_aref(dram->pctl, dis_auto_zq);

	/* restore auto low-power */
	writel(pwrctl, pctl_base + DDR_PCTL2_PWRCTL);

	return ret;
	}

	static void dram_set_bw(struct dram_info *dram, u32 bw)
	{
	phy_dram_set_bw(dram->phy, bw);
	}

	static void set_ddrconfig(struct dram_info *dram, u32 ddrconfig)
	{
	writel(ddrconfig \| (ddrconfig << 8), &dram->msch->deviceconf);
	rk_clrsetreg(&dram->grf->soc_noc_con[1], 0x3 << 14, 0 << 14);
	}

	static void sdram_msch_config(struct msch_regs *msch,
	struct sdram_msch_timings *noc_timings,
	struct sdram_cap_info *cap_info,
	struct sdram_base_params *base)
	{
	u64 cs_cap[2];

	cs_cap[0] = sdram_get_cs_cap(cap_info, 0, base->dramtype);
	cs_cap[1] = sdram_get_cs_cap(cap_info, 1, base->dramtype);
	writel(((((cs_cap[1] >> 20) / 64) & 0xff) << 8) \|
	(((cs_cap[0] >> 20) / 64) & 0xff),
	&msch->devicesize);

	writel(noc_timings->ddrtiminga0.d32,
	&msch->ddrtiminga0);
	writel(noc_timings->ddrtimingb0.d32,
	&msch->ddrtimingb0);
	writel(noc_timings->ddrtimingc0.d32,
	&msch->ddrtimingc0);
	writel(noc_timings->devtodev0.d32,
	&msch->devtodev0);
	writel(noc_timings->ddrmode.d32, &msch->ddrmode);
	writel(noc_timings->ddr4timing.d32,
	&msch->ddr4timing);
	writel(noc_timings->agingx0, &msch->agingx0);
	writel(noc_timings->agingx0, &msch->aging0);
	writel(noc_timings->agingx0, &msch->aging1);
	writel(noc_timings->agingx0, &msch->aging2);
	writel(noc_timings->agingx0, &msch->aging3);
	}

	static void dram_all_config(struct dram_info *dram,
	struct px30_sdram_params *sdram_params)
	{
	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
	u32 sys_reg2 = 0;
	u32 sys_reg3 = 0;

	set_ddrconfig(dram, cap_info->ddrconfig);
	sdram_org_config(cap_info, &sdram_params->base, &sys_reg2,
	&sys_reg3, 0);
	writel(sys_reg2, &dram->pmugrf->os_reg[2]);
	writel(sys_reg3, &dram->pmugrf->os_reg[3]);
	sdram_msch_config(dram->msch, &sdram_params->ch.noc_timings, cap_info,
	&sdram_params->base);
	}

	static void enable_low_power(struct dram_info *dram,
	struct px30_sdram_params *sdram_params)
	{
	void __iomem *pctl_base = dram->pctl;
	void __iomem *phy_base = dram->phy;
	void __iomem *ddr_grf_base = dram->ddr_grf;
	u32 grf_lp_con;

	/*
	* bit0: grf_upctl_axi_cg_en = 1 enable upctl2 axi clk auto gating
	* bit1: grf_upctl_apb_cg_en = 1 ungated axi,core clk for apb access
	* bit2: grf_upctl_core_cg_en = 1 enable upctl2 core clk auto gating
	* bit3: grf_selfref_type2_en = 0 disable core clk gating when type2 sr
	* bit4: grf_upctl_syscreq_cg_en = 1
	* ungating coreclk when c_sysreq assert
	* bit8-11: grf_auto_sr_dly = 6
	*/
	writel(0x1f1f0617, &dram->ddr_grf->ddr_grf_con[1]);

	if (sdram_params->base.dramtype == DDR4)
	grf_lp_con = (0x7 << 16) \| (1 << 1);
	else if (sdram_params->base.dramtype == DDR3)
	grf_lp_con = (0x7 << 16) \| (1 << 0);
	else
	grf_lp_con = (0x7 << 16) \| (1 << 2);

	/* en lpckdis_en */
	grf_lp_con = grf_lp_con \| (0x1 << (9 + 16)) \| (0x1 << 9);
	writel(grf_lp_con, ddr_grf_base + DDR_GRF_LP_CON);

	/* off digit module clock when enter power down */
	setbits_le32(PHY_REG(phy_base, 7), 1 << 7);

	/* enable sr, pd */
	if (PD_IDLE == 0)
	clrbits_le32(pctl_base + DDR_PCTL2_PWRCTL, (1 << 1));
	else
	setbits_le32(pctl_base + DDR_PCTL2_PWRCTL, (1 << 1));
	if (SR_IDLE == 0)
	clrbits_le32(pctl_base + DDR_PCTL2_PWRCTL, 1);
	else
	setbits_le32(pctl_base + DDR_PCTL2_PWRCTL, 1);
	setbits_le32(pctl_base + DDR_PCTL2_PWRCTL, (1 << 3));
	}

	/*
	* pre_init: 0: pre init for dram cap detect
	* 1: detect correct cap(except cs1 row)info, than reinit
	* 2: after reinit, we detect cs1_row, if cs1_row not equal
	* to cs0_row and cs is in middle on ddrconf map, we need
	* to reinit dram, than set the correct ddrconf.
	*/
	static int sdram_init_(struct dram_info *dram,
	struct px30_sdram_params *sdram_params, u32 pre_init)
	{
	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
	void __iomem *pctl_base = dram->pctl;

	rkclk_ddr_reset(dram, 1, 1, 1, 1);
	udelay(10);
	/*
	* dereset ddr phy psrstn to config pll,
	* if using phy pll psrstn must be dereset
	* before config pll
	*/
	rkclk_ddr_reset(dram, 1, 1, 1, 0);
	rkclk_configure_ddr(dram, sdram_params);

	/* release phy srst to provide clk to ctrl */
	rkclk_ddr_reset(dram, 1, 1, 0, 0);
	udelay(10);
	phy_soft_reset(dram->phy);
	/* release ctrl presetn, and config ctl registers */
	rkclk_ddr_reset(dram, 1, 0, 0, 0);
	pctl_cfg(dram->pctl, &sdram_params->pctl_regs, SR_IDLE, PD_IDLE);
	cap_info->ddrconfig = calculate_ddrconfig(sdram_params);
	set_ctl_address_map(dram, sdram_params);
	phy_cfg(dram->phy, &sdram_params->phy_regs, sdram_params->skew,
	&sdram_params->base, cap_info->bw);

	/* enable dfi_init_start to init phy after ctl srstn deassert */
	setbits_le32(pctl_base + DDR_PCTL2_DFIMISC, (1 << 5) \| (1 << 4));

	rkclk_ddr_reset(dram, 0, 0, 0, 0);
	/* wait for dfi_init_done and dram init complete */
	while ((readl(pctl_base + DDR_PCTL2_STAT) & 0x7) == 0)
	continue;

	if (sdram_params->base.dramtype == LPDDR3)
	pctl_write_mr(dram->pctl, 3, 11, 3, LPDDR3);

	/* do ddr gate training */
	redo_cs0_training:
	if (data_training(dram, 0, sdram_params->base.dramtype) != 0) {
	if (pre_init != 0)
	printascii("DTT cs0 error\n");
	return -1;
	}
	if (check_rd_gate(dram)) {
	printascii("re training cs0");
	goto redo_cs0_training;
	}

	if (sdram_params->base.dramtype == LPDDR3) {
	if ((read_mr(dram, 1, 8) & 0x3) != 0x3)
	return -1;
	} else if (sdram_params->base.dramtype == LPDDR2) {
	if ((read_mr(dram, 1, 8) & 0x3) != 0x0)
	return -1;
	}
	/* for px30: when 2cs, both 2 cs should be training */
	if (pre_init != 0 && cap_info->rank == 2) {
	redo_cs1_training:
	if (data_training(dram, 1, sdram_params->base.dramtype) != 0) {
	printascii("DTT cs1 error\n");
	return -1;
	}
	if (check_rd_gate(dram)) {
	printascii("re training cs1");
	goto redo_cs1_training;
	}
	}

	if (sdram_params->base.dramtype == DDR4)
	pctl_write_vrefdq(dram->pctl, 0x3, 5670,
	sdram_params->base.dramtype);

	dram_all_config(dram, sdram_params);
	enable_low_power(dram, sdram_params);

	return 0;
	}

	static int dram_detect_cap(struct dram_info *dram,
	struct px30_sdram_params *sdram_params,
	unsigned char channel)
	{
	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;

	/*
	* for ddr3: ddrconf = 3
	* for ddr4: ddrconf = 12
	* for lpddr3: ddrconf = 3
	* default bw = 1
	*/
	u32 bk, bktmp;
	u32 col, coltmp;
	u32 rowtmp;
	u32 cs;
	u32 bw = 1;
	u32 dram_type = sdram_params->base.dramtype;

	if (dram_type != DDR4) {
	/* detect col and bk for ddr3/lpddr3 */
	coltmp = 12;
	bktmp = 3;
	if (dram_type == LPDDR2)
	rowtmp = 15;
	else
	rowtmp = 16;

	if (sdram_detect_col(cap_info, coltmp) != 0)
	goto cap_err;
	sdram_detect_bank(cap_info, coltmp, bktmp);
	sdram_detect_dbw(cap_info, dram_type);
	} else {
	/* detect bg for ddr4 */
	coltmp = 10;
	bktmp = 4;
	rowtmp = 17;

	col = 10;
	bk = 2;
	cap_info->col = col;
	cap_info->bk = bk;
	sdram_detect_bg(cap_info, coltmp);
	}

	/* detect row */
	if (sdram_detect_row(cap_info, coltmp, bktmp, rowtmp) != 0)
	goto cap_err;

	/* detect row_3_4 */
	sdram_detect_row_3_4(cap_info, coltmp, bktmp);

	/* bw and cs detect using data training */
	if (data_training(dram, 1, dram_type) == 0)
	cs = 1;
	else
	cs = 0;
	cap_info->rank = cs + 1;

	dram_set_bw(dram, 2);
	if (data_training(dram, 0, dram_type) == 0)
	bw = 2;
	else
	bw = 1;
	cap_info->bw = bw;

	cap_info->cs0_high16bit_row = cap_info->cs0_row;
	if (cs) {
	cap_info->cs1_row = cap_info->cs0_row;
	cap_info->cs1_high16bit_row = cap_info->cs0_row;
	} else {
	cap_info->cs1_row = 0;
	cap_info->cs1_high16bit_row = 0;
	}

	return 0;
	cap_err:
	return -1;
	}

	/* return: 0 = success, other = fail */
	static int sdram_init_detect(struct dram_info *dram,
	struct px30_sdram_params *sdram_params)
	{
	struct sdram_cap_info *cap_info = &sdram_params->ch.cap_info;
	u32 ret;
	u32 sys_reg = 0;
	u32 sys_reg3 = 0;

	if (sdram_init_(dram, sdram_params, 0) != 0)
	return -1;

	if (dram_detect_cap(dram, sdram_params, 0) != 0)
	return -1;

	/* modify bw, cs related timing */
	pctl_remodify_sdram_params(&sdram_params->pctl_regs, cap_info,
	sdram_params->base.dramtype);
	/* reinit sdram by real dram cap */
	ret = sdram_init_(dram, sdram_params, 1);
	if (ret != 0)
	goto out;

	/* redetect cs1 row */
	sdram_detect_cs1_row(cap_info, sdram_params->base.dramtype);
	if (cap_info->cs1_row) {
	sys_reg = readl(&dram->pmugrf->os_reg[2]);
	sys_reg3 = readl(&dram->pmugrf->os_reg[3]);
	SYS_REG_ENC_CS1_ROW(cap_info->cs1_row,
	sys_reg, sys_reg3, 0);
	writel(sys_reg, &dram->pmugrf->os_reg[2]);
	writel(sys_reg3, &dram->pmugrf->os_reg[3]);
	}

	ret = sdram_detect_high_row(cap_info);

	out:
	return ret;
	}

	struct px30_sdram_params
	*get_default_sdram_config(void)
	{
	sdram_configs[0].skew = &skew;

	return &sdram_configs[0];
	}

	/* return: 0 = success, other = fail */
	int sdram_init(void)
	{
	struct px30_sdram_params *sdram_params;
	int ret = 0;

	dram_info.phy = (void *)DDR_PHY_BASE_ADDR;
	dram_info.pctl = (void *)DDRC_BASE_ADDR;
	dram_info.grf = (void *)GRF_BASE_ADDR;
	dram_info.cru = (void *)CRU_BASE_ADDR;
	dram_info.msch = (void *)SERVER_MSCH0_BASE_ADDR;
	dram_info.ddr_grf = (void *)DDR_GRF_BASE_ADDR;
	dram_info.pmugrf = (void *)PMUGRF_BASE_ADDR;

	sdram_params = get_default_sdram_config();
	ret = sdram_init_detect(&dram_info, sdram_params);

	if (ret)
	goto error;

	sdram_print_ddr_info(&sdram_params->ch.cap_info, &sdram_params->base);

	printascii("out\n");
	return ret;
	error:
	return (-1);
	}
	#else

	static int px30_dmc_probe(struct udevice *dev)
	{
	struct dram_info *priv = dev_get_priv(dev);

	priv->pmugrf = syscon_get_first_range(ROCKCHIP_SYSCON_PMUGRF);
	debug("%s: grf=%p\n", __func__, priv->pmugrf);
	priv->info.base = CONFIG_SYS_SDRAM_BASE;
	priv->info.size =
	rockchip_sdram_size((phys_addr_t)&priv->pmugrf->os_reg[2]);

	return 0;
	}

	static int px30_dmc_get_info(struct udevice dev, struct ram_info info)
	{
	struct dram_info *priv = dev_get_priv(dev);

	*info = priv->info;

	return 0;
	}

	static struct ram_ops px30_dmc_ops = {
	.get_info = px30_dmc_get_info,
	};

	static const struct udevice_id px30_dmc_ids[] = {
	{ .compatible = "rockchip,px30-dmc" },
	{ }
	};

	U_BOOT_DRIVER(dmc_px30) = {
	.name = "rockchip_px30_dmc",
	.id = UCLASS_RAM,
	.of_match = px30_dmc_ids,
	.ops = &px30_dmc_ops,
	.probe = px30_dmc_probe,
	.priv_auto_alloc_size = sizeof(struct dram_info),
	};
	#endif /* CONFIG_TPL_BUILD */