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https://github.com/AsahiLinux/u-boot
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c9473b2c37
Commit290ffe5788
(imx8m: fix reading of DDR4 MR registers) lifted a private definition of lpddr4_mr_read() from imx8mm-cl-iot-gate board code to drivers/ddr/imx/imx8m/ddrphy_utils.c, because that version actually seems to work in practice. However, commit99c7cc58e1
(ddr: imx: Add i.MX9 DDR controller driver) reintroduced the broken version in drivers/ddr/imx/imx8m/ddr_init.c, copied most of the rest of ddrphy_utils.c to drivers/ddr/imx/phy/ddrphy_utils.c, and stopped building drivers/ddr/imx/imx8m/ddrphy_utils.c [and that file was then finally completely removed with7e9bd84883
(imx8m: ddrphy_utils: Remove unused file)]. I assume this must have broken the imx8mm-cl-iot-gate board, at least those that have not had their eeprom programmed with the proper information. It certainly did break our out-of-tree board which always reads back the ID register and uses that for a sanity check. So apply the fix from290ffe5788
once again. Fixes:99c7cc58e1
(ddr: imx: Add i.MX9 DDR controller driver) Signed-off-by: Rasmus Villemoes <rasmus.villemoes@prevas.dk> Reviewed-by: Fabio Estevam <festevam@denx.de>
477 lines
14 KiB
C
477 lines
14 KiB
C
// SPDX-License-Identifier: GPL-2.0+
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/*
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* Copyright 2018-2019 NXP
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*/
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#include <common.h>
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#include <errno.h>
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#include <log.h>
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#include <asm/io.h>
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#include <asm/arch/ddr.h>
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#include <asm/arch/clock.h>
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#include <asm/arch/sys_proto.h>
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static unsigned int g_cdd_rr_max[4];
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static unsigned int g_cdd_rw_max[4];
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static unsigned int g_cdd_wr_max[4];
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static unsigned int g_cdd_ww_max[4];
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void ddr_cfg_umctl2(struct dram_cfg_param *ddrc_cfg, int num)
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{
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int i = 0;
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for (i = 0; i < num; i++) {
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reg32_write(ddrc_cfg->reg, ddrc_cfg->val);
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ddrc_cfg++;
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}
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}
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#ifdef CONFIG_IMX8M_DRAM_INLINE_ECC
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void ddrc_inline_ecc_scrub(unsigned int start_address,
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unsigned int range_address)
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{
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unsigned int tmp;
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/* Step1: Enable quasi-dynamic programming */
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reg32_write(DDRC_SWCTL(0), 0x00000000);
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/* Step2: Set ECCCFG1.ecc_parity_region_lock to 1 */
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reg32setbit(DDRC_ECCCFG1(0), 0x4);
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/* Step3: Block the AXI ports from taking the transaction */
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reg32_write(DDRC_PCTRL_0(0), 0x0);
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/* Step4: Set scrub start address */
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reg32_write(DDRC_SBRSTART0(0), start_address);
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/* Step5: Set scrub range address */
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reg32_write(DDRC_SBRRANGE0(0), range_address);
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/* Step6: Set scrub_mode to write */
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reg32_write(DDRC_SBRCTL(0), 0x00000014);
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/* Step7: Set the desired pattern through SBRWDATA0 registers */
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reg32_write(DDRC_SBRWDATA0(0), 0x55aa55aa);
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/* Step8: Enable the SBR by programming SBRCTL.scrub_en=1 */
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reg32setbit(DDRC_SBRCTL(0), 0x0);
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/* Step9: Poll SBRSTAT.scrub_done=1 */
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tmp = reg32_read(DDRC_SBRSTAT(0));
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while (tmp != 0x00000002)
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tmp = reg32_read(DDRC_SBRSTAT(0)) & 0x2;
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/* Step10: Poll SBRSTAT.scrub_busy=0 */
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tmp = reg32_read(DDRC_SBRSTAT(0));
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while (tmp != 0x0)
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tmp = reg32_read(DDRC_SBRSTAT(0)) & 0x1;
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/* Step11: Disable SBR by programming SBRCTL.scrub_en=0 */
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clrbits_le32(DDRC_SBRCTL(0), 0x1);
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/* Step12: Prepare for normal scrub operation(Read) and set scrub_interval*/
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reg32_write(DDRC_SBRCTL(0), 0x100);
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/* Step13: Enable the SBR by programming SBRCTL.scrub_en=1 */
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reg32_write(DDRC_SBRCTL(0), 0x101);
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/* Step14: Enable AXI ports by programming */
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reg32_write(DDRC_PCTRL_0(0), 0x1);
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/* Step15: Disable quasi-dynamic programming */
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reg32_write(DDRC_SWCTL(0), 0x00000001);
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}
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void ddrc_inline_ecc_scrub_end(unsigned int start_address,
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unsigned int range_address)
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{
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/* Step1: Enable quasi-dynamic programming */
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reg32_write(DDRC_SWCTL(0), 0x00000000);
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/* Step2: Block the AXI ports from taking the transaction */
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reg32_write(DDRC_PCTRL_0(0), 0x0);
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/* Step3: Set scrub start address */
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reg32_write(DDRC_SBRSTART0(0), start_address);
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/* Step4: Set scrub range address */
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reg32_write(DDRC_SBRRANGE0(0), range_address);
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/* Step5: Disable SBR by programming SBRCTL.scrub_en=0 */
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clrbits_le32(DDRC_SBRCTL(0), 0x1);
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/* Step6: Prepare for normal scrub operation(Read) and set scrub_interval */
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reg32_write(DDRC_SBRCTL(0), 0x100);
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/* Step7: Enable the SBR by programming SBRCTL.scrub_en=1 */
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reg32_write(DDRC_SBRCTL(0), 0x101);
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/* Step8: Enable AXI ports by programming */
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reg32_write(DDRC_PCTRL_0(0), 0x1);
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/* Step9: Disable quasi-dynamic programming */
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reg32_write(DDRC_SWCTL(0), 0x00000001);
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}
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#endif
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void __weak board_dram_ecc_scrub(void)
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{
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}
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void lpddr4_mr_write(unsigned int mr_rank, unsigned int mr_addr,
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unsigned int mr_data)
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{
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unsigned int tmp;
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/*
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* 1. Poll MRSTAT.mr_wr_busy until it is 0.
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* This checks that there is no outstanding MR transaction.
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* No writes should be performed to MRCTRL0 and MRCTRL1 if
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* MRSTAT.mr_wr_busy = 1.
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*/
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do {
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tmp = reg32_read(DDRC_MRSTAT(0));
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} while (tmp & 0x1);
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/*
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* 2. Write the MRCTRL0.mr_type, MRCTRL0.mr_addr, MRCTRL0.mr_rank and
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* (for MRWs) MRCTRL1.mr_data to define the MR transaction.
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*/
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reg32_write(DDRC_MRCTRL0(0), (mr_rank << 4));
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reg32_write(DDRC_MRCTRL1(0), (mr_addr << 8) | mr_data);
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reg32setbit(DDRC_MRCTRL0(0), 31);
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}
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unsigned int lpddr4_mr_read(unsigned int mr_rank, unsigned int mr_addr)
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{
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unsigned int tmp;
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reg32_write(DRC_PERF_MON_MRR0_DAT(0), 0x1);
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do {
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tmp = reg32_read(DDRC_MRSTAT(0));
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} while (tmp & 0x1);
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reg32_write(DDRC_MRCTRL0(0), (mr_rank << 4) | 0x1);
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reg32_write(DDRC_MRCTRL1(0), (mr_addr << 8));
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reg32setbit(DDRC_MRCTRL0(0), 31);
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do {
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tmp = reg32_read(DRC_PERF_MON_MRR0_DAT(0));
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} while ((tmp & 0x8) == 0);
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tmp = reg32_read(DRC_PERF_MON_MRR1_DAT(0));
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reg32_write(DRC_PERF_MON_MRR0_DAT(0), 0x4);
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while (tmp) { //try to find a significant byte in the word
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if (tmp & 0xff) {
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tmp &= 0xff;
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break;
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}
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tmp >>= 8;
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}
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return tmp;
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}
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static unsigned int look_for_max(unsigned int data[], unsigned int addr_start,
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unsigned int addr_end)
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{
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unsigned int i, imax = 0;
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for (i = addr_start; i <= addr_end; i++) {
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if (((data[i] >> 7) == 0) && data[i] > imax)
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imax = data[i];
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}
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return imax;
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}
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void get_trained_CDD(u32 fsp)
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{
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unsigned int i, ddr_type, tmp;
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unsigned int cdd_cha[12], cdd_chb[12];
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unsigned int cdd_cha_rr_max, cdd_cha_rw_max, cdd_cha_wr_max, cdd_cha_ww_max;
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unsigned int cdd_chb_rr_max, cdd_chb_rw_max, cdd_chb_wr_max, cdd_chb_ww_max;
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ddr_type = reg32_read(DDRC_MSTR(0)) & 0x3f;
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if (ddr_type == 0x20) {
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for (i = 0; i < 6; i++) {
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tmp = reg32_read(IP2APB_DDRPHY_IPS_BASE_ADDR(0) + (0x54013 + i) * 4);
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cdd_cha[i * 2] = tmp & 0xff;
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cdd_cha[i * 2 + 1] = (tmp >> 8) & 0xff;
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}
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for (i = 0; i < 7; i++) {
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tmp = reg32_read(IP2APB_DDRPHY_IPS_BASE_ADDR(0) + (0x5402c + i) * 4);
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if (i == 0) {
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cdd_cha[0] = (tmp >> 8) & 0xff;
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} else if (i == 6) {
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cdd_cha[11] = tmp & 0xff;
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} else {
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cdd_chb[i * 2 - 1] = tmp & 0xff;
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cdd_chb[i * 2] = (tmp >> 8) & 0xff;
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}
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}
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cdd_cha_rr_max = look_for_max(cdd_cha, 0, 1);
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cdd_cha_rw_max = look_for_max(cdd_cha, 2, 5);
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cdd_cha_wr_max = look_for_max(cdd_cha, 6, 9);
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cdd_cha_ww_max = look_for_max(cdd_cha, 10, 11);
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cdd_chb_rr_max = look_for_max(cdd_chb, 0, 1);
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cdd_chb_rw_max = look_for_max(cdd_chb, 2, 5);
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cdd_chb_wr_max = look_for_max(cdd_chb, 6, 9);
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cdd_chb_ww_max = look_for_max(cdd_chb, 10, 11);
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g_cdd_rr_max[fsp] =
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cdd_cha_rr_max > cdd_chb_rr_max ? cdd_cha_rr_max : cdd_chb_rr_max;
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g_cdd_rw_max[fsp] =
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cdd_cha_rw_max > cdd_chb_rw_max ? cdd_cha_rw_max : cdd_chb_rw_max;
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g_cdd_wr_max[fsp] =
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cdd_cha_wr_max > cdd_chb_wr_max ? cdd_cha_wr_max : cdd_chb_wr_max;
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g_cdd_ww_max[fsp] =
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cdd_cha_ww_max > cdd_chb_ww_max ? cdd_cha_ww_max : cdd_chb_ww_max;
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} else {
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unsigned int ddr4_cdd[64];
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for (i = 0; i < 29; i++) {
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tmp = reg32_read(IP2APB_DDRPHY_IPS_BASE_ADDR(0) + (0x54012 + i) * 4);
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ddr4_cdd[i * 2] = tmp & 0xff;
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ddr4_cdd[i * 2 + 1] = (tmp >> 8) & 0xff;
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}
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g_cdd_rr_max[fsp] = look_for_max(ddr4_cdd, 1, 12);
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g_cdd_ww_max[fsp] = look_for_max(ddr4_cdd, 13, 24);
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g_cdd_rw_max[fsp] = look_for_max(ddr4_cdd, 25, 40);
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g_cdd_wr_max[fsp] = look_for_max(ddr4_cdd, 41, 56);
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}
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}
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void update_umctl2_rank_space_setting(unsigned int pstat_num)
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{
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unsigned int i, ddr_type;
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unsigned int addr_slot, rdata, tmp, tmp_t;
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unsigned int ddrc_w2r, ddrc_r2w, ddrc_wr_gap, ddrc_rd_gap;
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ddr_type = reg32_read(DDRC_MSTR(0)) & 0x3f;
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for (i = 0; i < pstat_num; i++) {
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addr_slot = i ? (i + 1) * 0x1000 : 0;
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if (ddr_type == 0x20) {
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/* update r2w:[13:8], w2r:[5:0] */
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rdata = reg32_read(DDRC_DRAMTMG2(0) + addr_slot);
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ddrc_w2r = rdata & 0x3f;
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if (is_imx8mp())
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tmp = ddrc_w2r + (g_cdd_wr_max[i] >> 1);
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else
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tmp = ddrc_w2r + (g_cdd_wr_max[i] >> 1) + 1;
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ddrc_w2r = (tmp > 0x3f) ? 0x3f : tmp;
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ddrc_r2w = (rdata >> 8) & 0x3f;
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if (is_imx8mp())
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tmp = ddrc_r2w + (g_cdd_rw_max[i] >> 1);
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else
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tmp = ddrc_r2w + (g_cdd_rw_max[i] >> 1) + 1;
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ddrc_r2w = (tmp > 0x3f) ? 0x3f : tmp;
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tmp_t = (rdata & 0xffffc0c0) | (ddrc_r2w << 8) | ddrc_w2r;
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reg32_write((DDRC_DRAMTMG2(0) + addr_slot), tmp_t);
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} else {
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/* update w2r:[5:0] */
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rdata = reg32_read(DDRC_DRAMTMG9(0) + addr_slot);
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ddrc_w2r = rdata & 0x3f;
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if (is_imx8mp())
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tmp = ddrc_w2r + (g_cdd_wr_max[i] >> 1);
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else
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tmp = ddrc_w2r + (g_cdd_wr_max[i] >> 1) + 1;
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ddrc_w2r = (tmp > 0x3f) ? 0x3f : tmp;
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tmp_t = (rdata & 0xffffffc0) | ddrc_w2r;
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reg32_write((DDRC_DRAMTMG9(0) + addr_slot), tmp_t);
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/* update r2w:[13:8] */
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rdata = reg32_read(DDRC_DRAMTMG2(0) + addr_slot);
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ddrc_r2w = (rdata >> 8) & 0x3f;
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if (is_imx8mp())
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tmp = ddrc_r2w + (g_cdd_rw_max[i] >> 1);
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else
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tmp = ddrc_r2w + (g_cdd_rw_max[i] >> 1) + 1;
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ddrc_r2w = (tmp > 0x3f) ? 0x3f : tmp;
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tmp_t = (rdata & 0xffffc0ff) | (ddrc_r2w << 8);
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reg32_write((DDRC_DRAMTMG2(0) + addr_slot), tmp_t);
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}
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if (!is_imx8mq()) {
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/*
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* update rankctl: wr_gap:11:8; rd:gap:7:4; quasi-dymic, doc wrong(static)
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*/
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rdata = reg32_read(DDRC_RANKCTL(0) + addr_slot);
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ddrc_wr_gap = (rdata >> 8) & 0xf;
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if (is_imx8mp())
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tmp = ddrc_wr_gap + (g_cdd_ww_max[i] >> 1);
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else
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tmp = ddrc_wr_gap + (g_cdd_ww_max[i] >> 1) + 1;
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ddrc_wr_gap = (tmp > 0xf) ? 0xf : tmp;
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ddrc_rd_gap = (rdata >> 4) & 0xf;
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if (is_imx8mp())
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tmp = ddrc_rd_gap + (g_cdd_rr_max[i] >> 1);
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else
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tmp = ddrc_rd_gap + (g_cdd_rr_max[i] >> 1) + 1;
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ddrc_rd_gap = (tmp > 0xf) ? 0xf : tmp;
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tmp_t = (rdata & 0xfffff00f) | (ddrc_wr_gap << 8) | (ddrc_rd_gap << 4);
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reg32_write((DDRC_RANKCTL(0) + addr_slot), tmp_t);
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}
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}
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if (is_imx8mq()) {
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/* update rankctl: wr_gap:11:8; rd:gap:7:4; quasi-dymic, doc wrong(static) */
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rdata = reg32_read(DDRC_RANKCTL(0));
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ddrc_wr_gap = (rdata >> 8) & 0xf;
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tmp = ddrc_wr_gap + (g_cdd_ww_max[0] >> 1) + 1;
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ddrc_wr_gap = (tmp > 0xf) ? 0xf : tmp;
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ddrc_rd_gap = (rdata >> 4) & 0xf;
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tmp = ddrc_rd_gap + (g_cdd_rr_max[0] >> 1) + 1;
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ddrc_rd_gap = (tmp > 0xf) ? 0xf : tmp;
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tmp_t = (rdata & 0xfffff00f) | (ddrc_wr_gap << 8) | (ddrc_rd_gap << 4);
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reg32_write(DDRC_RANKCTL(0), tmp_t);
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}
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}
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int ddr_init(struct dram_timing_info *dram_timing)
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{
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unsigned int tmp, initial_drate, target_freq;
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int ret;
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debug("DDRINFO: start DRAM init\n");
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/* Step1: Follow the power up procedure */
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if (is_imx8mq()) {
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reg32_write(SRC_DDRC_RCR_ADDR + 0x04, 0x8F00000F);
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reg32_write(SRC_DDRC_RCR_ADDR, 0x8F00000F);
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reg32_write(SRC_DDRC_RCR_ADDR + 0x04, 0x8F000000);
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} else {
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reg32_write(SRC_DDRC_RCR_ADDR, 0x8F00001F);
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reg32_write(SRC_DDRC_RCR_ADDR, 0x8F00000F);
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}
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debug("DDRINFO: cfg clk\n");
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/* change the clock source of dram_apb_clk_root: source 4 800MHz /4 = 200MHz */
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clock_set_target_val(DRAM_APB_CLK_ROOT, CLK_ROOT_ON | CLK_ROOT_SOURCE_SEL(4) |
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CLK_ROOT_PRE_DIV(CLK_ROOT_PRE_DIV4));
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/* disable iso */
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reg32_write(0x303A00EC, 0x0000ffff); /* PGC_CPU_MAPPING */
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reg32setbit(0x303A00F8, 5); /* PU_PGC_SW_PUP_REQ */
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initial_drate = dram_timing->fsp_msg[0].drate;
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/* default to the frequency point 0 clock */
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ddrphy_init_set_dfi_clk(initial_drate);
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/* D-aasert the presetn */
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reg32_write(SRC_DDRC_RCR_ADDR, 0x8F000006);
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/* Step2: Program the dwc_ddr_umctl2 registers */
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debug("DDRINFO: ddrc config start\n");
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ddr_cfg_umctl2(dram_timing->ddrc_cfg, dram_timing->ddrc_cfg_num);
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debug("DDRINFO: ddrc config done\n");
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/* Step3: De-assert reset signal(core_ddrc_rstn & aresetn_n) */
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reg32_write(SRC_DDRC_RCR_ADDR, 0x8F000004);
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reg32_write(SRC_DDRC_RCR_ADDR, 0x8F000000);
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/*
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* Step4: Disable auto-refreshes, self-refresh, powerdown, and
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* assertion of dfi_dram_clk_disable by setting RFSHCTL3.dis_auto_refresh = 1,
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* PWRCTL.powerdown_en = 0, and PWRCTL.selfref_en = 0, PWRCTL.en_dfi_dram_clk_disable = 0
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*/
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reg32_write(DDRC_DBG1(0), 0x00000000);
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reg32_write(DDRC_RFSHCTL3(0), 0x0000001);
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reg32_write(DDRC_PWRCTL(0), 0xa0);
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|
/* if ddr type is LPDDR4, do it */
|
|
tmp = reg32_read(DDRC_MSTR(0));
|
|
if (tmp & (0x1 << 5) && !is_imx8mn())
|
|
reg32_write(DDRC_DDR_SS_GPR0, 0x01); /* LPDDR4 mode */
|
|
|
|
/* determine the initial boot frequency */
|
|
target_freq = reg32_read(DDRC_MSTR2(0)) & 0x3;
|
|
target_freq = (tmp & (0x1 << 29)) ? target_freq : 0x0;
|
|
|
|
/* Step5: Set SWCT.sw_done to 0 */
|
|
reg32_write(DDRC_SWCTL(0), 0x00000000);
|
|
|
|
/* Set the default boot frequency point */
|
|
clrsetbits_le32(DDRC_DFIMISC(0), (0x1f << 8), target_freq << 8);
|
|
/* Step6: Set DFIMISC.dfi_init_complete_en to 0 */
|
|
clrbits_le32(DDRC_DFIMISC(0), 0x1);
|
|
|
|
/* Step7: Set SWCTL.sw_done to 1; need to polling SWSTAT.sw_done_ack */
|
|
reg32_write(DDRC_SWCTL(0), 0x00000001);
|
|
do {
|
|
tmp = reg32_read(DDRC_SWSTAT(0));
|
|
} while ((tmp & 0x1) == 0x0);
|
|
|
|
/*
|
|
* Step8 ~ Step13: Start PHY initialization and training by
|
|
* accessing relevant PUB registers
|
|
*/
|
|
debug("DDRINFO:ddrphy config start\n");
|
|
|
|
ret = ddr_cfg_phy(dram_timing);
|
|
if (ret)
|
|
return ret;
|
|
|
|
debug("DDRINFO: ddrphy config done\n");
|
|
|
|
/*
|
|
* step14 CalBusy.0 =1, indicates the calibrator is actively
|
|
* calibrating. Wait Calibrating done.
|
|
*/
|
|
do {
|
|
tmp = reg32_read(DDRPHY_CalBusy(0));
|
|
} while ((tmp & 0x1));
|
|
|
|
debug("DDRINFO:ddrphy calibration done\n");
|
|
|
|
/* Step15: Set SWCTL.sw_done to 0 */
|
|
reg32_write(DDRC_SWCTL(0), 0x00000000);
|
|
|
|
/* Apply rank-to-rank workaround */
|
|
update_umctl2_rank_space_setting(dram_timing->fsp_msg_num - 1);
|
|
|
|
/* Step16: Set DFIMISC.dfi_init_start to 1 */
|
|
setbits_le32(DDRC_DFIMISC(0), (0x1 << 5));
|
|
|
|
/* Step17: Set SWCTL.sw_done to 1; need to polling SWSTAT.sw_done_ack */
|
|
reg32_write(DDRC_SWCTL(0), 0x00000001);
|
|
do {
|
|
tmp = reg32_read(DDRC_SWSTAT(0));
|
|
} while ((tmp & 0x1) == 0x0);
|
|
|
|
/* Step18: Polling DFISTAT.dfi_init_complete = 1 */
|
|
do {
|
|
tmp = reg32_read(DDRC_DFISTAT(0));
|
|
} while ((tmp & 0x1) == 0x0);
|
|
|
|
/* Step19: Set SWCTL.sw_done to 0 */
|
|
reg32_write(DDRC_SWCTL(0), 0x00000000);
|
|
|
|
/* Step20: Set DFIMISC.dfi_init_start to 0 */
|
|
clrbits_le32(DDRC_DFIMISC(0), (0x1 << 5));
|
|
|
|
/* Step21: optional */
|
|
|
|
/* Step22: Set DFIMISC.dfi_init_complete_en to 1 */
|
|
setbits_le32(DDRC_DFIMISC(0), 0x1);
|
|
|
|
/* Step23: Set PWRCTL.selfref_sw to 0 */
|
|
clrbits_le32(DDRC_PWRCTL(0), (0x1 << 5));
|
|
|
|
/* Step24: Set SWCTL.sw_done to 1; need polling SWSTAT.sw_done_ack */
|
|
reg32_write(DDRC_SWCTL(0), 0x00000001);
|
|
do {
|
|
tmp = reg32_read(DDRC_SWSTAT(0));
|
|
} while ((tmp & 0x1) == 0x0);
|
|
|
|
/* Step25: Wait for dwc_ddr_umctl2 to move to normal operating mode by monitoring
|
|
* STAT.operating_mode signal */
|
|
do {
|
|
tmp = reg32_read(DDRC_STAT(0));
|
|
} while ((tmp & 0x3) != 0x1);
|
|
|
|
/* Step26: Set back register in Step4 to the original values if desired */
|
|
reg32_write(DDRC_RFSHCTL3(0), 0x0000000);
|
|
|
|
/* enable port 0 */
|
|
reg32_write(DDRC_PCTRL_0(0), 0x00000001);
|
|
debug("DDRINFO: ddrmix config done\n");
|
|
|
|
board_dram_ecc_scrub();
|
|
|
|
/* enable selfref_en by default */
|
|
setbits_le32(DDRC_PWRCTL(0), 0x1);
|
|
|
|
/* save the dram timing config into memory */
|
|
dram_config_save(dram_timing, CONFIG_SAVED_DRAM_TIMING_BASE);
|
|
|
|
return 0;
|
|
}
|
|
|
|
ulong ddrphy_addr_remap(uint32_t paddr_apb_from_ctlr)
|
|
{
|
|
return 4 * paddr_apb_from_ctlr;
|
|
}
|