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2d67a095dc
Driver for Cadence EDAC DDR controller, as found in the Renesas RZ/N1. Signed-off-by: Ralph Siemsen <ralph.siemsen@linaro.org> Reviewed-by: Marek Vasut <marek.vasut+renesas@mailbox.org>
414 lines
12 KiB
C
414 lines
12 KiB
C
// SPDX-License-Identifier: BSD-2-Clause
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/*
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* Cadence DDR Controller
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*
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* Copyright (C) 2015 Renesas Electronics Europe Ltd
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*/
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/*
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* The Cadence DDR Controller has a huge number of registers that principally
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* cover two aspects, DDR specific timing information and AXI bus interfacing.
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* Cadence's TCL script generates all of the register values for specific
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* DDR devices operating at a specific frequency. The TCL script uses Denali
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* SOMA files as inputs. The tool also generates the AXI bus register values as
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* well, however this driver assumes that users will want to modifiy these to
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* meet a specific application's needs.
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* Therefore, this driver is passed two arrays containing register values for
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* the DDR device specific information, and explicity sets the AXI registers.
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*
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* AXI bus interfacing:
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* The controller has four AXI slaves connections, and each of these can be
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* programmed to accept requests from specific AXI masters (using their IDs).
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* The regions of DDR that can be accessed by each AXI slave can be set such
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* as to isolate DDR used by one AXI master from another. Further, the maximum
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* bandwidth allocated to each AXI slave can be set.
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*/
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#include <common.h>
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#include <linux/delay.h>
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#include <linux/sizes.h>
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#include <asm/io.h>
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#include <wait_bit.h>
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#include <renesas/ddr_ctrl.h>
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/* avoid warning for real pr_debug in <linux/printk.h> */
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#ifdef pr_debug
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#undef pr_debug
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#endif
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#ifdef DEBUG
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#define pr_debug(fmt, args...) printf(fmt, ##args)
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#define pr_debug2(fmt, args...) printf(fmt, ##args)
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#else
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#define pr_debug(fmt, args...)
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#define pr_debug2(fmt, args...)
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#endif
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#define DDR_NR_AXI_PORTS 4
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#define DDR_NR_ENTRIES 16
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#define DDR_START_REG (0) /* DENALI_CTL_00 */
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#define DDR_CS0_MR1_REG (32 * 4) /* DENALI_CTL_32 */
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#define DDR_CS0_MR2_REG (32 * 4 + 2) /* DENALI_CTL_32 */
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#define DDR_CS1_MR1_REG (34 * 4 + 2) /* DENALI_CTL_34 */
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#define DDR_CS1_MR2_REG (35 * 4) /* DENALI_CTL_35 */
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#define DDR_ECC_ENABLE_REG (36 * 4 + 2) /* DENALI_CTL_36 */
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#define DDR_ECC_DISABLE_W_UC_ERR_REG (37 * 4 + 2) /* DENALI_CTL_37 */
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#define DDR_HALF_DATAPATH_REG (54 * 4) /* DENALI_CTL_54 */
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#define DDR_INTERRUPT_STATUS (56 * 4) /* DENALI_CTL_56 */
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#define DDR_INTERRUPT_ACK (57 * 4) /* DENALI_CTL_57 */
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#define DDR_INTERRUPT_MASK (58 * 4) /* DENALI_CTL_58 */
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#define DDR_CS0_ODT_MAP_REG (62 * 4 + 2) /* DENALI_CTL_62 */
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#define DDR_CS1_ODT_MAP_REG (63 * 4) /* DENALI_CTL_63 */
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#define DDR_ODT_TODTL_2CMD (63 * 4 + 2) /* DENALI_CTL_63 */
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#define DDR_ODT_TODTH_WR (63 * 4 + 3) /* DENALI_CTL_63 */
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#define DDR_ODT_TODTH_RD (64 * 4 + 0) /* DENALI_CTL_64 */
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#define DDR_ODT_EN (64 * 4 + 1) /* DENALI_CTL_64 */
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#define DDR_ODT_WR_TO_ODTH (64 * 4 + 2) /* DENALI_CTL_64 */
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#define DDR_ODT_RD_TO_ODTH (64 * 4 + 3) /* DENALI_CTL_64 */
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#define DDR_DIFF_CS_DELAY_REG (66 * 4) /* DENALI_CTL_66 */
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#define DDR_SAME_CS_DELAY_REG (67 * 4) /* DENALI_CTL_67 */
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#define DDR_RW_PRIORITY_REGS (87 * 4 + 2) /* DENALI_CTL_87 */
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#define DDR_RW_FIFO_TYPE_REGS (88 * 4) /* DENALI_CTL_88 */
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#define DDR_AXI_PORT_PROT_ENABLE_REG (90 * 4 + 3) /* DENALI_CTL_90 */
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#define DDR_ADDR_RANGE_REGS (91 * 4) /* DENALI_CTL_91 */
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#define DDR_RANGE_PROT_REGS (218 * 4 + 2) /* DENALI_CTL_218 */
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#define DDR_ARB_CMD_Q_THRESHOLD_REG (346 * 4 + 2) /* DENALI_CTL_346 */
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#define DDR_AXI_PORT_BANDWIDTH_REG (346 * 4 + 3) /* DENALI_CTL_346 */
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#define DDR_OPT_RMODW_REG (372 * 4 + 3) /* DENALI_CTL_372 */
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static void ddrc_writeb(u8 val, void *p)
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{
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pr_debug2("DDR: %p = 0x%02x\n", p, val);
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writeb(val, p);
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}
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static void ddrc_writew(u16 val, void *p)
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{
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pr_debug2("DDR: %p = 0x%04x\n", p, val);
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writew(val, p);
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}
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static void ddrc_writel(u32 val, void *p)
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{
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pr_debug2("DDR: %p = 0x%08x\n", p, val);
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writel(val, p);
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}
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void cdns_ddr_set_mr1(void *base, int cs, u16 odt_impedance, u16 drive_strength)
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{
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void *reg;
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u16 tmp;
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if (cs == 0)
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reg = (u8 *)base + DDR_CS0_MR1_REG;
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else
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reg = (u8 *)base + DDR_CS1_MR1_REG;
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tmp = readw(reg);
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tmp &= ~MODE_REGISTER_MASK;
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tmp |= MODE_REGISTER_MR1;
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tmp &= ~MR1_ODT_IMPEDANCE_MASK;
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tmp |= odt_impedance;
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tmp &= ~MR1_DRIVE_STRENGTH_MASK;
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tmp |= drive_strength;
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writew(tmp, reg);
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}
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void cdns_ddr_set_mr2(void *base, int cs, u16 dynamic_odt, u16 self_refresh_temp)
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{
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void *reg;
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u16 tmp;
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if (cs == 0)
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reg = (u8 *)base + DDR_CS0_MR2_REG;
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else
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reg = (u8 *)base + DDR_CS1_MR2_REG;
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tmp = readw(reg);
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tmp &= ~MODE_REGISTER_MASK;
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tmp |= MODE_REGISTER_MR2;
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tmp &= ~MR2_DYNAMIC_ODT_MASK;
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tmp |= dynamic_odt;
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tmp &= ~MR2_SELF_REFRESH_TEMP_MASK;
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tmp |= self_refresh_temp;
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writew(tmp, reg);
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}
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void cdns_ddr_set_odt_map(void *base, int cs, u16 odt_map)
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{
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void *reg;
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if (cs == 0)
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reg = (u8 *)base + DDR_CS0_ODT_MAP_REG;
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else
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reg = (u8 *)base + DDR_CS1_ODT_MAP_REG;
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writew(odt_map, reg);
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}
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void cdns_ddr_set_odt_times(void *base, u8 TODTL_2CMD, u8 TODTH_WR, u8 TODTH_RD,
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u8 WR_TO_ODTH, u8 RD_TO_ODTH)
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{
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writeb(TODTL_2CMD, (u8 *)base + DDR_ODT_TODTL_2CMD);
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writeb(TODTH_WR, (u8 *)base + DDR_ODT_TODTH_WR);
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writeb(TODTH_RD, (u8 *)base + DDR_ODT_TODTH_RD);
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writeb(1, (u8 *)base + DDR_ODT_EN);
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writeb(WR_TO_ODTH, (u8 *)base + DDR_ODT_WR_TO_ODTH);
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writeb(RD_TO_ODTH, (u8 *)base + DDR_ODT_RD_TO_ODTH);
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}
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void cdns_ddr_set_same_cs_delays(void *base, u8 r2r, u8 r2w, u8 w2r, u8 w2w)
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{
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u32 val = (w2w << 24) | (w2r << 16) | (r2w << 8) | r2r;
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writel(val, (u8 *)base + DDR_SAME_CS_DELAY_REG);
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}
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void cdns_ddr_set_diff_cs_delays(void *base, u8 r2r, u8 r2w, u8 w2r, u8 w2w)
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{
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u32 val = (w2w << 24) | (w2r << 16) | (r2w << 8) | r2r;
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writel(val, (u8 *)base + DDR_DIFF_CS_DELAY_REG);
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}
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void cdns_ddr_set_port_rw_priority(void *base, int port,
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u8 read_pri, u8 write_pri)
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{
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u8 *reg8 = (u8 *)base + DDR_RW_PRIORITY_REGS;
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reg8 += (port * 3);
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pr_debug("%s port %d (reg8=%p, DENALI_CTL_%d)\n",
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__func__, port, reg8, (reg8 - (u8 *)base) / 4);
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ddrc_writeb(read_pri, reg8++);
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ddrc_writeb(write_pri, reg8++);
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}
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/* The DDR Controller has 16 entries. Each entry can specify an allowed address
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* range (with 16KB resolution) for one of the 4 AXI slave ports.
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*/
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void cdns_ddr_enable_port_addr_range(void *base, int port, int entry,
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u32 addr_start, u32 size)
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{
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u32 addr_end;
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u32 *reg32 = (u32 *)((u8 *)base + DDR_ADDR_RANGE_REGS);
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u32 tmp;
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reg32 += (port * DDR_NR_ENTRIES * 2);
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reg32 += (entry * 2);
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pr_debug("%s port %d, entry %d (reg32=%p, DENALI_CTL_%d)\n",
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__func__, port, entry, reg32, ((u8 *)reg32 - (u8 *)base) / 4);
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/* These registers represent 16KB address blocks */
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addr_start /= SZ_16K;
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size /= SZ_16K;
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if (size)
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addr_end = addr_start + size - 1;
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else
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addr_end = addr_start;
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ddrc_writel(addr_start, reg32++);
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/*
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* end_addr: Ensure we only set the bottom 18-bits as DENALI_CTL_218
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* also contains the AXI0 range protection bits.
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*/
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tmp = readl(reg32);
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tmp &= ~(BIT(18) - 1);
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tmp |= addr_end;
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ddrc_writel(tmp, reg32);
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}
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void cdns_ddr_enable_addr_range(void *base, int entry,
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u32 addr_start, u32 size)
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{
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int axi;
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for (axi = 0; axi < DDR_NR_AXI_PORTS; axi++)
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cdns_ddr_enable_port_addr_range(base, axi, entry,
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addr_start, size);
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}
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void cdns_ddr_enable_port_prot(void *base, int port, int entry,
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enum cdns_ddr_range_prot range_protection_bits,
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u16 range_RID_check_bits,
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u16 range_WID_check_bits,
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u8 range_RID_check_bits_ID_lookup,
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u8 range_WID_check_bits_ID_lookup)
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{
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/*
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* Technically, the offset here points to the byte before the start of
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* the range protection registers. However, all entries consist of 8
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* bytes, except the first one (which is missing a padding byte) so we
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* work around that subtlely.
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*/
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u8 *reg8 = (u8 *)base + DDR_RANGE_PROT_REGS;
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reg8 += (port * DDR_NR_ENTRIES * 8);
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reg8 += (entry * 8);
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pr_debug("%s port %d, entry %d (reg8=%p, DENALI_CTL_%d)\n",
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__func__, port, entry, reg8, (reg8 - (u8 *)base) / 4);
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if (port == 0 && entry == 0)
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ddrc_writeb(range_protection_bits, reg8 + 1);
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else
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ddrc_writeb(range_protection_bits, reg8);
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ddrc_writew(range_RID_check_bits, reg8 + 2);
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ddrc_writew(range_WID_check_bits, reg8 + 4);
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ddrc_writeb(range_RID_check_bits_ID_lookup, reg8 + 6);
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ddrc_writeb(range_WID_check_bits_ID_lookup, reg8 + 7);
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}
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void cdns_ddr_enable_prot(void *base, int entry,
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enum cdns_ddr_range_prot range_protection_bits,
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u16 range_RID_check_bits,
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u16 range_WID_check_bits,
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u8 range_RID_check_bits_ID_lookup,
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u8 range_WID_check_bits_ID_lookup)
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{
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int axi;
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for (axi = 0; axi < DDR_NR_AXI_PORTS; axi++)
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cdns_ddr_enable_port_prot(base, axi, entry,
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range_protection_bits,
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range_RID_check_bits,
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range_WID_check_bits,
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range_RID_check_bits_ID_lookup,
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range_WID_check_bits_ID_lookup);
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}
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void cdns_ddr_set_port_bandwidth(void *base, int port,
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u8 max_percent, u8 overflow_ok)
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{
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u8 *reg8 = (u8 *)base + DDR_AXI_PORT_BANDWIDTH_REG;
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reg8 += (port * 3);
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pr_debug("%s port %d, (reg8=%p, DENALI_CTL_%d)\n",
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__func__, port, reg8, (reg8 - (u8 *)base) / 4);
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ddrc_writeb(max_percent, reg8++); /* Maximum bandwidth percentage */
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ddrc_writeb(overflow_ok, reg8++); /* Bandwidth overflow allowed */
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}
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void cdns_ddr_ctrl_init(void *ddr_ctrl_basex, int async,
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const u32 *reg0, const u32 *reg350,
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u32 ddr_start_addr, u32 ddr_size,
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int enable_ecc, int enable_8bit)
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{
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int i, axi, entry;
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u32 *ddr_ctrl_base = (u32 *)ddr_ctrl_basex;
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u8 *base8 = (u8 *)ddr_ctrl_basex;
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ddrc_writel(*reg0, ddr_ctrl_base + 0);
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/* 1 to 6 are read only */
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for (i = 7; i <= 26; i++)
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ddrc_writel(*(reg0 + i), ddr_ctrl_base + i);
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/* 27 to 29 are not changed */
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for (i = 30; i <= 87; i++)
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ddrc_writel(*(reg0 + i), ddr_ctrl_base + i);
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/* Enable/disable ECC */
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if (enable_ecc) {
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pr_debug("%s enabling ECC\n", __func__);
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ddrc_writeb(1, base8 + DDR_ECC_ENABLE_REG);
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} else {
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ddrc_writeb(0, base8 + DDR_ECC_ENABLE_REG);
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}
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/* ECC: Disable corruption for read/modify/write operations */
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ddrc_writeb(1, base8 + DDR_ECC_DISABLE_W_UC_ERR_REG);
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/* Set 8/16-bit data width using reduce bit (enable half datapath)*/
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if (enable_8bit) {
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pr_debug("%s using 8-bit data\n", __func__);
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ddrc_writeb(1, base8 + DDR_HALF_DATAPATH_REG);
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} else {
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ddrc_writeb(0, base8 + DDR_HALF_DATAPATH_REG);
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}
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/* Threshold for command queue */
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ddrc_writeb(4, base8 + DDR_ARB_CMD_Q_THRESHOLD_REG);
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/* AXI port protection => enable */
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ddrc_writeb(0x01, base8 + DDR_AXI_PORT_PROT_ENABLE_REG);
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/* Set port interface type, default port priority and bandwidths */
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for (axi = 0; axi < DDR_NR_AXI_PORTS; axi++) {
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/* port interface type: synchronous or asynchronous AXI clock */
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u8 *fifo_reg = base8 + DDR_RW_FIFO_TYPE_REGS + (axi * 3);
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if (async)
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ddrc_writeb(0, fifo_reg);
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else
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ddrc_writeb(3, fifo_reg);
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/* R/W priorities */
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cdns_ddr_set_port_rw_priority(ddr_ctrl_base, axi, 2, 2);
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/* AXI bandwidth */
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cdns_ddr_set_port_bandwidth(ddr_ctrl_base, axi, 50, 1);
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}
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/*
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* The hardware requires that the valid address ranges must not overlap.
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* So, we initialise all address ranges to be above the DDR, length 0.
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*/
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for (entry = 0; entry < DDR_NR_ENTRIES; entry++)
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cdns_ddr_enable_addr_range(ddr_ctrl_base, entry,
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ddr_start_addr + ddr_size, 0);
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for (i = 350; i <= 374; i++)
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ddrc_writel(*(reg350 - 350 + i), ddr_ctrl_base + i);
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/* Disable optimised read-modify-write logic */
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ddrc_writeb(0, base8 + DDR_OPT_RMODW_REG);
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/*
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* Disable all interrupts, we are not handling them.
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* For detail of the interrupt mask, ack and status bits, see the
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* manual's description of the 'int_status' parameter.
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*/
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ddrc_writel(0, base8 + DDR_INTERRUPT_MASK);
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/*
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* Default settings to enable full access to the entire DDR.
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* Users can set different ranges and access rights by calling these
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* functions before calling cdns_ddr_ctrl_start().
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*/
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cdns_ddr_enable_addr_range(ddr_ctrl_base, 0,
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ddr_start_addr, ddr_size);
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cdns_ddr_enable_prot(ddr_ctrl_base, 0, CDNS_DDR_RANGE_PROT_BITS_FULL,
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0xffff, 0xffff, 0x0f, 0x0f);
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}
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void cdns_ddr_ctrl_start(void *ddr_ctrl_basex)
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{
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u32 *ddr_ctrl_base = (u32 *)ddr_ctrl_basex;
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u8 *base8 = (u8 *)ddr_ctrl_basex;
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/* Start */
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ddrc_writeb(1, base8 + DDR_START_REG);
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/* Wait for controller to be ready (interrupt status) */
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wait_for_bit_le32(base8 + DDR_INTERRUPT_STATUS, 0x100, true, 1000, false);
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/* clear all interrupts */
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ddrc_writel(~0, base8 + DDR_INTERRUPT_ACK);
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/* Step 19 Wait 500us from MRESETB=1 */
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udelay(500);
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/* Step 20 tCKSRX wait (From supply stable clock for MCK) */
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/* DENALI_CTL_19 TREF_ENABLE=0x1(=1), AREFRESH=0x1(=1) */
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ddrc_writel(0x01000100, ddr_ctrl_base + 19);
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}
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