u-boot/arch/arm/cpu/armv7/mx6/ddr.c
Tim Harvey 3625fd64ef arm: mx6: ddr: set fast-exit on DDR3 if pd_fast_exit specified
Commit fa8b7d66f49f0c7bd41467fe78f6488d8af6976a introduced fast-exit support
to the MMDC however enabling it on the DDR3 got missed. Make sure we enable
it on the DDR3 as well.

Gateworks uses Micron memory as well as Winbond in MX6. We have found in
testing that we need to enable fast-exit for Winbond stability. Gateworks
boards are currently the only boards using the MX6 SPL and enabling
fast-exit mode.

Signed-off-by: Tim Harvey <tharvey@gateworks.com>
2015-05-19 15:22:53 +02:00

560 lines
18 KiB
C

/*
* Copyright (C) 2014 Gateworks Corporation
* Author: Tim Harvey <tharvey@gateworks.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <linux/types.h>
#include <asm/arch/mx6-ddr.h>
#include <asm/arch/sys_proto.h>
#include <asm/io.h>
#include <asm/types.h>
#if defined(CONFIG_MX6SX)
/* Configure MX6SX mmdc iomux */
void mx6sx_dram_iocfg(unsigned width,
const struct mx6sx_iomux_ddr_regs *ddr,
const struct mx6sx_iomux_grp_regs *grp)
{
struct mx6sx_iomux_ddr_regs *mx6_ddr_iomux;
struct mx6sx_iomux_grp_regs *mx6_grp_iomux;
mx6_ddr_iomux = (struct mx6sx_iomux_ddr_regs *)MX6SX_IOM_DDR_BASE;
mx6_grp_iomux = (struct mx6sx_iomux_grp_regs *)MX6SX_IOM_GRP_BASE;
/* DDR IO TYPE */
writel(grp->grp_ddr_type, &mx6_grp_iomux->grp_ddr_type);
writel(grp->grp_ddrpke, &mx6_grp_iomux->grp_ddrpke);
/* CLOCK */
writel(ddr->dram_sdclk_0, &mx6_ddr_iomux->dram_sdclk_0);
/* ADDRESS */
writel(ddr->dram_cas, &mx6_ddr_iomux->dram_cas);
writel(ddr->dram_ras, &mx6_ddr_iomux->dram_ras);
writel(grp->grp_addds, &mx6_grp_iomux->grp_addds);
/* Control */
writel(ddr->dram_reset, &mx6_ddr_iomux->dram_reset);
writel(ddr->dram_sdba2, &mx6_ddr_iomux->dram_sdba2);
writel(ddr->dram_sdcke0, &mx6_ddr_iomux->dram_sdcke0);
writel(ddr->dram_sdcke1, &mx6_ddr_iomux->dram_sdcke1);
writel(ddr->dram_odt0, &mx6_ddr_iomux->dram_odt0);
writel(ddr->dram_odt1, &mx6_ddr_iomux->dram_odt1);
writel(grp->grp_ctlds, &mx6_grp_iomux->grp_ctlds);
/* Data Strobes */
writel(grp->grp_ddrmode_ctl, &mx6_grp_iomux->grp_ddrmode_ctl);
writel(ddr->dram_sdqs0, &mx6_ddr_iomux->dram_sdqs0);
writel(ddr->dram_sdqs1, &mx6_ddr_iomux->dram_sdqs1);
if (width >= 32) {
writel(ddr->dram_sdqs2, &mx6_ddr_iomux->dram_sdqs2);
writel(ddr->dram_sdqs3, &mx6_ddr_iomux->dram_sdqs3);
}
/* Data */
writel(grp->grp_ddrmode, &mx6_grp_iomux->grp_ddrmode);
writel(grp->grp_b0ds, &mx6_grp_iomux->grp_b0ds);
writel(grp->grp_b1ds, &mx6_grp_iomux->grp_b1ds);
if (width >= 32) {
writel(grp->grp_b2ds, &mx6_grp_iomux->grp_b2ds);
writel(grp->grp_b3ds, &mx6_grp_iomux->grp_b3ds);
}
writel(ddr->dram_dqm0, &mx6_ddr_iomux->dram_dqm0);
writel(ddr->dram_dqm1, &mx6_ddr_iomux->dram_dqm1);
if (width >= 32) {
writel(ddr->dram_dqm2, &mx6_ddr_iomux->dram_dqm2);
writel(ddr->dram_dqm3, &mx6_ddr_iomux->dram_dqm3);
}
}
#endif
#if defined(CONFIG_MX6QDL) || defined(CONFIG_MX6Q) || defined(CONFIG_MX6D)
/* Configure MX6DQ mmdc iomux */
void mx6dq_dram_iocfg(unsigned width,
const struct mx6dq_iomux_ddr_regs *ddr,
const struct mx6dq_iomux_grp_regs *grp)
{
volatile struct mx6dq_iomux_ddr_regs *mx6_ddr_iomux;
volatile struct mx6dq_iomux_grp_regs *mx6_grp_iomux;
mx6_ddr_iomux = (struct mx6dq_iomux_ddr_regs *)MX6DQ_IOM_DDR_BASE;
mx6_grp_iomux = (struct mx6dq_iomux_grp_regs *)MX6DQ_IOM_GRP_BASE;
/* DDR IO Type */
mx6_grp_iomux->grp_ddr_type = grp->grp_ddr_type;
mx6_grp_iomux->grp_ddrpke = grp->grp_ddrpke;
/* Clock */
mx6_ddr_iomux->dram_sdclk_0 = ddr->dram_sdclk_0;
mx6_ddr_iomux->dram_sdclk_1 = ddr->dram_sdclk_1;
/* Address */
mx6_ddr_iomux->dram_cas = ddr->dram_cas;
mx6_ddr_iomux->dram_ras = ddr->dram_ras;
mx6_grp_iomux->grp_addds = grp->grp_addds;
/* Control */
mx6_ddr_iomux->dram_reset = ddr->dram_reset;
mx6_ddr_iomux->dram_sdcke0 = ddr->dram_sdcke0;
mx6_ddr_iomux->dram_sdcke1 = ddr->dram_sdcke1;
mx6_ddr_iomux->dram_sdba2 = ddr->dram_sdba2;
mx6_ddr_iomux->dram_sdodt0 = ddr->dram_sdodt0;
mx6_ddr_iomux->dram_sdodt1 = ddr->dram_sdodt1;
mx6_grp_iomux->grp_ctlds = grp->grp_ctlds;
/* Data Strobes */
mx6_grp_iomux->grp_ddrmode_ctl = grp->grp_ddrmode_ctl;
mx6_ddr_iomux->dram_sdqs0 = ddr->dram_sdqs0;
mx6_ddr_iomux->dram_sdqs1 = ddr->dram_sdqs1;
if (width >= 32) {
mx6_ddr_iomux->dram_sdqs2 = ddr->dram_sdqs2;
mx6_ddr_iomux->dram_sdqs3 = ddr->dram_sdqs3;
}
if (width >= 64) {
mx6_ddr_iomux->dram_sdqs4 = ddr->dram_sdqs4;
mx6_ddr_iomux->dram_sdqs5 = ddr->dram_sdqs5;
mx6_ddr_iomux->dram_sdqs6 = ddr->dram_sdqs6;
mx6_ddr_iomux->dram_sdqs7 = ddr->dram_sdqs7;
}
/* Data */
mx6_grp_iomux->grp_ddrmode = grp->grp_ddrmode;
mx6_grp_iomux->grp_b0ds = grp->grp_b0ds;
mx6_grp_iomux->grp_b1ds = grp->grp_b1ds;
if (width >= 32) {
mx6_grp_iomux->grp_b2ds = grp->grp_b2ds;
mx6_grp_iomux->grp_b3ds = grp->grp_b3ds;
}
if (width >= 64) {
mx6_grp_iomux->grp_b4ds = grp->grp_b4ds;
mx6_grp_iomux->grp_b5ds = grp->grp_b5ds;
mx6_grp_iomux->grp_b6ds = grp->grp_b6ds;
mx6_grp_iomux->grp_b7ds = grp->grp_b7ds;
}
mx6_ddr_iomux->dram_dqm0 = ddr->dram_dqm0;
mx6_ddr_iomux->dram_dqm1 = ddr->dram_dqm1;
if (width >= 32) {
mx6_ddr_iomux->dram_dqm2 = ddr->dram_dqm2;
mx6_ddr_iomux->dram_dqm3 = ddr->dram_dqm3;
}
if (width >= 64) {
mx6_ddr_iomux->dram_dqm4 = ddr->dram_dqm4;
mx6_ddr_iomux->dram_dqm5 = ddr->dram_dqm5;
mx6_ddr_iomux->dram_dqm6 = ddr->dram_dqm6;
mx6_ddr_iomux->dram_dqm7 = ddr->dram_dqm7;
}
}
#endif
#if defined(CONFIG_MX6QDL) || defined(CONFIG_MX6DL) || defined(CONFIG_MX6S)
/* Configure MX6SDL mmdc iomux */
void mx6sdl_dram_iocfg(unsigned width,
const struct mx6sdl_iomux_ddr_regs *ddr,
const struct mx6sdl_iomux_grp_regs *grp)
{
volatile struct mx6sdl_iomux_ddr_regs *mx6_ddr_iomux;
volatile struct mx6sdl_iomux_grp_regs *mx6_grp_iomux;
mx6_ddr_iomux = (struct mx6sdl_iomux_ddr_regs *)MX6SDL_IOM_DDR_BASE;
mx6_grp_iomux = (struct mx6sdl_iomux_grp_regs *)MX6SDL_IOM_GRP_BASE;
/* DDR IO Type */
mx6_grp_iomux->grp_ddr_type = grp->grp_ddr_type;
mx6_grp_iomux->grp_ddrpke = grp->grp_ddrpke;
/* Clock */
mx6_ddr_iomux->dram_sdclk_0 = ddr->dram_sdclk_0;
mx6_ddr_iomux->dram_sdclk_1 = ddr->dram_sdclk_1;
/* Address */
mx6_ddr_iomux->dram_cas = ddr->dram_cas;
mx6_ddr_iomux->dram_ras = ddr->dram_ras;
mx6_grp_iomux->grp_addds = grp->grp_addds;
/* Control */
mx6_ddr_iomux->dram_reset = ddr->dram_reset;
mx6_ddr_iomux->dram_sdcke0 = ddr->dram_sdcke0;
mx6_ddr_iomux->dram_sdcke1 = ddr->dram_sdcke1;
mx6_ddr_iomux->dram_sdba2 = ddr->dram_sdba2;
mx6_ddr_iomux->dram_sdodt0 = ddr->dram_sdodt0;
mx6_ddr_iomux->dram_sdodt1 = ddr->dram_sdodt1;
mx6_grp_iomux->grp_ctlds = grp->grp_ctlds;
/* Data Strobes */
mx6_grp_iomux->grp_ddrmode_ctl = grp->grp_ddrmode_ctl;
mx6_ddr_iomux->dram_sdqs0 = ddr->dram_sdqs0;
mx6_ddr_iomux->dram_sdqs1 = ddr->dram_sdqs1;
if (width >= 32) {
mx6_ddr_iomux->dram_sdqs2 = ddr->dram_sdqs2;
mx6_ddr_iomux->dram_sdqs3 = ddr->dram_sdqs3;
}
if (width >= 64) {
mx6_ddr_iomux->dram_sdqs4 = ddr->dram_sdqs4;
mx6_ddr_iomux->dram_sdqs5 = ddr->dram_sdqs5;
mx6_ddr_iomux->dram_sdqs6 = ddr->dram_sdqs6;
mx6_ddr_iomux->dram_sdqs7 = ddr->dram_sdqs7;
}
/* Data */
mx6_grp_iomux->grp_ddrmode = grp->grp_ddrmode;
mx6_grp_iomux->grp_b0ds = grp->grp_b0ds;
mx6_grp_iomux->grp_b1ds = grp->grp_b1ds;
if (width >= 32) {
mx6_grp_iomux->grp_b2ds = grp->grp_b2ds;
mx6_grp_iomux->grp_b3ds = grp->grp_b3ds;
}
if (width >= 64) {
mx6_grp_iomux->grp_b4ds = grp->grp_b4ds;
mx6_grp_iomux->grp_b5ds = grp->grp_b5ds;
mx6_grp_iomux->grp_b6ds = grp->grp_b6ds;
mx6_grp_iomux->grp_b7ds = grp->grp_b7ds;
}
mx6_ddr_iomux->dram_dqm0 = ddr->dram_dqm0;
mx6_ddr_iomux->dram_dqm1 = ddr->dram_dqm1;
if (width >= 32) {
mx6_ddr_iomux->dram_dqm2 = ddr->dram_dqm2;
mx6_ddr_iomux->dram_dqm3 = ddr->dram_dqm3;
}
if (width >= 64) {
mx6_ddr_iomux->dram_dqm4 = ddr->dram_dqm4;
mx6_ddr_iomux->dram_dqm5 = ddr->dram_dqm5;
mx6_ddr_iomux->dram_dqm6 = ddr->dram_dqm6;
mx6_ddr_iomux->dram_dqm7 = ddr->dram_dqm7;
}
}
#endif
/*
* Configure mx6 mmdc registers based on:
* - board-specific memory configuration
* - board-specific calibration data
* - ddr3 chip details
*
* The various calculations here are derived from the Freescale
* i.Mx6DQSDL DDR3 Script Aid spreadsheet (DOC-94917) designed to generate MMDC
* configuration registers based on memory system and memory chip parameters.
*
* The defaults here are those which were specified in the spreadsheet.
* For details on each register, refer to the IMX6DQRM and/or IMX6SDLRM
* section titled MMDC initialization
*/
#define MR(val, ba, cmd, cs1) \
((val << 16) | (1 << 15) | (cmd << 4) | (cs1 << 3) | ba)
#ifdef CONFIG_MX6SX
#define MMDC1(entry, value) do {} while (0)
#else
#define MMDC1(entry, value) do { mmdc1->entry = value; } while (0)
#endif
void mx6_dram_cfg(const struct mx6_ddr_sysinfo *sysinfo,
const struct mx6_mmdc_calibration *calib,
const struct mx6_ddr3_cfg *ddr3_cfg)
{
volatile struct mmdc_p_regs *mmdc0;
#ifndef CONFIG_MX6SX
volatile struct mmdc_p_regs *mmdc1;
#endif
u32 val;
u8 tcke, tcksrx, tcksre, txpdll, taofpd, taonpd, trrd;
u8 todtlon, taxpd, tanpd, tcwl, txp, tfaw, tcl;
u8 todt_idle_off = 0x4; /* from DDR3 Script Aid spreadsheet */
u16 trcd, trc, tras, twr, tmrd, trtp, trp, twtr, trfc, txs, txpr;
u16 cs0_end;
u16 tdllk = 0x1ff; /* DLL locking time: 512 cycles (JEDEC DDR3) */
u8 coladdr;
int clkper; /* clock period in picoseconds */
int clock; /* clock freq in MHz */
int cs;
u16 mem_speed = ddr3_cfg->mem_speed;
mmdc0 = (struct mmdc_p_regs *)MMDC_P0_BASE_ADDR;
#ifndef CONFIG_MX6SX
mmdc1 = (struct mmdc_p_regs *)MMDC_P1_BASE_ADDR;
#endif
/* Limit mem_speed for MX6D/MX6Q */
if (is_cpu_type(MXC_CPU_MX6Q) || is_cpu_type(MXC_CPU_MX6D)) {
if (mem_speed > 1066)
mem_speed = 1066; /* 1066 MT/s */
tcwl = 4;
}
/* Limit mem_speed for MX6S/MX6DL */
else {
if (mem_speed > 800)
mem_speed = 800; /* 800 MT/s */
tcwl = 3;
}
clock = mem_speed / 2;
/*
* Data rate of 1066 MT/s requires 533 MHz DDR3 clock, but MX6D/Q supports
* up to 528 MHz, so reduce the clock to fit chip specs
*/
if (is_cpu_type(MXC_CPU_MX6Q) || is_cpu_type(MXC_CPU_MX6D)) {
if (clock > 528)
clock = 528; /* 528 MHz */
}
clkper = (1000 * 1000) / clock; /* pico seconds */
todtlon = tcwl;
taxpd = tcwl;
tanpd = tcwl;
switch (ddr3_cfg->density) {
case 1: /* 1Gb per chip */
trfc = DIV_ROUND_UP(110000, clkper) - 1;
txs = DIV_ROUND_UP(120000, clkper) - 1;
break;
case 2: /* 2Gb per chip */
trfc = DIV_ROUND_UP(160000, clkper) - 1;
txs = DIV_ROUND_UP(170000, clkper) - 1;
break;
case 4: /* 4Gb per chip */
trfc = DIV_ROUND_UP(260000, clkper) - 1;
txs = DIV_ROUND_UP(270000, clkper) - 1;
break;
case 8: /* 8Gb per chip */
trfc = DIV_ROUND_UP(350000, clkper) - 1;
txs = DIV_ROUND_UP(360000, clkper) - 1;
break;
default:
/* invalid density */
puts("invalid chip density\n");
hang();
break;
}
txpr = txs;
switch (mem_speed) {
case 800:
txp = DIV_ROUND_UP(max(3 * clkper, 7500), clkper) - 1;
tcke = DIV_ROUND_UP(max(3 * clkper, 7500), clkper) - 1;
if (ddr3_cfg->pagesz == 1) {
tfaw = DIV_ROUND_UP(40000, clkper) - 1;
trrd = DIV_ROUND_UP(max(4 * clkper, 10000), clkper) - 1;
} else {
tfaw = DIV_ROUND_UP(50000, clkper) - 1;
trrd = DIV_ROUND_UP(max(4 * clkper, 10000), clkper) - 1;
}
break;
case 1066:
txp = DIV_ROUND_UP(max(3 * clkper, 7500), clkper) - 1;
tcke = DIV_ROUND_UP(max(3 * clkper, 5625), clkper) - 1;
if (ddr3_cfg->pagesz == 1) {
tfaw = DIV_ROUND_UP(37500, clkper) - 1;
trrd = DIV_ROUND_UP(max(4 * clkper, 7500), clkper) - 1;
} else {
tfaw = DIV_ROUND_UP(50000, clkper) - 1;
trrd = DIV_ROUND_UP(max(4 * clkper, 10000), clkper) - 1;
}
break;
default:
puts("invalid memory speed\n");
hang();
break;
}
txpdll = DIV_ROUND_UP(max(10 * clkper, 24000), clkper) - 1;
tcksre = DIV_ROUND_UP(max(5 * clkper, 10000), clkper);
taonpd = DIV_ROUND_UP(2000, clkper) - 1;
tcksrx = tcksre;
taofpd = taonpd;
twr = DIV_ROUND_UP(15000, clkper) - 1;
tmrd = DIV_ROUND_UP(max(12 * clkper, 15000), clkper) - 1;
trc = DIV_ROUND_UP(ddr3_cfg->trcmin, clkper / 10) - 1;
tras = DIV_ROUND_UP(ddr3_cfg->trasmin, clkper / 10) - 1;
tcl = DIV_ROUND_UP(ddr3_cfg->trcd, clkper / 10) - 3;
trp = DIV_ROUND_UP(ddr3_cfg->trcd, clkper / 10) - 1;
twtr = ROUND(max(4 * clkper, 7500) / clkper, 1) - 1;
trcd = trp;
trtp = twtr;
cs0_end = 4 * sysinfo->cs_density - 1;
debug("density:%d Gb (%d Gb per chip)\n",
sysinfo->cs_density, ddr3_cfg->density);
debug("clock: %dMHz (%d ps)\n", clock, clkper);
debug("memspd:%d\n", mem_speed);
debug("tcke=%d\n", tcke);
debug("tcksrx=%d\n", tcksrx);
debug("tcksre=%d\n", tcksre);
debug("taofpd=%d\n", taofpd);
debug("taonpd=%d\n", taonpd);
debug("todtlon=%d\n", todtlon);
debug("tanpd=%d\n", tanpd);
debug("taxpd=%d\n", taxpd);
debug("trfc=%d\n", trfc);
debug("txs=%d\n", txs);
debug("txp=%d\n", txp);
debug("txpdll=%d\n", txpdll);
debug("tfaw=%d\n", tfaw);
debug("tcl=%d\n", tcl);
debug("trcd=%d\n", trcd);
debug("trp=%d\n", trp);
debug("trc=%d\n", trc);
debug("tras=%d\n", tras);
debug("twr=%d\n", twr);
debug("tmrd=%d\n", tmrd);
debug("tcwl=%d\n", tcwl);
debug("tdllk=%d\n", tdllk);
debug("trtp=%d\n", trtp);
debug("twtr=%d\n", twtr);
debug("trrd=%d\n", trrd);
debug("txpr=%d\n", txpr);
debug("cs0_end=%d\n", cs0_end);
debug("ncs=%d\n", sysinfo->ncs);
debug("Rtt_wr=%d\n", sysinfo->rtt_wr);
debug("Rtt_nom=%d\n", sysinfo->rtt_nom);
debug("SRT=%d\n", ddr3_cfg->SRT);
debug("tcl=%d\n", tcl);
debug("twr=%d\n", twr);
/*
* board-specific configuration:
* These values are determined empirically and vary per board layout
* see:
* appnote, ddr3 spreadsheet
*/
mmdc0->mpwldectrl0 = calib->p0_mpwldectrl0;
mmdc0->mpwldectrl1 = calib->p0_mpwldectrl1;
mmdc0->mpdgctrl0 = calib->p0_mpdgctrl0;
mmdc0->mpdgctrl1 = calib->p0_mpdgctrl1;
mmdc0->mprddlctl = calib->p0_mprddlctl;
mmdc0->mpwrdlctl = calib->p0_mpwrdlctl;
if (sysinfo->dsize > 1) {
MMDC1(mpwldectrl0, calib->p1_mpwldectrl0);
MMDC1(mpwldectrl1, calib->p1_mpwldectrl1);
MMDC1(mpdgctrl0, calib->p1_mpdgctrl0);
MMDC1(mpdgctrl1, calib->p1_mpdgctrl1);
MMDC1(mprddlctl, calib->p1_mprddlctl);
MMDC1(mpwrdlctl, calib->p1_mpwrdlctl);
}
/* Read data DQ Byte0-3 delay */
mmdc0->mprddqby0dl = 0x33333333;
mmdc0->mprddqby1dl = 0x33333333;
if (sysinfo->dsize > 0) {
mmdc0->mprddqby2dl = 0x33333333;
mmdc0->mprddqby3dl = 0x33333333;
}
if (sysinfo->dsize > 1) {
MMDC1(mprddqby0dl, 0x33333333);
MMDC1(mprddqby1dl, 0x33333333);
MMDC1(mprddqby2dl, 0x33333333);
MMDC1(mprddqby3dl, 0x33333333);
}
/* MMDC Termination: rtt_nom:2 RZQ/2(120ohm), rtt_nom:1 RZQ/4(60ohm) */
val = (sysinfo->rtt_nom == 2) ? 0x00011117 : 0x00022227;
mmdc0->mpodtctrl = val;
if (sysinfo->dsize > 1)
MMDC1(mpodtctrl, val);
/* complete calibration */
val = (1 << 11); /* Force measurement on delay-lines */
mmdc0->mpmur0 = val;
if (sysinfo->dsize > 1)
MMDC1(mpmur0, val);
/* Step 1: configuration request */
mmdc0->mdscr = (u32)(1 << 15); /* config request */
/* Step 2: Timing configuration */
mmdc0->mdcfg0 = (trfc << 24) | (txs << 16) | (txp << 13) |
(txpdll << 9) | (tfaw << 4) | tcl;
mmdc0->mdcfg1 = (trcd << 29) | (trp << 26) | (trc << 21) |
(tras << 16) | (1 << 15) /* trpa */ |
(twr << 9) | (tmrd << 5) | tcwl;
mmdc0->mdcfg2 = (tdllk << 16) | (trtp << 6) | (twtr << 3) | trrd;
mmdc0->mdotc = (taofpd << 27) | (taonpd << 24) | (tanpd << 20) |
(taxpd << 16) | (todtlon << 12) | (todt_idle_off << 4);
mmdc0->mdasp = cs0_end; /* CS addressing */
/* Step 3: Configure DDR type */
mmdc0->mdmisc = (sysinfo->cs1_mirror << 19) | (sysinfo->walat << 16) |
(sysinfo->bi_on << 12) | (sysinfo->mif3_mode << 9) |
(sysinfo->ralat << 6);
/* Step 4: Configure delay while leaving reset */
mmdc0->mdor = (txpr << 16) | (sysinfo->sde_to_rst << 8) |
(sysinfo->rst_to_cke << 0);
/* Step 5: Configure DDR physical parameters (density and burst len) */
coladdr = ddr3_cfg->coladdr;
if (ddr3_cfg->coladdr == 8) /* 8-bit COL is 0x3 */
coladdr += 4;
else if (ddr3_cfg->coladdr == 12) /* 12-bit COL is 0x4 */
coladdr += 1;
mmdc0->mdctl = (ddr3_cfg->rowaddr - 11) << 24 | /* ROW */
(coladdr - 9) << 20 | /* COL */
(1 << 19) | /* Burst Length = 8 for DDR3 */
(sysinfo->dsize << 16); /* DDR data bus size */
/* Step 6: Perform ZQ calibration */
val = 0xa1390001; /* one-time HW ZQ calib */
mmdc0->mpzqhwctrl = val;
if (sysinfo->dsize > 1)
MMDC1(mpzqhwctrl, val);
/* Step 7: Enable MMDC with desired chip select */
mmdc0->mdctl |= (1 << 31) | /* SDE_0 for CS0 */
((sysinfo->ncs == 2) ? 1 : 0) << 30; /* SDE_1 for CS1 */
/* Step 8: Write Mode Registers to Init DDR3 devices */
for (cs = 0; cs < sysinfo->ncs; cs++) {
/* MR2 */
val = (sysinfo->rtt_wr & 3) << 9 | (ddr3_cfg->SRT & 1) << 7 |
((tcwl - 3) & 3) << 3;
debug("MR2 CS%d: 0x%08x\n", cs, (u32)MR(val, 2, 3, cs));
mmdc0->mdscr = MR(val, 2, 3, cs);
/* MR3 */
debug("MR3 CS%d: 0x%08x\n", cs, (u32)MR(0, 3, 3, cs));
mmdc0->mdscr = MR(0, 3, 3, cs);
/* MR1 */
val = ((sysinfo->rtt_nom & 1) ? 1 : 0) << 2 |
((sysinfo->rtt_nom & 2) ? 1 : 0) << 6;
debug("MR1 CS%d: 0x%08x\n", cs, (u32)MR(val, 1, 3, cs));
mmdc0->mdscr = MR(val, 1, 3, cs);
/* MR0 */
val = ((tcl - 1) << 4) | /* CAS */
(1 << 8) | /* DLL Reset */
((twr - 3) << 9) | /* Write Recovery */
(sysinfo->pd_fast_exit << 12); /* Precharge PD PLL on */
debug("MR0 CS%d: 0x%08x\n", cs, (u32)MR(val, 0, 3, cs));
mmdc0->mdscr = MR(val, 0, 3, cs);
/* ZQ calibration */
val = (1 << 10);
mmdc0->mdscr = MR(val, 0, 4, cs);
}
/* Step 10: Power down control and self-refresh */
mmdc0->mdpdc = (tcke & 0x7) << 16 |
5 << 12 | /* PWDT_1: 256 cycles */
5 << 8 | /* PWDT_0: 256 cycles */
1 << 6 | /* BOTH_CS_PD */
(tcksrx & 0x7) << 3 |
(tcksre & 0x7);
if (!sysinfo->pd_fast_exit)
mmdc0->mdpdc |= (1 << 7); /* SLOW_PD */
mmdc0->mapsr = 0x00001006; /* ADOPT power down enabled */
/* Step 11: Configure ZQ calibration: one-time and periodic 1ms */
val = 0xa1390003;
mmdc0->mpzqhwctrl = val;
if (sysinfo->dsize > 1)
MMDC1(mpzqhwctrl, val);
/* Step 12: Configure and activate periodic refresh */
mmdc0->mdref = (1 << 14) | /* REF_SEL: Periodic refresh cycle: 32kHz */
(7 << 11); /* REFR: Refresh Rate - 8 refreshes */
/* Step 13: Deassert config request - init complete */
mmdc0->mdscr = 0x00000000;
/* wait for auto-ZQ calibration to complete */
mdelay(1);
}