blob: 9a25bba5997c618b87321bc3e6f4542318676b2c [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2015-2017 Socionext Inc.
* Author: Masahiro Yamada <yamada.masahiro@socionext.com>
*/
#include <common.h>
#include <stdio.h>
#include <linux/io.h>
#include <linux/printk.h>
#include <linux/sizes.h>
#include "../soc-info.h"
#include "ddrmphy-regs.h"
/* Select either decimal or hexadecimal */
#if 1
#define PRINTF_FORMAT "%2d"
#else
#define PRINTF_FORMAT "%02x"
#endif
/* field separator */
#define FS " "
#define ptr_to_uint(p) ((unsigned int)(unsigned long)(p))
#define UNIPHIER_MAX_NR_DDRMPHY 3
struct uniphier_ddrmphy_param {
unsigned int soc_id;
unsigned int nr_phy;
struct {
resource_size_t base;
unsigned int nr_zq;
unsigned int nr_dx;
} phy[UNIPHIER_MAX_NR_DDRMPHY];
};
static const struct uniphier_ddrmphy_param uniphier_ddrmphy_param[] = {
{
.soc_id = UNIPHIER_PXS2_ID,
.nr_phy = 3,
.phy = {
{ .base = 0x5b830000, .nr_zq = 3, .nr_dx = 4, },
{ .base = 0x5ba30000, .nr_zq = 3, .nr_dx = 4, },
{ .base = 0x5bc30000, .nr_zq = 2, .nr_dx = 2, },
},
},
{
.soc_id = UNIPHIER_LD6B_ID,
.nr_phy = 3,
.phy = {
{ .base = 0x5b830000, .nr_zq = 3, .nr_dx = 4, },
{ .base = 0x5ba30000, .nr_zq = 3, .nr_dx = 4, },
{ .base = 0x5bc30000, .nr_zq = 2, .nr_dx = 2, },
},
},
};
UNIPHIER_DEFINE_SOCDATA_FUNC(uniphier_get_ddrmphy_param, uniphier_ddrmphy_param)
static void print_bdl(void __iomem *reg, int n)
{
u32 val = readl(reg);
int i;
for (i = 0; i < n; i++)
printf(FS PRINTF_FORMAT, (val >> i * 8) & 0x1f);
}
static void dump_loop(const struct uniphier_ddrmphy_param *param,
void (*callback)(void __iomem *))
{
void __iomem *phy_base, *dx_base;
int phy, dx;
for (phy = 0; phy < param->nr_phy; phy++) {
phy_base = ioremap(param->phy[phy].base, SZ_4K);
dx_base = phy_base + MPHY_DX_BASE;
for (dx = 0; dx < param->phy[phy].nr_dx; dx++) {
printf("PHY%dDX%d:", phy, dx);
(*callback)(dx_base);
dx_base += MPHY_DX_STRIDE;
printf("\n");
}
iounmap(phy_base);
}
}
static void zq_dump(const struct uniphier_ddrmphy_param *param)
{
void __iomem *phy_base, *zq_base;
u32 val;
int phy, zq, i;
printf("\n--- Impedance Data ---\n");
printf(" ZPD ZPU OPD OPU ZDV ODV\n");
for (phy = 0; phy < param->nr_phy; phy++) {
phy_base = ioremap(param->phy[phy].base, SZ_4K);
zq_base = phy_base + MPHY_ZQ_BASE;
for (zq = 0; zq < param->phy[phy].nr_zq; zq++) {
printf("PHY%dZQ%d:", phy, zq);
val = readl(zq_base + MPHY_ZQ_DR);
for (i = 0; i < 4; i++) {
printf(FS PRINTF_FORMAT, val & 0x7f);
val >>= 7;
}
val = readl(zq_base + MPHY_ZQ_PR);
for (i = 0; i < 2; i++) {
printf(FS PRINTF_FORMAT, val & 0xf);
val >>= 4;
}
zq_base += MPHY_ZQ_STRIDE;
printf("\n");
}
iounmap(phy_base);
}
}
static void __wbdl_dump(void __iomem *dx_base)
{
print_bdl(dx_base + MPHY_DX_BDLR0, 4);
print_bdl(dx_base + MPHY_DX_BDLR1, 4);
print_bdl(dx_base + MPHY_DX_BDLR2, 2);
printf(FS "(+" PRINTF_FORMAT ")",
readl(dx_base + MPHY_DX_LCDLR1) & 0xff);
}
static void wbdl_dump(const struct uniphier_ddrmphy_param *param)
{
printf("\n--- Write Bit Delay Line ---\n");
printf(" DQ0 DQ1 DQ2 DQ3 DQ4 DQ5 DQ6 DQ7 DM DQS (WDQD)\n");
dump_loop(param, &__wbdl_dump);
}
static void __rbdl_dump(void __iomem *dx_base)
{
print_bdl(dx_base + MPHY_DX_BDLR3, 4);
print_bdl(dx_base + MPHY_DX_BDLR4, 4);
print_bdl(dx_base + MPHY_DX_BDLR5, 1);
printf(FS "(+" PRINTF_FORMAT ")",
(readl(dx_base + MPHY_DX_LCDLR1) >> 8) & 0xff);
printf(FS "(+" PRINTF_FORMAT ")",
(readl(dx_base + MPHY_DX_LCDLR1) >> 16) & 0xff);
}
static void rbdl_dump(const struct uniphier_ddrmphy_param *param)
{
printf("\n--- Read Bit Delay Line ---\n");
printf(" DQ0 DQ1 DQ2 DQ3 DQ4 DQ5 DQ6 DQ7 DM (RDQSD) (RDQSND)\n");
dump_loop(param, &__rbdl_dump);
}
static void __wld_dump(void __iomem *dx_base)
{
int rank;
u32 lcdlr0 = readl(dx_base + MPHY_DX_LCDLR0);
u32 gtr = readl(dx_base + MPHY_DX_GTR);
for (rank = 0; rank < 4; rank++) {
u32 wld = (lcdlr0 >> (8 * rank)) & 0xff; /* Delay */
u32 wlsl = (gtr >> (12 + 2 * rank)) & 0x3; /* System Latency */
printf(FS PRINTF_FORMAT "%sT", wld,
wlsl == 0 ? "-1" : wlsl == 1 ? "+0" : "+1");
}
}
static void wld_dump(const struct uniphier_ddrmphy_param *param)
{
printf("\n--- Write Leveling Delay ---\n");
printf(" Rank0 Rank1 Rank2 Rank3\n");
dump_loop(param, &__wld_dump);
}
static void __dqsgd_dump(void __iomem *dx_base)
{
int rank;
u32 lcdlr2 = readl(dx_base + MPHY_DX_LCDLR2);
u32 gtr = readl(dx_base + MPHY_DX_GTR);
for (rank = 0; rank < 4; rank++) {
u32 dqsgd = (lcdlr2 >> (8 * rank)) & 0xff; /* Delay */
u32 dgsl = (gtr >> (3 * rank)) & 0x7; /* System Latency */
printf(FS PRINTF_FORMAT "+%dT", dqsgd, dgsl);
}
}
static void dqsgd_dump(const struct uniphier_ddrmphy_param *param)
{
printf("\n--- DQS Gating Delay ---\n");
printf(" Rank0 Rank1 Rank2 Rank3\n");
dump_loop(param, &__dqsgd_dump);
}
static void __mdl_dump(void __iomem *dx_base)
{
int i;
u32 mdl = readl(dx_base + MPHY_DX_MDLR);
for (i = 0; i < 3; i++)
printf(FS PRINTF_FORMAT, (mdl >> (8 * i)) & 0xff);
}
static void mdl_dump(const struct uniphier_ddrmphy_param *param)
{
printf("\n--- Master Delay Line ---\n");
printf(" IPRD TPRD MDLD\n");
dump_loop(param, &__mdl_dump);
}
#define REG_DUMP(x) \
{ int ofst = MPHY_ ## x; void __iomem *reg = phy_base + ofst; \
printf("%3d: %-10s: %p : %08x\n", \
ofst >> MPHY_SHIFT, #x, reg, readl(reg)); }
#define DX_REG_DUMP(dx, x) \
{ int ofst = MPHY_DX_BASE + MPHY_DX_STRIDE * (dx) + \
MPHY_DX_## x; \
void __iomem *reg = phy_base + ofst; \
printf("%3d: DX%d%-7s: %p : %08x\n", \
ofst >> MPHY_SHIFT, (dx), #x, reg, readl(reg)); }
static void reg_dump(const struct uniphier_ddrmphy_param *param)
{
void __iomem *phy_base;
int phy, dx;
printf("\n--- DDR Multi PHY registers ---\n");
for (phy = 0; phy < param->nr_phy; phy++) {
phy_base = ioremap(param->phy[phy].base, SZ_4K);
printf("== PHY%d (base: %08x) ==\n", phy,
ptr_to_uint(phy_base));
printf(" No: Name : Address : Data\n");
REG_DUMP(RIDR);
REG_DUMP(PIR);
REG_DUMP(PGCR0);
REG_DUMP(PGCR1);
REG_DUMP(PGCR2);
REG_DUMP(PGCR3);
REG_DUMP(PGSR0);
REG_DUMP(PGSR1);
REG_DUMP(PLLCR);
REG_DUMP(PTR0);
REG_DUMP(PTR1);
REG_DUMP(PTR2);
REG_DUMP(PTR3);
REG_DUMP(PTR4);
REG_DUMP(ACMDLR);
REG_DUMP(ACBDLR0);
REG_DUMP(DXCCR);
REG_DUMP(DSGCR);
REG_DUMP(DCR);
REG_DUMP(DTPR0);
REG_DUMP(DTPR1);
REG_DUMP(DTPR2);
REG_DUMP(DTPR3);
REG_DUMP(MR0);
REG_DUMP(MR1);
REG_DUMP(MR2);
REG_DUMP(MR3);
for (dx = 0; dx < param->phy[phy].nr_dx; dx++) {
DX_REG_DUMP(dx, GCR0);
DX_REG_DUMP(dx, GCR1);
DX_REG_DUMP(dx, GCR2);
DX_REG_DUMP(dx, GCR3);
DX_REG_DUMP(dx, GTR);
}
iounmap(phy_base);
}
}
static int do_ddrm(cmd_tbl_t *cmdtp, int flag, int argc, char * const argv[])
{
const struct uniphier_ddrmphy_param *param;
char *cmd;
param = uniphier_get_ddrmphy_param();
if (!param) {
pr_err("unsupported SoC\n");
return CMD_RET_FAILURE;
}
if (argc == 1)
cmd = "all";
else
cmd = argv[1];
if (!strcmp(cmd, "zq") || !strcmp(cmd, "all"))
zq_dump(param);
if (!strcmp(cmd, "wbdl") || !strcmp(cmd, "all"))
wbdl_dump(param);
if (!strcmp(cmd, "rbdl") || !strcmp(cmd, "all"))
rbdl_dump(param);
if (!strcmp(cmd, "wld") || !strcmp(cmd, "all"))
wld_dump(param);
if (!strcmp(cmd, "dqsgd") || !strcmp(cmd, "all"))
dqsgd_dump(param);
if (!strcmp(cmd, "mdl") || !strcmp(cmd, "all"))
mdl_dump(param);
if (!strcmp(cmd, "reg") || !strcmp(cmd, "all"))
reg_dump(param);
return CMD_RET_SUCCESS;
}
U_BOOT_CMD(
ddrm, 2, 1, do_ddrm,
"UniPhier DDR Multi PHY parameters dumper",
"- dump all of the following\n"
"ddrm zq - dump Impedance Data\n"
"ddrm wbdl - dump Write Bit Delay\n"
"ddrm rbdl - dump Read Bit Delay\n"
"ddrm wld - dump Write Leveling\n"
"ddrm dqsgd - dump DQS Gating Delay\n"
"ddrm mdl - dump Master Delay Line\n"
"ddrm reg - dump registers\n"
);