u-boot/arch/arm/mach-uniphier/dram/cmd_ddrphy.c
Masahiro Yamada e27d6c7d32 ARM: uniphier: simplify SoC ID get function
Currently, uniphier_get_soc_type() converts the SoC ID (this is
read from the revision register) to an enum symbol to use it for SoC
identification.  Come to think of it, there is no need for the
conversion in the first place.  Using the SoC ID from the register
as-is a straightforward way.

Signed-off-by: Masahiro Yamada <yamada.masahiro@socionext.com>
2017-01-22 16:49:27 +09:00

300 lines
6.9 KiB
C

/*
* Copyright (C) 2014 Panasonic Corporation
* Copyright (C) 2015-2016 Socionext Inc.
* Author: Masahiro Yamada <yamada.masahiro@socionext.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <linux/io.h>
#include <linux/sizes.h>
#include "../soc-info.h"
#include "ddrphy-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))
struct phy_param {
resource_size_t base;
unsigned int nr_dx;
};
static const struct phy_param uniphier_ld4_phy_param[] = {
{ .base = 0x5bc01000, .nr_dx = 2, },
{ .base = 0x5be01000, .nr_dx = 2, },
{ /* sentinel */ }
};
static const struct phy_param uniphier_pro4_phy_param[] = {
{ .base = 0x5bc01000, .nr_dx = 2, },
{ .base = 0x5bc02000, .nr_dx = 2, },
{ .base = 0x5be01000, .nr_dx = 2, },
{ .base = 0x5be02000, .nr_dx = 2, },
{ /* sentinel */ }
};
static const struct phy_param uniphier_sld8_phy_param[] = {
{ .base = 0x5bc01000, .nr_dx = 2, },
{ .base = 0x5be01000, .nr_dx = 2, },
{ /* sentinel */ }
};
static const struct phy_param uniphier_ld11_phy_param[] = {
{ .base = 0x5bc01000, .nr_dx = 4, },
{ /* sentinel */ }
};
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 * 6) & 0x3f);
}
static void dump_loop(const struct phy_param *phy_param,
void (*callback)(void __iomem *))
{
void __iomem *phy_base, *dx_base;
int p, dx;
for (p = 0; phy_param->base; phy_param++, p++) {
phy_base = ioremap(phy_param->base, SZ_4K);
dx_base = phy_base + PHY_DX_BASE;
for (dx = 0; dx < phy_param->nr_dx; dx++) {
printf("PHY%dDX%d:", p, dx);
(*callback)(dx_base);
dx_base += PHY_DX_STRIDE;
printf("\n");
}
iounmap(phy_base);
}
}
static void __wbdl_dump(void __iomem *dx_base)
{
print_bdl(dx_base + PHY_DX_BDLR0, 5);
print_bdl(dx_base + PHY_DX_BDLR1, 5);
printf(FS "(+" PRINTF_FORMAT ")",
readl(dx_base + PHY_DX_LCDLR1) & 0xff);
}
static void wbdl_dump(const struct phy_param *phy_param)
{
printf("\n--- Write Bit Delay Line ---\n");
printf(" DQ0 DQ1 DQ2 DQ3 DQ4 DQ5 DQ6 DQ7 DM DQS (WDQD)\n");
dump_loop(phy_param, &__wbdl_dump);
}
static void __rbdl_dump(void __iomem *dx_base)
{
print_bdl(dx_base + PHY_DX_BDLR3, 5);
print_bdl(dx_base + PHY_DX_BDLR4, 4);
printf(FS "(+" PRINTF_FORMAT ")",
(readl(dx_base + PHY_DX_LCDLR1) >> 8) & 0xff);
}
static void rbdl_dump(const struct phy_param *phy_param)
{
printf("\n--- Read Bit Delay Line ---\n");
printf(" DQ0 DQ1 DQ2 DQ3 DQ4 DQ5 DQ6 DQ7 DM (RDQSD)\n");
dump_loop(phy_param, &__rbdl_dump);
}
static void __wld_dump(void __iomem *dx_base)
{
int rank;
u32 lcdlr0 = readl(dx_base + PHY_DX_LCDLR0);
u32 gtr = readl(dx_base + PHY_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 phy_param *phy_param)
{
printf("\n--- Write Leveling Delay ---\n");
printf(" Rank0 Rank1 Rank2 Rank3\n");
dump_loop(phy_param, &__wld_dump);
}
static void __dqsgd_dump(void __iomem *dx_base)
{
int rank;
u32 lcdlr2 = readl(dx_base + PHY_DX_LCDLR2);
u32 gtr = readl(dx_base + PHY_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 phy_param *phy_param)
{
printf("\n--- DQS Gating Delay ---\n");
printf(" Rank0 Rank1 Rank2 Rank3\n");
dump_loop(phy_param, &__dqsgd_dump);
}
static void __mdl_dump(void __iomem *dx_base)
{
int i;
u32 mdl = readl(dx_base + PHY_DX_MDLR);
for (i = 0; i < 3; i++)
printf(FS PRINTF_FORMAT, (mdl >> (8 * i)) & 0xff);
}
static void mdl_dump(const struct phy_param *phy_param)
{
printf("\n--- Master Delay Line ---\n");
printf(" IPRD TPRD MDLD\n");
dump_loop(phy_param, &__mdl_dump);
}
#define REG_DUMP(x) \
{ int ofst = PHY_ ## x; void __iomem *reg = phy_base + ofst; \
printf("%3d: %-10s: %08x : %08x\n", \
ofst >> PHY_REG_SHIFT, #x, \
ptr_to_uint(reg), readl(reg)); }
#define DX_REG_DUMP(dx, x) \
{ int ofst = PHY_DX_BASE + PHY_DX_STRIDE * (dx) + \
PHY_DX_## x; \
void __iomem *reg = phy_base + ofst; \
printf("%3d: DX%d%-7s: %08x : %08x\n", \
ofst >> PHY_REG_SHIFT, (dx), #x, \
ptr_to_uint(reg), readl(reg)); }
static void reg_dump(const struct phy_param *phy_param)
{
void __iomem *phy_base;
int p, dx;
printf("\n--- DDR PHY registers ---\n");
for (p = 0; phy_param->base; phy_param++, p++) {
phy_base = ioremap(phy_param->base, SZ_4K);
printf("== PHY%d (base: %08x) ==\n", p, 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(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(ACBDLR);
REG_DUMP(DXCCR);
REG_DUMP(DSGCR);
REG_DUMP(DCR);
REG_DUMP(DTPR0);
REG_DUMP(DTPR1);
REG_DUMP(DTPR2);
REG_DUMP(MR0);
REG_DUMP(MR1);
REG_DUMP(MR2);
REG_DUMP(MR3);
for (dx = 0; dx < phy_param->nr_dx; dx++) {
DX_REG_DUMP(dx, GCR);
DX_REG_DUMP(dx, GTR);
}
iounmap(phy_base);
}
}
static int do_ddr(cmd_tbl_t *cmdtp, int flag, int argc, char * const argv[])
{
char *cmd = argv[1];
const struct phy_param *phy_param;
switch (uniphier_get_soc_id()) {
case UNIPHIER_LD4_ID:
phy_param = uniphier_ld4_phy_param;
break;
case UNIPHIER_PRO4_ID:
phy_param = uniphier_pro4_phy_param;
break;
case UNIPHIER_SLD8_ID:
phy_param = uniphier_sld8_phy_param;
break;
case UNIPHIER_LD11_ID:
phy_param = uniphier_ld11_phy_param;
break;
default:
printf("unsupported SoC\n");
return CMD_RET_FAILURE;
}
if (argc == 1)
cmd = "all";
if (!strcmp(cmd, "wbdl") || !strcmp(cmd, "all"))
wbdl_dump(phy_param);
if (!strcmp(cmd, "rbdl") || !strcmp(cmd, "all"))
rbdl_dump(phy_param);
if (!strcmp(cmd, "wld") || !strcmp(cmd, "all"))
wld_dump(phy_param);
if (!strcmp(cmd, "dqsgd") || !strcmp(cmd, "all"))
dqsgd_dump(phy_param);
if (!strcmp(cmd, "mdl") || !strcmp(cmd, "all"))
mdl_dump(phy_param);
if (!strcmp(cmd, "reg") || !strcmp(cmd, "all"))
reg_dump(phy_param);
return CMD_RET_SUCCESS;
}
U_BOOT_CMD(
ddr, 2, 1, do_ddr,
"UniPhier DDR PHY parameters dumper",
"- dump all of the following\n"
"ddr wbdl - dump Write Bit Delay\n"
"ddr rbdl - dump Read Bit Delay\n"
"ddr wld - dump Write Leveling\n"
"ddr dqsgd - dump DQS Gating Delay\n"
"ddr mdl - dump Master Delay Line\n"
"ddr reg - dump registers\n"
);