u-boot/arch/mips/mach-mscc/include/mach/ddr.h
Simon Glass cd93d625fd common: Drop linux/bitops.h from common header
Move this uncommon header out of the common header.

Signed-off-by: Simon Glass <sjg@chromium.org>
2020-05-18 21:19:23 -04:00

848 lines
26 KiB
C

/* SPDX-License-Identifier: (GPL-2.0+ OR MIT) */
/*
* Copyright (c) 2018 Microsemi Corporation
*/
#ifndef __ASM_MACH_DDR_H
#define __ASM_MACH_DDR_H
#include <asm/cacheops.h>
#include <asm/io.h>
#include <asm/reboot.h>
#include <linux/bitops.h>
#include <mach/common.h>
#define MIPS_VCOREIII_MEMORY_DDR3
#define MIPS_VCOREIII_DDR_SIZE CONFIG_SYS_SDRAM_SIZE
#if defined(CONFIG_DDRTYPE_H5TQ1G63BFA) /* Serval1 Refboard */
/* Hynix H5TQ1G63BFA (1Gbit DDR3, x16) @ 3.20ns */
#define VC3_MPAR_bank_addr_cnt 3
#define VC3_MPAR_row_addr_cnt 13
#define VC3_MPAR_col_addr_cnt 10
#define VC3_MPAR_tREFI 2437
#define VC3_MPAR_tRAS_min 12
#define VC3_MPAR_CL 6
#define VC3_MPAR_tWTR 4
#define VC3_MPAR_tRC 16
#define VC3_MPAR_tFAW 16
#define VC3_MPAR_tRP 5
#define VC3_MPAR_tRRD 4
#define VC3_MPAR_tRCD 5
#define VC3_MPAR_tMRD 4
#define VC3_MPAR_tRFC 35
#define VC3_MPAR_CWL 5
#define VC3_MPAR_tXPR 38
#define VC3_MPAR_tMOD 12
#define VC3_MPAR_tDLLK 512
#define VC3_MPAR_tWR 5
#elif defined(CONFIG_DDRTYPE_MT41J128M16HA) /* Validation board */
/* Micron MT41J128M16HA-15E:D (2Gbit DDR3, x16) @ 3.20ns */
#define VC3_MPAR_bank_addr_cnt 3
#define VC3_MPAR_row_addr_cnt 14
#define VC3_MPAR_col_addr_cnt 10
#define VC3_MPAR_tREFI 2437
#define VC3_MPAR_tRAS_min 12
#define VC3_MPAR_CL 5
#define VC3_MPAR_tWTR 4
#define VC3_MPAR_tRC 16
#define VC3_MPAR_tFAW 16
#define VC3_MPAR_tRP 5
#define VC3_MPAR_tRRD 4
#define VC3_MPAR_tRCD 5
#define VC3_MPAR_tMRD 4
#define VC3_MPAR_tRFC 50
#define VC3_MPAR_CWL 5
#define VC3_MPAR_tXPR 54
#define VC3_MPAR_tMOD 12
#define VC3_MPAR_tDLLK 512
#define VC3_MPAR_tWR 5
#elif defined(CONFIG_DDRTYPE_MT41K256M16) /* JR2 Validation board */
/* Micron MT41K256M16 (4Gbit, DDR3L-800, 256Mbitx16) @ 3.20ns */
#define VC3_MPAR_bank_addr_cnt 3
#define VC3_MPAR_row_addr_cnt 15
#define VC3_MPAR_col_addr_cnt 10
#define VC3_MPAR_tREFI 2437
#define VC3_MPAR_tRAS_min 12
#define VC3_MPAR_CL 5
#define VC3_MPAR_tWTR 4
#define VC3_MPAR_tRC 16
#define VC3_MPAR_tFAW 16
#define VC3_MPAR_tRP 5
#define VC3_MPAR_tRRD 4
#define VC3_MPAR_tRCD 5
#define VC3_MPAR_tMRD 4
#define VC3_MPAR_tRFC 82
#define VC3_MPAR_CWL 5
#define VC3_MPAR_tXPR 85
#define VC3_MPAR_tMOD 12
#define VC3_MPAR_tDLLK 512
#define VC3_MPAR_tWR 5
#elif defined(CONFIG_DDRTYPE_H5TQ4G63MFR) /* JR2 Reference board */
/* Hynix H5TQ4G63MFR-PBC (4Gbit, DDR3-800, 256Mbitx16) - 2kb pages @ 3.20ns */
#define VC3_MPAR_bank_addr_cnt 3
#define VC3_MPAR_row_addr_cnt 15
#define VC3_MPAR_col_addr_cnt 10
#define VC3_MPAR_tREFI 2437
#define VC3_MPAR_tRAS_min 12
#define VC3_MPAR_CL 6
#define VC3_MPAR_tWTR 4
#define VC3_MPAR_tRC 17
#define VC3_MPAR_tFAW 16
#define VC3_MPAR_tRP 5
#define VC3_MPAR_tRRD 4
#define VC3_MPAR_tRCD 5
#define VC3_MPAR_tMRD 4
#define VC3_MPAR_tRFC 82
#define VC3_MPAR_CWL 5
#define VC3_MPAR_tXPR 85
#define VC3_MPAR_tMOD 12
#define VC3_MPAR_tDLLK 512
#define VC3_MPAR_tWR 5
#elif defined(CONFIG_DDRTYPE_MT41K128M16JT)
/* Micron Micron MT41K128M16JT-125 (2Gbit DDR3L, 128Mbitx16) @ 3.20ns */
#define VC3_MPAR_bank_addr_cnt 3
#define VC3_MPAR_row_addr_cnt 14
#define VC3_MPAR_col_addr_cnt 10
#define VC3_MPAR_tREFI 2437
#define VC3_MPAR_tRAS_min 12
#define VC3_MPAR_CL 6
#define VC3_MPAR_tWTR 4
#define VC3_MPAR_tRC 16
#define VC3_MPAR_tFAW 16
#define VC3_MPAR_tRP 5
#define VC3_MPAR_tRRD 4
#define VC3_MPAR_tRCD 5
#define VC3_MPAR_tMRD 4
#define VC3_MPAR_tRFC 82
#define VC3_MPAR_CWL 5
#define VC3_MPAR_tXPR 85
#define VC3_MPAR_tMOD 12
#define VC3_MPAR_tDLLK 512
#define VC3_MPAR_tWR 5
#elif defined(CONFIG_DDRTYPE_MT47H128M8HQ) /* Luton10/26 Refboards */
/* Micron 1Gb MT47H128M8-3 16Meg x 8 x 8 banks, DDR-533@CL4 @ 4.80ns */
#define VC3_MPAR_bank_addr_cnt 3
#define VC3_MPAR_row_addr_cnt 14
#define VC3_MPAR_col_addr_cnt 10
#define VC3_MPAR_tREFI 1625
#define VC3_MPAR_tRAS_min 9
#define VC3_MPAR_CL 4
#define VC3_MPAR_tWTR 2
#define VC3_MPAR_tRC 12
#define VC3_MPAR_tFAW 8
#define VC3_MPAR_tRP 4
#define VC3_MPAR_tRRD 2
#define VC3_MPAR_tRCD 4
#define VC3_MPAR_tRPA 4
#define VC3_MPAR_tRP 4
#define VC3_MPAR_tMRD 2
#define VC3_MPAR_tRFC 27
#define VC3_MPAR__400_ns_dly 84
#define VC3_MPAR_tWR 4
#undef MIPS_VCOREIII_MEMORY_DDR3
#else
#error Unknown DDR system configuration - please add!
#endif
#if defined(CONFIG_SOC_OCELOT) || defined(CONFIG_SOC_JR2) || \
defined(CONFIG_SOC_SERVALT) || defined(CONFIG_SOC_SERVAL)
#define MIPS_VCOREIII_MEMORY_16BIT 1
#endif
#define MIPS_VCOREIII_MEMORY_SSTL_ODT 7
#define MIPS_VCOREIII_MEMORY_SSTL_DRIVE 7
#define VCOREIII_DDR_DQS_MODE_CALIBRATE
#ifdef MIPS_VCOREIII_MEMORY_16BIT
#define VC3_MPAR_16BIT 1
#else
#define VC3_MPAR_16BIT 0
#endif
#ifdef MIPS_VCOREIII_MEMORY_DDR3
#define VC3_MPAR_DDR3_MODE 1 /* DDR3 */
#define VC3_MPAR_BURST_LENGTH 8 /* Always 8 (1) for DDR3 */
#ifdef MIPS_VCOREIII_MEMORY_16BIT
#define VC3_MPAR_BURST_SIZE 1 /* Always 1 for DDR3/16bit */
#else
#define VC3_MPAR_BURST_SIZE 0
#endif
#else
#define VC3_MPAR_DDR3_MODE 0 /* DDR2 */
#ifdef MIPS_VCOREIII_MEMORY_16BIT
#define VC3_MPAR_BURST_LENGTH 4 /* in DDR2 16-bit mode, use burstlen 4 */
#else
#define VC3_MPAR_BURST_LENGTH 8 /* For 8-bit IF we must run burst-8 */
#endif
#define VC3_MPAR_BURST_SIZE 0 /* Always 0 for DDR2 */
#endif
#define VC3_MPAR_RL VC3_MPAR_CL
#if !defined(MIPS_VCOREIII_MEMORY_DDR3)
#define VC3_MPAR_WL (VC3_MPAR_RL - 1)
#define VC3_MPAR_MD VC3_MPAR_tMRD
#define VC3_MPAR_ID VC3_MPAR__400_ns_dly
#define VC3_MPAR_SD VC3_MPAR_tXSRD
#define VC3_MPAR_OW (VC3_MPAR_WL - 2)
#define VC3_MPAR_OR (VC3_MPAR_WL - 3)
#define VC3_MPAR_RP (VC3_MPAR_bank_addr_cnt < 3 ? VC3_MPAR_tRP : VC3_MPAR_tRPA)
#define VC3_MPAR_FAW (VC3_MPAR_bank_addr_cnt < 3 ? 1 : VC3_MPAR_tFAW)
#define VC3_MPAR_BL (VC3_MPAR_BURST_LENGTH == 4 ? 2 : 4)
#define MSCC_MEMPARM_MR0 \
(VC3_MPAR_BURST_LENGTH == 8 ? 3 : 2) | (VC3_MPAR_CL << 4) | \
((VC3_MPAR_tWR - 1) << 9)
/* DLL-on, Full-OD, AL=0, RTT=off, nDQS-on, RDQS-off, out-en */
#define MSCC_MEMPARM_MR1 0x382
#define MSCC_MEMPARM_MR2 0
#define MSCC_MEMPARM_MR3 0
#else
#define VC3_MPAR_WL VC3_MPAR_CWL
#define VC3_MPAR_MD VC3_MPAR_tMOD
#define VC3_MPAR_ID VC3_MPAR_tXPR
#define VC3_MPAR_SD VC3_MPAR_tDLLK
#define VC3_MPAR_OW 2
#define VC3_MPAR_OR 2
#define VC3_MPAR_RP VC3_MPAR_tRP
#define VC3_MPAR_FAW VC3_MPAR_tFAW
#define VC3_MPAR_BL 4
#define MSCC_MEMPARM_MR0 ((VC3_MPAR_RL - 4) << 4) | ((VC3_MPAR_tWR - 4) << 9)
/* ODT_RTT: “0x0040” for 120ohm, and “0x0004” for 60ohm. */
#define MSCC_MEMPARM_MR1 0x0040
#define MSCC_MEMPARM_MR2 ((VC3_MPAR_WL - 5) << 3)
#define MSCC_MEMPARM_MR3 0
#endif /* MIPS_VCOREIII_MEMORY_DDR3 */
#define MSCC_MEMPARM_MEMCFG \
((MIPS_VCOREIII_DDR_SIZE > SZ_512M) ? \
ICPU_MEMCTRL_CFG_DDR_512MBYTE_PLUS : 0) | \
(VC3_MPAR_16BIT ? ICPU_MEMCTRL_CFG_DDR_WIDTH : 0) | \
(VC3_MPAR_DDR3_MODE ? ICPU_MEMCTRL_CFG_DDR_MODE : 0) | \
(VC3_MPAR_BURST_SIZE ? ICPU_MEMCTRL_CFG_BURST_SIZE : 0) | \
(VC3_MPAR_BURST_LENGTH == 8 ? ICPU_MEMCTRL_CFG_BURST_LEN : 0) | \
(VC3_MPAR_bank_addr_cnt == 3 ? ICPU_MEMCTRL_CFG_BANK_CNT : 0) | \
ICPU_MEMCTRL_CFG_MSB_ROW_ADDR(VC3_MPAR_row_addr_cnt - 1) | \
ICPU_MEMCTRL_CFG_MSB_COL_ADDR(VC3_MPAR_col_addr_cnt - 1)
#if defined(CONFIG_SOC_OCELOT) || defined(CONFIG_SOC_JR2) || \
defined(CONFIG_SOC_SERVALT) || defined(CONFIG_SOC_SERVAL)
#define MSCC_MEMPARM_PERIOD \
ICPU_MEMCTRL_REF_PERIOD_MAX_PEND_REF(8) | \
ICPU_MEMCTRL_REF_PERIOD_REF_PERIOD(VC3_MPAR_tREFI)
#define MSCC_MEMPARM_TIMING0 \
ICPU_MEMCTRL_TIMING0_RD_TO_WR_DLY(VC3_MPAR_RL + VC3_MPAR_BL + 1 - \
VC3_MPAR_WL) | \
ICPU_MEMCTRL_TIMING0_WR_CS_CHANGE_DLY(VC3_MPAR_BL - 1) | \
ICPU_MEMCTRL_TIMING0_RD_CS_CHANGE_DLY(VC3_MPAR_BL) | \
ICPU_MEMCTRL_TIMING0_RAS_TO_PRECH_DLY(VC3_MPAR_tRAS_min - 1) | \
ICPU_MEMCTRL_TIMING0_WR_TO_PRECH_DLY(VC3_MPAR_WL + \
VC3_MPAR_BL + \
VC3_MPAR_tWR - 1) | \
ICPU_MEMCTRL_TIMING0_RD_TO_PRECH_DLY(VC3_MPAR_BL - 1) | \
ICPU_MEMCTRL_TIMING0_WR_DATA_XFR_DLY(VC3_MPAR_WL - 1) | \
ICPU_MEMCTRL_TIMING0_RD_DATA_XFR_DLY(VC3_MPAR_RL - 3)
#define MSCC_MEMPARM_TIMING1 \
ICPU_MEMCTRL_TIMING1_RAS_TO_RAS_SAME_BANK_DLY(VC3_MPAR_tRC - 1) | \
ICPU_MEMCTRL_TIMING1_BANK8_FAW_DLY(VC3_MPAR_FAW - 1) | \
ICPU_MEMCTRL_TIMING1_PRECH_TO_RAS_DLY(VC3_MPAR_RP - 1) | \
ICPU_MEMCTRL_TIMING1_RAS_TO_RAS_DLY(VC3_MPAR_tRRD - 1) | \
ICPU_MEMCTRL_TIMING1_RAS_TO_CAS_DLY(VC3_MPAR_tRCD - 1) | \
ICPU_MEMCTRL_TIMING1_WR_TO_RD_DLY(VC3_MPAR_WL + \
VC3_MPAR_BL + \
VC3_MPAR_tWTR - 1)
#define MSCC_MEMPARM_TIMING2 \
ICPU_MEMCTRL_TIMING2_PRECH_ALL_DLY(VC3_MPAR_RP - 1) | \
ICPU_MEMCTRL_TIMING2_MDSET_DLY(VC3_MPAR_MD - 1) | \
ICPU_MEMCTRL_TIMING2_REF_DLY(VC3_MPAR_tRFC - 1) | \
ICPU_MEMCTRL_TIMING2_INIT_DLY(VC3_MPAR_ID - 1)
#define MSCC_MEMPARM_TIMING3 \
ICPU_MEMCTRL_TIMING3_WR_TO_RD_CS_CHANGE_DLY(VC3_MPAR_WL + \
VC3_MPAR_tWTR - 1) |\
ICPU_MEMCTRL_TIMING3_ODT_RD_DLY(VC3_MPAR_OR - 1) | \
ICPU_MEMCTRL_TIMING3_ODT_WR_DLY(VC3_MPAR_OW - 1) | \
ICPU_MEMCTRL_TIMING3_LOCAL_ODT_RD_DLY(VC3_MPAR_RL - 3)
#else
#define MSCC_MEMPARM_PERIOD \
ICPU_MEMCTRL_REF_PERIOD_MAX_PEND_REF(1) | \
ICPU_MEMCTRL_REF_PERIOD_REF_PERIOD(VC3_MPAR_tREFI)
#define MSCC_MEMPARM_TIMING0 \
ICPU_MEMCTRL_TIMING0_RAS_TO_PRECH_DLY(VC3_MPAR_tRAS_min - 1) | \
ICPU_MEMCTRL_TIMING0_WR_TO_PRECH_DLY(VC3_MPAR_CL + \
(VC3_MPAR_BURST_LENGTH == 8 ? 2 : 0) + \
VC3_MPAR_tWR) | \
ICPU_MEMCTRL_TIMING0_RD_TO_PRECH_DLY(VC3_MPAR_BURST_LENGTH == 8 ? 3 : 1) | \
ICPU_MEMCTRL_TIMING0_WR_DATA_XFR_DLY(VC3_MPAR_CL - 3) | \
ICPU_MEMCTRL_TIMING0_RD_DATA_XFR_DLY(VC3_MPAR_CL - 3)
#define MSCC_MEMPARM_TIMING1 \
ICPU_MEMCTRL_TIMING1_RAS_TO_RAS_SAME_BANK_DLY(VC3_MPAR_tRC - 1) | \
ICPU_MEMCTRL_TIMING1_BANK8_FAW_DLY(VC3_MPAR_tFAW - 1) | \
ICPU_MEMCTRL_TIMING1_PRECH_TO_RAS_DLY(VC3_MPAR_tRP - 1) | \
ICPU_MEMCTRL_TIMING1_RAS_TO_RAS_DLY(VC3_MPAR_tRRD - 1) | \
ICPU_MEMCTRL_TIMING1_RAS_TO_CAS_DLY(VC3_MPAR_tRCD - 1) | \
ICPU_MEMCTRL_TIMING1_WR_TO_RD_DLY(VC3_MPAR_CL + \
(VC3_MPAR_BURST_LENGTH == 8 ? 2 : 0) + \
VC3_MPAR_tWTR)
#define MSCC_MEMPARM_TIMING2 \
ICPU_MEMCTRL_TIMING2_PRECH_ALL_DLY(VC3_MPAR_tRPA - 1) | \
ICPU_MEMCTRL_TIMING2_MDSET_DLY(VC3_MPAR_tMRD - 1) | \
ICPU_MEMCTRL_TIMING2_REF_DLY(VC3_MPAR_tRFC - 1) | \
ICPU_MEMCTRL_TIMING2_FOUR_HUNDRED_NS_DLY(VC3_MPAR__400_ns_dly)
#define MSCC_MEMPARM_TIMING3 \
ICPU_MEMCTRL_TIMING3_WR_TO_RD_CS_CHANGE_DLY(VC3_MPAR_CL - 1) | \
ICPU_MEMCTRL_TIMING3_ODT_WR_DLY(VC3_MPAR_CL - 1) | \
ICPU_MEMCTRL_TIMING3_LOCAL_ODT_RD_DLY(VC3_MPAR_CL - 1)
#endif
enum {
DDR_TRAIN_OK,
DDR_TRAIN_CONTINUE,
DDR_TRAIN_ERROR,
};
/*
* We actually have very few 'pause' possibilities apart from
* these assembly nops (at this very early stage).
*/
#define PAUSE() asm volatile("nop; nop; nop; nop; nop; nop; nop; nop")
/* NB: Assumes inlining as no stack is available! */
static inline void set_dly(u32 bytelane, u32 dly)
{
register u32 r = readl(BASE_CFG + ICPU_MEMCTRL_DQS_DLY(bytelane));
r &= ~ICPU_MEMCTRL_DQS_DLY_DQS_DLY_M;
r |= ICPU_MEMCTRL_DQS_DLY_DQS_DLY(dly);
writel(r, BASE_CFG + ICPU_MEMCTRL_DQS_DLY(bytelane));
}
static inline bool incr_dly(u32 bytelane)
{
register u32 r = readl(BASE_CFG + ICPU_MEMCTRL_DQS_DLY(bytelane));
if (ICPU_MEMCTRL_DQS_DLY_DQS_DLY(r) < 31) {
writel(r + 1, BASE_CFG + ICPU_MEMCTRL_DQS_DLY(bytelane));
return true;
}
return false;
}
static inline bool adjust_dly(int adjust)
{
register u32 r = readl(BASE_CFG + ICPU_MEMCTRL_DQS_DLY(0));
if (ICPU_MEMCTRL_DQS_DLY_DQS_DLY(r) < 31) {
writel(r + adjust, BASE_CFG + ICPU_MEMCTRL_DQS_DLY(0));
return true;
}
return false;
}
/* NB: Assumes inlining as no stack is available! */
static inline void center_dly(u32 bytelane, u32 start)
{
register u32 r = readl(BASE_CFG + ICPU_MEMCTRL_DQS_DLY(bytelane)) - start;
writel(start + (r >> 1), BASE_CFG + ICPU_MEMCTRL_DQS_DLY(bytelane));
}
static inline void memphy_soft_reset(void)
{
setbits_le32(BASE_CFG + ICPU_MEMPHY_CFG, ICPU_MEMPHY_CFG_PHY_FIFO_RST);
PAUSE();
clrbits_le32(BASE_CFG + ICPU_MEMPHY_CFG, ICPU_MEMPHY_CFG_PHY_FIFO_RST);
PAUSE();
}
#if defined(CONFIG_SOC_OCELOT) || defined(CONFIG_SOC_JR2) || \
defined(CONFIG_SOC_SERVALT) || defined(CONFIG_SOC_SERVAL)
static u8 training_data[] = { 0xfe, 0x11, 0x33, 0x55, 0x77, 0x99, 0xbb, 0xdd };
static inline void sleep_100ns(u32 val)
{
/* Set the timer tick generator to 100 ns */
writel(VCOREIII_TIMER_DIVIDER - 1, BASE_CFG + ICPU_TIMER_TICK_DIV);
/* Set the timer value */
writel(val, BASE_CFG + ICPU_TIMER_VALUE(0));
/* Enable timer 0 for one-shot */
writel(ICPU_TIMER_CTRL_ONE_SHOT_ENA | ICPU_TIMER_CTRL_TIMER_ENA,
BASE_CFG + ICPU_TIMER_CTRL(0));
/* Wait for timer 0 to reach 0 */
while (readl(BASE_CFG + ICPU_TIMER_VALUE(0)) != 0)
;
}
#if defined(CONFIG_SOC_OCELOT) || defined(CONFIG_SOC_SERVAL)
/*
* DDR memory sanity checking failed, tally and do hard reset
*
* NB: Assumes inlining as no stack is available!
*/
static inline void hal_vcoreiii_ddr_failed(void)
{
register u32 reset;
#if defined(CONFIG_SOC_OCELOT)
writel(readl(BASE_CFG + ICPU_GPR(6)) + 1, BASE_CFG + ICPU_GPR(6));
clrbits_le32(BASE_DEVCPU_GCB + PERF_GPIO_OE, BIT(19));
#endif
/* We have to execute the reset function from cache. Indeed,
* the reboot workaround in _machine_restart() will change the
* SPI NOR into SW bitbang.
*
* This will render the CPU unable to execute directly from
* the NOR, which is why the reset instructions are prefetched
* into the I-cache.
*
* When failing the DDR initialization we are executing from
* NOR.
*
* The last instruction in _machine_restart() will reset the
* MIPS CPU (and the cache), and the CPU will start executing
* from the reset vector.
*/
reset = KSEG0ADDR(_machine_restart);
icache_lock((void *)reset, 128);
asm volatile ("jr %0"::"r" (reset));
}
#else /* JR2 || ServalT */
static inline void hal_vcoreiii_ddr_failed(void)
{
writel(0, BASE_CFG + ICPU_RESET);
writel(PERF_SOFT_RST_SOFT_CHIP_RST, BASE_CFG + PERF_SOFT_RST);
}
#endif
#if defined(CONFIG_SOC_OCELOT)
static inline void hal_vcoreiii_ddr_reset_assert(void)
{
/* DDR has reset pin on GPIO 19 toggle Low-High to release */
setbits_le32(BASE_DEVCPU_GCB + PERF_GPIO_OE, BIT(19));
writel(BIT(19), BASE_DEVCPU_GCB + PERF_GPIO_OUT_CLR);
sleep_100ns(10000);
}
static inline void hal_vcoreiii_ddr_reset_release(void)
{
/* DDR has reset pin on GPIO 19 toggle Low-High to release */
setbits_le32(BASE_DEVCPU_GCB + PERF_GPIO_OE, BIT(19));
writel(BIT(19), BASE_DEVCPU_GCB + PERF_GPIO_OUT_SET);
sleep_100ns(10000);
}
#else /* JR2 || ServalT || Serval */
static inline void hal_vcoreiii_ddr_reset_assert(void)
{
/* Ensure the memory controller physical iface is forced reset */
writel(readl(BASE_CFG + ICPU_MEMPHY_CFG) |
ICPU_MEMPHY_CFG_PHY_RST, BASE_CFG + ICPU_MEMPHY_CFG);
/* Ensure the memory controller is forced reset */
writel(readl(BASE_CFG + ICPU_RESET) |
ICPU_RESET_MEM_RST_FORCE, BASE_CFG + ICPU_RESET);
}
#endif /* JR2 || ServalT || Serval */
/*
* DDR memory sanity checking done, possibly enable ECC.
*
* NB: Assumes inlining as no stack is available!
*/
static inline void hal_vcoreiii_ddr_verified(void)
{
#ifdef MIPS_VCOREIII_MEMORY_ECC
/* Finally, enable ECC */
register u32 val = readl(BASE_CFG + ICPU_MEMCTRL_CFG);
val |= ICPU_MEMCTRL_CFG_DDR_ECC_ERR_ENA;
val &= ~ICPU_MEMCTRL_CFG_BURST_SIZE;
writel(val, BASE_CFG + ICPU_MEMCTRL_CFG);
#endif
/* Reset Status register - sticky bits */
writel(readl(BASE_CFG + ICPU_MEMCTRL_STAT), BASE_CFG + ICPU_MEMCTRL_STAT);
}
/* NB: Assumes inlining as no stack is available! */
static inline int look_for(u32 bytelane)
{
register u32 i;
/* Reset FIFO in case any previous access failed */
for (i = 0; i < sizeof(training_data); i++) {
register u32 byte;
memphy_soft_reset();
/* Reset sticky bits */
writel(readl(BASE_CFG + ICPU_MEMCTRL_STAT),
BASE_CFG + ICPU_MEMCTRL_STAT);
/* Read data */
byte = __raw_readb((void __iomem *)MSCC_DDR_TO + bytelane +
(i * 4));
/*
* Prevent the compiler reordering the instruction so
* the read of RAM happens after the check of the
* errors.
*/
rmb();
if (readl(BASE_CFG + ICPU_MEMCTRL_STAT) &
(ICPU_MEMCTRL_STAT_RDATA_MASKED |
ICPU_MEMCTRL_STAT_RDATA_DUMMY)) {
/* Noise on the line */
goto read_error;
}
/* If mismatch, increment DQS - if possible */
if (byte != training_data[i]) {
read_error:
if (!incr_dly(bytelane))
return DDR_TRAIN_ERROR;
return DDR_TRAIN_CONTINUE;
}
}
return DDR_TRAIN_OK;
}
/* NB: Assumes inlining as no stack is available! */
static inline int look_past(u32 bytelane)
{
register u32 i;
/* Reset FIFO in case any previous access failed */
for (i = 0; i < sizeof(training_data); i++) {
register u32 byte;
memphy_soft_reset();
/* Ack sticky bits */
writel(readl(BASE_CFG + ICPU_MEMCTRL_STAT),
BASE_CFG + ICPU_MEMCTRL_STAT);
byte = __raw_readb((void __iomem *)MSCC_DDR_TO + bytelane +
(i * 4));
/*
* Prevent the compiler reordering the instruction so
* the read of RAM happens after the check of the
* errors.
*/
rmb();
if (readl(BASE_CFG + ICPU_MEMCTRL_STAT) &
(ICPU_MEMCTRL_STAT_RDATA_MASKED |
ICPU_MEMCTRL_STAT_RDATA_DUMMY)) {
/* Noise on the line */
goto read_error;
}
/* Bail out when we see first mismatch */
if (byte != training_data[i]) {
read_error:
return DDR_TRAIN_OK;
}
}
/* All data compares OK, increase DQS and retry */
if (!incr_dly(bytelane))
return DDR_TRAIN_ERROR;
return DDR_TRAIN_CONTINUE;
}
static inline int hal_vcoreiii_train_bytelane(u32 bytelane)
{
register int res;
register u32 dqs_s;
set_dly(bytelane, 0); /* Start training at DQS=0 */
while ((res = look_for(bytelane)) == DDR_TRAIN_CONTINUE)
;
if (res != DDR_TRAIN_OK)
return res;
dqs_s = readl(BASE_CFG + ICPU_MEMCTRL_DQS_DLY(bytelane));
while ((res = look_past(bytelane)) == DDR_TRAIN_CONTINUE)
;
if (res != DDR_TRAIN_OK)
return res;
/* Reset FIFO - for good measure */
memphy_soft_reset();
/* Adjust to center [dqs_s;cur] */
center_dly(bytelane, dqs_s);
return DDR_TRAIN_OK;
}
/* This algorithm is converted from the TCL training algorithm used
* during silicon simulation.
* NB: Assumes inlining as no stack is available!
*/
static inline int hal_vcoreiii_init_dqs(void)
{
#define MAX_DQS 32
register u32 i, j;
for (i = 0; i < MAX_DQS; i++) {
set_dly(0, i); /* Byte-lane 0 */
for (j = 0; j < MAX_DQS; j++) {
__maybe_unused register u32 byte;
set_dly(1, j); /* Byte-lane 1 */
/* Reset FIFO in case any previous access failed */
memphy_soft_reset();
writel(readl(BASE_CFG + ICPU_MEMCTRL_STAT),
BASE_CFG + ICPU_MEMCTRL_STAT);
byte = __raw_readb((void __iomem *)MSCC_DDR_TO);
byte = __raw_readb((void __iomem *)(MSCC_DDR_TO + 1));
if (!(readl(BASE_CFG + ICPU_MEMCTRL_STAT) &
(ICPU_MEMCTRL_STAT_RDATA_MASKED |
ICPU_MEMCTRL_STAT_RDATA_DUMMY)))
return 0;
}
}
return -1;
}
static inline int dram_check(void)
{
register u32 i;
for (i = 0; i < 8; i++) {
__raw_writel(~i, (void __iomem *)(MSCC_DDR_TO + (i * 4)));
if (__raw_readl((void __iomem *)(MSCC_DDR_TO + (i * 4))) != ~i)
return 1;
}
return 0;
}
#else /* Luton */
static inline void sleep_100ns(u32 val)
{
}
static inline void hal_vcoreiii_ddr_reset_assert(void)
{
setbits_le32(BASE_CFG + ICPU_MEMPHY_CFG, ICPU_MEMPHY_CFG_PHY_RST);
setbits_le32(BASE_CFG + ICPU_RESET, ICPU_RESET_MEM_RST_FORCE);
}
static inline void hal_vcoreiii_ddr_reset_release(void)
{
}
static inline void hal_vcoreiii_ddr_failed(void)
{
register u32 memphy_cfg = readl(BASE_CFG + ICPU_MEMPHY_CFG);
/* Do a fifo reset and start over */
writel(memphy_cfg | ICPU_MEMPHY_CFG_PHY_FIFO_RST,
BASE_CFG + ICPU_MEMPHY_CFG);
writel(memphy_cfg & ~ICPU_MEMPHY_CFG_PHY_FIFO_RST,
BASE_CFG + ICPU_MEMPHY_CFG);
writel(memphy_cfg | ICPU_MEMPHY_CFG_PHY_FIFO_RST,
BASE_CFG + ICPU_MEMPHY_CFG);
}
static inline void hal_vcoreiii_ddr_verified(void)
{
}
static inline int look_for(u32 data)
{
register u32 byte = __raw_readb((void __iomem *)MSCC_DDR_TO);
if (data != byte) {
if (!incr_dly(0))
return DDR_TRAIN_ERROR;
return DDR_TRAIN_CONTINUE;
}
return DDR_TRAIN_OK;
}
/* This algorithm is converted from the TCL training algorithm used
* during silicon simulation.
* NB: Assumes inlining as no stack is available!
*/
static inline int hal_vcoreiii_train_bytelane(u32 bytelane)
{
register int res;
set_dly(bytelane, 0); /* Start training at DQS=0 */
while ((res = look_for(0xff)) == DDR_TRAIN_CONTINUE)
;
if (res != DDR_TRAIN_OK)
return res;
set_dly(bytelane, 0); /* Start training at DQS=0 */
while ((res = look_for(0x00)) == DDR_TRAIN_CONTINUE)
;
if (res != DDR_TRAIN_OK)
return res;
adjust_dly(-3);
return DDR_TRAIN_OK;
}
static inline int hal_vcoreiii_init_dqs(void)
{
return 0;
}
static inline int dram_check(void)
{
register u32 i;
for (i = 0; i < 8; i++) {
__raw_writel(~i, (void __iomem *)(MSCC_DDR_TO + (i * 4)));
if (__raw_readl((void __iomem *)(MSCC_DDR_TO + (i * 4))) != ~i)
return 1;
}
return 0;
}
#endif
/*
* NB: Called *early* to init memory controller - assumes inlining as
* no stack is available!
*/
static inline void hal_vcoreiii_init_memctl(void)
{
/* Ensure DDR is in reset */
hal_vcoreiii_ddr_reset_assert();
/* Wait maybe not needed, but ... */
PAUSE();
/* Drop sys ctl memory controller forced reset */
clrbits_le32(BASE_CFG + ICPU_RESET, ICPU_RESET_MEM_RST_FORCE);
PAUSE();
/* Drop Reset, enable SSTL */
writel(ICPU_MEMPHY_CFG_PHY_SSTL_ENA, BASE_CFG + ICPU_MEMPHY_CFG);
PAUSE();
/* Start the automatic SSTL output and ODT drive-strength calibration */
writel(ICPU_MEMPHY_ZCAL_ZCAL_PROG_ODT(MIPS_VCOREIII_MEMORY_SSTL_ODT) |
/* drive strength */
ICPU_MEMPHY_ZCAL_ZCAL_PROG(MIPS_VCOREIII_MEMORY_SSTL_DRIVE) |
/* Start calibration process */
ICPU_MEMPHY_ZCAL_ZCAL_ENA, BASE_CFG + ICPU_MEMPHY_ZCAL);
/* Wait for ZCAL to clear */
while (readl(BASE_CFG + ICPU_MEMPHY_ZCAL) & ICPU_MEMPHY_ZCAL_ZCAL_ENA)
;
#if defined(CONFIG_SOC_OCELOT) || defined(CONFIG_SOC_JR2) || \
defined(CONFIG_SOC_SERVALT)
/* Check no ZCAL_ERR */
if (readl(BASE_CFG + ICPU_MEMPHY_ZCAL_STAT)
& ICPU_MEMPHY_ZCAL_STAT_ZCAL_ERR)
hal_vcoreiii_ddr_failed();
#endif
/* Drive CL, CK, ODT */
setbits_le32(BASE_CFG + ICPU_MEMPHY_CFG, ICPU_MEMPHY_CFG_PHY_ODT_OE |
ICPU_MEMPHY_CFG_PHY_CK_OE | ICPU_MEMPHY_CFG_PHY_CL_OE);
/* Initialize memory controller */
writel(MSCC_MEMPARM_MEMCFG, BASE_CFG + ICPU_MEMCTRL_CFG);
writel(MSCC_MEMPARM_PERIOD, BASE_CFG + ICPU_MEMCTRL_REF_PERIOD);
#if defined(CONFIG_SOC_OCELOT) || defined(CONFIG_SOC_JR2) || \
defined(CONFIG_SOC_SERVALT) || defined(CONFIG_SOC_SERVAL)
writel(MSCC_MEMPARM_TIMING0, BASE_CFG + ICPU_MEMCTRL_TIMING0);
#else /* Luton */
clrbits_le32(BASE_CFG + ICPU_MEMCTRL_TIMING0, ((1 << 20) - 1));
setbits_le32(BASE_CFG + ICPU_MEMCTRL_TIMING0, MSCC_MEMPARM_TIMING0);
#endif
writel(MSCC_MEMPARM_TIMING1, BASE_CFG + ICPU_MEMCTRL_TIMING1);
writel(MSCC_MEMPARM_TIMING2, BASE_CFG + ICPU_MEMCTRL_TIMING2);
writel(MSCC_MEMPARM_TIMING3, BASE_CFG + ICPU_MEMCTRL_TIMING3);
writel(MSCC_MEMPARM_MR0, BASE_CFG + ICPU_MEMCTRL_MR0_VAL);
writel(MSCC_MEMPARM_MR1, BASE_CFG + ICPU_MEMCTRL_MR1_VAL);
writel(MSCC_MEMPARM_MR2, BASE_CFG + ICPU_MEMCTRL_MR2_VAL);
writel(MSCC_MEMPARM_MR3, BASE_CFG + ICPU_MEMCTRL_MR3_VAL);
#if defined(CONFIG_SOC_OCELOT) || defined(CONFIG_SOC_SERVAL)
/* Termination setup - enable ODT */
writel(ICPU_MEMCTRL_TERMRES_CTRL_LOCAL_ODT_RD_ENA |
/* Assert ODT0 for any write */
ICPU_MEMCTRL_TERMRES_CTRL_ODT_WR_ENA(3),
BASE_CFG + ICPU_MEMCTRL_TERMRES_CTRL);
/* Release Reset from DDR */
#if defined(CONFIG_SOC_OCELOT)
hal_vcoreiii_ddr_reset_release();
#endif
writel(readl(BASE_CFG + ICPU_GPR(7)) + 1, BASE_CFG + ICPU_GPR(7));
#elif defined(CONFIG_SOC_JR2) || defined(CONFIG_SOC_SERVALT)
writel(ICPU_MEMCTRL_TERMRES_CTRL_ODT_WR_ENA(3),
BASE_CFG + ICPU_MEMCTRL_TERMRES_CTRL);
#else /* Luton */
/* Termination setup - disable ODT */
writel(0, BASE_CFG + ICPU_MEMCTRL_TERMRES_CTRL);
#endif
}
static inline void hal_vcoreiii_wait_memctl(void)
{
/* Now, rip it! */
writel(ICPU_MEMCTRL_CTRL_INITIALIZE, BASE_CFG + ICPU_MEMCTRL_CTRL);
while (!(readl(BASE_CFG + ICPU_MEMCTRL_STAT)
& ICPU_MEMCTRL_STAT_INIT_DONE))
;
/* Settle...? */
sleep_100ns(10000);
#if defined(CONFIG_SOC_OCELOT) || defined(CONFIG_SOC_JR2) || \
defined(CONFIG_SOC_SERVALT) || defined(CONFIG_SOC_SERVAL)
/* Establish data contents in DDR RAM for training */
__raw_writel(0xcacafefe, ((void __iomem *)MSCC_DDR_TO));
__raw_writel(0x22221111, ((void __iomem *)MSCC_DDR_TO + 0x4));
__raw_writel(0x44443333, ((void __iomem *)MSCC_DDR_TO + 0x8));
__raw_writel(0x66665555, ((void __iomem *)MSCC_DDR_TO + 0xC));
__raw_writel(0x88887777, ((void __iomem *)MSCC_DDR_TO + 0x10));
__raw_writel(0xaaaa9999, ((void __iomem *)MSCC_DDR_TO + 0x14));
__raw_writel(0xccccbbbb, ((void __iomem *)MSCC_DDR_TO + 0x18));
__raw_writel(0xeeeedddd, ((void __iomem *)MSCC_DDR_TO + 0x1C));
#else
__raw_writel(0xff, ((void __iomem *)MSCC_DDR_TO));
#endif
}
#endif /* __ASM_MACH_DDR_H */