upstream u-boot with additional patches for our devices/boards: https://lists.denx.de/pipermail/u-boot/2017-March/282789.html (AXP crashes) ; Gbit ethernet patch for some LIME2 revisions ; with SPI flash support
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u-boot/drivers/ddr/marvell/axp/xor.c

436 lines
11 KiB

arm: mvebu: drivers/ddr: Add DDR3 driver with training code from Marvell bin_hdr This patch adds the DDR3 setup and training code taken from the Marvell U-Boot repository. This code used to be included as a binary (bin_hdr) into the AXP boot image. Not linked with the main U-Boot. With this code addition and the following serdes/PHY setup code, the Armada-XP support in mainline U-Boot is finally self-contained. So the complete image for booting can be built from mainline U-Boot. Without any additional external inclusion. Hopefully other MVEBU SoC's will follow here. Support for some SoC's has been removed in this version. This is: MV_MSYS: The code referred to by the MV_MSYS define is currently unused. And its not really planned to support this in mainline. So lets remove it to make the code clearer and increase the readability. MV88F68XX (A38x): The code referred to by the MV88F68XX define (A38x) is currently unused. And its partial and not sufficient for this device in this stage. So lets remove it to make the code clearer and increase the readability. MV88F66XX (ALP): The code referred to by the MV88F66XX define is currently unused. And its not really planned to support this in mainline. So lets remove it to make the code clearer and increase the readability. MV88F78X60_Z1: The code referred to by the MV88F78X60_Z1 define is currently unused. As the Z1 revision of the AXP is not supported in mainline anymore. So lets remove it to make the code clearer and increase the readability. Remove support for Z1 & A0 AXP revisions (steppings). The current stepping is B0 and this is the only one that is actively supported in this code version. Tested on AXP using a SPD DIMM setup on the Marvell DB-MV784MP-GP board and on a custom fixed DDR configuration board (maxbcm). Note: This code has undergone many hours of coding-style cleanup and refactoring. It still is not checkpatch clean though, I'm afraid. As the factoring of the code has so many levels of indentation that many lines are longer than 80 chars. This might be some task to tackly later on. Signed-off-by: Stefan Roese <sr@denx.de> Reviewed-by: Luka Perkov <luka.perkov@sartura.hr>
10 years ago
/*
* Copyright (C) Marvell International Ltd. and its affiliates
*
* SPDX-License-Identifier: GPL-2.0
*/
#include <common.h>
#include <i2c.h>
#include <spl.h>
#include <asm/io.h>
#include <asm/arch/cpu.h>
#include <asm/arch/soc.h>
#include "xor.h"
#include "xor_regs.h"
static u32 xor_regs_ctrl_backup;
static u32 xor_regs_base_backup[MAX_CS];
static u32 xor_regs_mask_backup[MAX_CS];
static int mv_xor_cmd_set(u32 chan, int command);
static int mv_xor_ctrl_set(u32 chan, u32 xor_ctrl);
void mv_sys_xor_init(MV_DRAM_INFO *dram_info)
{
u32 reg, ui, base, cs_count;
xor_regs_ctrl_backup = reg_read(XOR_WINDOW_CTRL_REG(0, 0));
for (ui = 0; ui < MAX_CS; ui++)
xor_regs_base_backup[ui] = reg_read(XOR_BASE_ADDR_REG(0, ui));
for (ui = 0; ui < MAX_CS; ui++)
xor_regs_mask_backup[ui] = reg_read(XOR_SIZE_MASK_REG(0, ui));
reg = 0;
for (ui = 0; ui < (dram_info->num_cs + 1); ui++) {
/* Enable Window x for each CS */
reg |= (0x1 << (ui));
/* Enable Window x for each CS */
reg |= (0x3 << ((ui * 2) + 16));
}
reg_write(XOR_WINDOW_CTRL_REG(0, 0), reg);
/* Last window - Base - 0x40000000, Attribute 0x1E - SRAM */
base = (SRAM_BASE & 0xFFFF0000) | 0x1E00;
reg_write(XOR_BASE_ADDR_REG(0, dram_info->num_cs), base);
/* Last window - Size - 64 MB */
reg_write(XOR_SIZE_MASK_REG(0, dram_info->num_cs), 0x03FF0000);
cs_count = 0;
for (ui = 0; ui < MAX_CS; ui++) {
if (dram_info->cs_ena & (1 << ui)) {
/*
* Window x - Base - 0x00000000, Attribute 0x0E - DRAM
*/
base = 0;
switch (ui) {
case 0:
base |= 0xE00;
break;
case 1:
base |= 0xD00;
break;
case 2:
base |= 0xB00;
break;
case 3:
base |= 0x700;
break;
}
reg_write(XOR_BASE_ADDR_REG(0, cs_count), base);
/* Window x - Size - 256 MB */
reg_write(XOR_SIZE_MASK_REG(0, cs_count), 0x0FFF0000);
cs_count++;
}
}
mv_xor_hal_init(1);
return;
}
void mv_sys_xor_finish(void)
{
u32 ui;
reg_write(XOR_WINDOW_CTRL_REG(0, 0), xor_regs_ctrl_backup);
for (ui = 0; ui < MAX_CS; ui++)
reg_write(XOR_BASE_ADDR_REG(0, ui), xor_regs_base_backup[ui]);
for (ui = 0; ui < MAX_CS; ui++)
reg_write(XOR_SIZE_MASK_REG(0, ui), xor_regs_mask_backup[ui]);
reg_write(XOR_ADDR_OVRD_REG(0, 0), 0);
}
/*
* mv_xor_hal_init - Initialize XOR engine
*
* DESCRIPTION:
* This function initialize XOR unit.
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_BAD_PARAM if parameters to function invalid, MV_OK otherwise.
*/
void mv_xor_hal_init(u32 chan_num)
arm: mvebu: drivers/ddr: Add DDR3 driver with training code from Marvell bin_hdr This patch adds the DDR3 setup and training code taken from the Marvell U-Boot repository. This code used to be included as a binary (bin_hdr) into the AXP boot image. Not linked with the main U-Boot. With this code addition and the following serdes/PHY setup code, the Armada-XP support in mainline U-Boot is finally self-contained. So the complete image for booting can be built from mainline U-Boot. Without any additional external inclusion. Hopefully other MVEBU SoC's will follow here. Support for some SoC's has been removed in this version. This is: MV_MSYS: The code referred to by the MV_MSYS define is currently unused. And its not really planned to support this in mainline. So lets remove it to make the code clearer and increase the readability. MV88F68XX (A38x): The code referred to by the MV88F68XX define (A38x) is currently unused. And its partial and not sufficient for this device in this stage. So lets remove it to make the code clearer and increase the readability. MV88F66XX (ALP): The code referred to by the MV88F66XX define is currently unused. And its not really planned to support this in mainline. So lets remove it to make the code clearer and increase the readability. MV88F78X60_Z1: The code referred to by the MV88F78X60_Z1 define is currently unused. As the Z1 revision of the AXP is not supported in mainline anymore. So lets remove it to make the code clearer and increase the readability. Remove support for Z1 & A0 AXP revisions (steppings). The current stepping is B0 and this is the only one that is actively supported in this code version. Tested on AXP using a SPD DIMM setup on the Marvell DB-MV784MP-GP board and on a custom fixed DDR configuration board (maxbcm). Note: This code has undergone many hours of coding-style cleanup and refactoring. It still is not checkpatch clean though, I'm afraid. As the factoring of the code has so many levels of indentation that many lines are longer than 80 chars. This might be some task to tackly later on. Signed-off-by: Stefan Roese <sr@denx.de> Reviewed-by: Luka Perkov <luka.perkov@sartura.hr>
10 years ago
{
u32 i;
/* Abort any XOR activity & set default configuration */
for (i = 0; i < chan_num; i++) {
mv_xor_cmd_set(i, MV_STOP);
mv_xor_ctrl_set(i, (1 << XEXCR_REG_ACC_PROTECT_OFFS) |
(4 << XEXCR_DST_BURST_LIMIT_OFFS) |
(4 << XEXCR_SRC_BURST_LIMIT_OFFS));
}
}
/*
* mv_xor_ctrl_set - Set XOR channel control registers
*
* DESCRIPTION:
*
* INPUT:
*
* OUTPUT:
* None.
*
* RETURN:
* MV_BAD_PARAM if parameters to function invalid, MV_OK otherwise.
* NOTE:
* This function does not modify the OperationMode field of control register.
*
*/
static int mv_xor_ctrl_set(u32 chan, u32 xor_ctrl)
{
u32 val;
/* Update the XOR Engine [0..1] Configuration Registers (XExCR) */
val = reg_read(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)))
& XEXCR_OPERATION_MODE_MASK;
xor_ctrl &= ~XEXCR_OPERATION_MODE_MASK;
xor_ctrl |= val;
reg_write(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)), xor_ctrl);
return MV_OK;
}
int mv_xor_mem_init(u32 chan, u32 start_ptr, u32 block_size, u32 init_val_high,
u32 init_val_low)
{
u32 tmp;
/* Parameter checking */
if (chan >= MV_XOR_MAX_CHAN)
return MV_BAD_PARAM;
if (MV_ACTIVE == mv_xor_state_get(chan))
return MV_BUSY;
if ((block_size < XEXBSR_BLOCK_SIZE_MIN_VALUE) ||
(block_size > XEXBSR_BLOCK_SIZE_MAX_VALUE))
return MV_BAD_PARAM;
/* Set the operation mode to Memory Init */
tmp = reg_read(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)));
tmp &= ~XEXCR_OPERATION_MODE_MASK;
tmp |= XEXCR_OPERATION_MODE_MEM_INIT;
reg_write(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)), tmp);
/*
* Update the start_ptr field in XOR Engine [0..1] Destination Pointer
* Register (XExDPR0)
*/
reg_write(XOR_DST_PTR_REG(XOR_UNIT(chan), XOR_CHAN(chan)), start_ptr);
/*
* Update the BlockSize field in the XOR Engine[0..1] Block Size
* Registers (XExBSR)
*/
reg_write(XOR_BLOCK_SIZE_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
block_size);
/*
* Update the field InitValL in the XOR Engine Initial Value Register
* Low (XEIVRL)
*/
reg_write(XOR_INIT_VAL_LOW_REG(XOR_UNIT(chan)), init_val_low);
/*
* Update the field InitValH in the XOR Engine Initial Value Register
* High (XEIVRH)
*/
reg_write(XOR_INIT_VAL_HIGH_REG(XOR_UNIT(chan)), init_val_high);
/* Start transfer */
reg_bit_set(XOR_ACTIVATION_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
XEXACTR_XESTART_MASK);
return MV_OK;
}
/*
* mv_xor_transfer - Transfer data from source to destination on one of
* three modes (XOR,CRC32,DMA)
*
* DESCRIPTION:
* This function initiates XOR channel, according to function parameters,
* in order to perform XOR or CRC32 or DMA transaction.
* To gain maximum performance the user is asked to keep the following
* restrictions:
* 1) Selected engine is available (not busy).
* 1) This module does not take into consideration CPU MMU issues.
* In order for the XOR engine to access the appropreate source
* and destination, address parameters must be given in system
* physical mode.
* 2) This API does not take care of cache coherency issues. The source,
* destination and in case of chain the descriptor list are assumed
* to be cache coherent.
* 4) Parameters validity. For example, does size parameter exceeds
* maximum byte count of descriptor mode (16M or 64K).
*
* INPUT:
* chan - XOR channel number. See MV_XOR_CHANNEL enumerator.
* xor_type - One of three: XOR, CRC32 and DMA operations.
* xor_chain_ptr - address of chain pointer
*
* OUTPUT:
* None.
*
* RETURS:
* MV_BAD_PARAM if parameters to function invalid, MV_OK otherwise.
*
*/
int mv_xor_transfer(u32 chan, int xor_type, u32 xor_chain_ptr)
{
u32 tmp;
/* Parameter checking */
if (chan >= MV_XOR_MAX_CHAN) {
debug("%s: ERR. Invalid chan num %d\n", __func__, chan);
return MV_BAD_PARAM;
}
if (MV_ACTIVE == mv_xor_state_get(chan)) {
debug("%s: ERR. Channel is already active\n", __func__);
return MV_BUSY;
}
if (0x0 == xor_chain_ptr) {
debug("%s: ERR. xor_chain_ptr is NULL pointer\n", __func__);
return MV_BAD_PARAM;
}
/* Read configuration register and mask the operation mode field */
tmp = reg_read(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)));
tmp &= ~XEXCR_OPERATION_MODE_MASK;
switch (xor_type) {
case MV_XOR:
if (0 != (xor_chain_ptr & XEXDPR_DST_PTR_XOR_MASK)) {
debug("%s: ERR. Invalid chain pointer (bits [5:0] must be cleared)\n",
__func__);
return MV_BAD_PARAM;
}
/* Set the operation mode to XOR */
tmp |= XEXCR_OPERATION_MODE_XOR;
break;
case MV_DMA:
if (0 != (xor_chain_ptr & XEXDPR_DST_PTR_DMA_MASK)) {
debug("%s: ERR. Invalid chain pointer (bits [4:0] must be cleared)\n",
__func__);
return MV_BAD_PARAM;
}
/* Set the operation mode to DMA */
tmp |= XEXCR_OPERATION_MODE_DMA;
break;
case MV_CRC32:
if (0 != (xor_chain_ptr & XEXDPR_DST_PTR_CRC_MASK)) {
debug("%s: ERR. Invalid chain pointer (bits [4:0] must be cleared)\n",
__func__);
return MV_BAD_PARAM;
}
/* Set the operation mode to CRC32 */
tmp |= XEXCR_OPERATION_MODE_CRC;
break;
default:
return MV_BAD_PARAM;
}
/* Write the operation mode to the register */
reg_write(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)), tmp);
/*
* Update the NextDescPtr field in the XOR Engine [0..1] Next Descriptor
* Pointer Register (XExNDPR)
*/
reg_write(XOR_NEXT_DESC_PTR_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
xor_chain_ptr);
/* Start transfer */
reg_bit_set(XOR_ACTIVATION_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
XEXACTR_XESTART_MASK);
return MV_OK;
}
/*
* mv_xor_state_get - Get XOR channel state.
*
* DESCRIPTION:
* XOR channel activity state can be active, idle, paused.
* This function retrunes the channel activity state.
*
* INPUT:
* chan - the channel number
*
* OUTPUT:
* None.
*
* RETURN:
* XOR_CHANNEL_IDLE - If the engine is idle.
* XOR_CHANNEL_ACTIVE - If the engine is busy.
* XOR_CHANNEL_PAUSED - If the engine is paused.
* MV_UNDEFINED_STATE - If the engine state is undefind or there is no
* such engine
*
*/
int mv_xor_state_get(u32 chan)
{
u32 state;
/* Parameter checking */
if (chan >= MV_XOR_MAX_CHAN) {
debug("%s: ERR. Invalid chan num %d\n", __func__, chan);
return MV_UNDEFINED_STATE;
}
/* Read the current state */
state = reg_read(XOR_ACTIVATION_REG(XOR_UNIT(chan), XOR_CHAN(chan)));
state &= XEXACTR_XESTATUS_MASK;
/* Return the state */
switch (state) {
case XEXACTR_XESTATUS_IDLE:
return MV_IDLE;
case XEXACTR_XESTATUS_ACTIVE:
return MV_ACTIVE;
case XEXACTR_XESTATUS_PAUSED:
return MV_PAUSED;
}
return MV_UNDEFINED_STATE;
}
/*
* mv_xor_cmd_set - Set command of XOR channel
*
* DESCRIPTION:
* XOR channel can be started, idle, paused and restarted.
* Paused can be set only if channel is active.
* Start can be set only if channel is idle or paused.
* Restart can be set only if channel is paused.
* Stop can be set only if channel is active.
*
* INPUT:
* chan - The channel number
* command - The command type (start, stop, restart, pause)
*
* OUTPUT:
* None.
*
* RETURN:
* MV_OK on success , MV_BAD_PARAM on erroneous parameter, MV_ERROR on
* undefind XOR engine mode
*
*/
static int mv_xor_cmd_set(u32 chan, int command)
{
int state;
/* Parameter checking */
if (chan >= MV_XOR_MAX_CHAN) {
debug("%s: ERR. Invalid chan num %d\n", __func__, chan);
return MV_BAD_PARAM;
}
/* Get the current state */
state = mv_xor_state_get(chan);
/* Command is start and current state is idle */
if ((command == MV_START) && (state == MV_IDLE)) {
reg_bit_set(XOR_ACTIVATION_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
XEXACTR_XESTART_MASK);
return MV_OK;
}
/* Command is stop and current state is active */
else if ((command == MV_STOP) && (state == MV_ACTIVE)) {
reg_bit_set(XOR_ACTIVATION_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
XEXACTR_XESTOP_MASK);
return MV_OK;
}
/* Command is paused and current state is active */
else if ((command == MV_PAUSED) && (state == MV_ACTIVE)) {
reg_bit_set(XOR_ACTIVATION_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
XEXACTR_XEPAUSE_MASK);
return MV_OK;
}
/* Command is restart and current state is paused */
else if ((command == MV_RESTART) && (state == MV_PAUSED)) {
reg_bit_set(XOR_ACTIVATION_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
XEXACTR_XERESTART_MASK);
return MV_OK;
}
/* Command is stop and current state is active */
else if ((command == MV_STOP) && (state == MV_IDLE))
return MV_OK;
/* Illegal command */
debug("%s: ERR. Illegal command\n", __func__);
return MV_BAD_PARAM;
}