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mv_ddr4_mpr_pda_if.c
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mv_ddr4_mpr_pda_if.c
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/*******************************************************************************
Copyright (C) 2016 Marvell International Ltd.
This software file (the "File") is owned and distributed by Marvell
International Ltd. and/or its affiliates ("Marvell") under the following
alternative licensing terms. Once you have made an election to distribute the
File under one of the following license alternatives, please (i) delete this
introductory statement regarding license alternatives, (ii) delete the three
license alternatives that you have not elected to use and (iii) preserve the
Marvell copyright notice above.
********************************************************************************
Marvell Commercial License Option
If you received this File from Marvell and you have entered into a commercial
license agreement (a "Commercial License") with Marvell, the File is licensed
to you under the terms of the applicable Commercial License.
********************************************************************************
Marvell GPL License Option
This program is free software: you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the Free
Software Foundation, either version 2 of the License, or any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
********************************************************************************
Marvell GNU General Public License FreeRTOS Exception
If you received this File from Marvell, you may opt to use, redistribute and/or
modify this File in accordance with the terms and conditions of the Lesser
General Public License Version 2.1 plus the following FreeRTOS exception.
An independent module is a module which is not derived from or based on
FreeRTOS.
Clause 1:
Linking FreeRTOS statically or dynamically with other modules is making a
combined work based on FreeRTOS. Thus, the terms and conditions of the GNU
General Public License cover the whole combination.
As a special exception, the copyright holder of FreeRTOS gives you permission
to link FreeRTOS with independent modules that communicate with FreeRTOS solely
through the FreeRTOS API interface, regardless of the license terms of these
independent modules, and to copy and distribute the resulting combined work
under terms of your choice, provided that:
1. Every copy of the combined work is accompanied by a written statement that
details to the recipient the version of FreeRTOS used and an offer by yourself
to provide the FreeRTOS source code (including any modifications you may have
made) should the recipient request it.
2. The combined work is not itself an RTOS, scheduler, kernel or related
product.
3. The independent modules add significant and primary functionality to
FreeRTOS and do not merely extend the existing functionality already present in
FreeRTOS.
Clause 2:
FreeRTOS may not be used for any competitive or comparative purpose, including
the publication of any form of run time or compile time metric, without the
express permission of Real Time Engineers Ltd. (this is the norm within the
industry and is intended to ensure information accuracy).
********************************************************************************
Marvell BSD License Option
If you received this File from Marvell, you may opt to use, redistribute and/or
modify this File under the following licensing terms.
Redistribution and use in source and binary forms, with or without modification,
are permitted provided that the following conditions are met:
* Redistributions of source code must retain the above copyright notice,
this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
* Neither the name of Marvell nor the names of its contributors may be
used to endorse or promote products derived from this software without
specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*******************************************************************************/
#if defined(CONFIG_DDR4)
/* DDR4 MPR/PDA Interface */
#include "ddr3_init.h"
#include "mv_ddr4_mpr_pda_if.h"
#include "mv_ddr4_training.h"
#include "mv_ddr_training_db.h"
#include "mv_ddr_common.h"
#include "mv_ddr_regs.h"
static u8 dram_to_mc_dq_map[MAX_BUS_NUM][BUS_WIDTH_IN_BITS];
static int dq_map_enable;
static u32 mv_ddr4_tx_odt_get(void)
{
u16 odt = 0xffff, rtt = 0xffff;
if (g_odt_config & 0xe0000)
rtt = mv_ddr4_rtt_nom_to_odt(g_rtt_nom);
else if (g_odt_config & 0x10000)
rtt = mv_ddr4_rtt_wr_to_odt(g_rtt_wr);
else
return odt;
return (odt * rtt) / (odt + rtt);
}
/*
* mode registers initialization function
* replaces all MR writes in DDR3 init function
*/
int mv_ddr4_mode_regs_init(u8 dev_num)
{
int status;
struct mv_ddr_topology_map *tm = mv_ddr_topology_map_get();
enum hws_access_type access_type = ACCESS_TYPE_UNICAST;
u32 if_id;
u32 cl, cwl;
u32 val, mask;
u32 t_wr, t_ckclk;
/* design GL params to be set outside */
u32 dic = 0;
u32 ron = 30; /* znri */
u32 rodt = mv_ddr4_tx_odt_get(); /* effective rtt */
/* vref percentage presented as 100 x percentage value (e.g., 6000 = 100 x 60%) */
u32 vref = ((ron + rodt / 2) * 10000) / (ron + rodt);
u32 range = (vref >= 6000) ? 0 : 1; /* if vref is >= 60%, use upper range */
u32 tap;
u32 refresh_mode;
if (range == 0)
tap = (vref - 6000) / 65;
else
tap = (vref - 4500) / 65;
for (if_id = 0; if_id < MAX_INTERFACE_NUM; if_id++) {
VALIDATE_IF_ACTIVE(tm->if_act_mask, if_id);
cl = tm->interface_params[if_id].cas_l;
cwl = tm->interface_params[if_id].cas_wl;
t_ckclk = MEGA / mv_ddr_freq_get(tm->interface_params[if_id].memory_freq);
t_wr = time_to_nclk(mv_ddr_speed_bin_timing_get(tm->interface_params[if_id].speed_bin_index,
SPEED_BIN_TWR), t_ckclk) - 1;
/* TODO: replace hard-coded values with appropriate defines */
/* DDR4 MR0 */
/*
* [6:4,2] bits to be taken from S@R frequency and speed bin
* rtt_nom to be taken from the algorithm definition
* dic to be taken fro the algorithm definition -
* set to 0x1 (for driver rzq/5 = 48 ohm) or
* set to 0x0 (for driver rzq/7 = 34 ohm)
*/
/* set dll reset, 0x1900[8] to 0x1 */
/* set tm, 0x1900[7] to 0x0 */
/* set rbt, 0x1900[3] to 0x0 */
/* set bl, 0x1900[1:0] to 0x0 */
val = ((cl_mask_table[cl] & 0x1) << 2) |
(((cl_mask_table[cl] & 0xe) >> 1) << 4) |
(twr_mask_table[t_wr + 1] << 9) |
(0x1 << 8) | (0x0 << 7) | (0x0 << 3) | 0x0;
mask = (0x1 << 2) | (0x7 << 4) | (0x7 << 9) |
(0x1 << 8) | (0x1 << 7) | (0x1 << 3) | 0x3;
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR0_REG,
val, mask);
if (status != MV_OK)
return status;
/* DDR4 MR1 */
/* set rtt nom to 0 if rtt park is activated (not zero) */
if ((g_rtt_park >> 6) != 0x0)
g_rtt_nom = 0;
/* set tdqs, 0x1904[11] to 0x0 */
/* set al, 0x1904[4:3] to 0x0 */
/* dic, 0x1904[2:1] */
/* dll enable */
val = g_rtt_nom | (0x0 << 11) | (0x0 << 3) | (dic << 1) | 0x1;
mask = (0x7 << 8) | (0x1 << 11) | (0x3 << 3) | (0x3 << 1) | 0x1;
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR1_REG,
val, mask);
if (status != MV_OK)
return status;
/* DDR4 MR2 */
/* set rtt wr, 0x1908[10,9] to 0x0 */
/* set wr crc, 0x1908[12] to 0x0 */
/* cwl */
val = g_rtt_wr | (0x0 << 12) | (cwl_mask_table[cwl] << 3);
mask = (0x3 << 9) | (0x1 << 12) | (0x7 << 3);
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR2_REG,
val, mask);
if (status != MV_OK)
return status;
/* DDR4 MR3 */
/* set fgrm, 0x190C[8:6] to 0x0 */
/* set gd, 0x190C[3] to 0x0 */
refresh_mode = (tm->interface_params[if_id].interface_temp == MV_DDR_TEMP_HIGH) ? 1 : 0;
val = (refresh_mode << 6) | (0x0 << 3);
mask = (0x7 << 6) | (0x1 << 3);
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR3_REG,
val, mask);
if (status != MV_OK)
return status;
/* DDR4 MR4 */
/*
* set wp, 0x1910[12] to 0x0
* set rp, 0x1910[11] to 0x0
* set rp training, 0x1910[10] to 0x0
* set sra, 0x1910[9] to 0x0
* set cs2cmd, 0x1910[8:6] to 0x0
* set mpd, 0x1910[1] to 0x0
*/
mask = (0x1 << 12) | (0x1 << 11) | (0x1 << 10) | (0x1 << 9) | (0x7 << 6) | (0x1 << 1);
val = (0x0 << 12) | (0x1 << 11) | (0x0 << 10) | (0x0 << 9) | (0x0 << 6) | (0x0 << 1);
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR4_REG,
val, mask);
if (status != MV_OK)
return status;
/* DDR4 MR5 */
/*
* set rdbi, 0x1914[12] to 0x0 during init sequence (may be enabled with
* op cmd mrs - bug in z1, to be fixed in a0)
* set wdbi, 0x1914[11] to 0x0
* set dm, 0x1914[10] to 0x1
* set ca_pl, 0x1914[2:0] to 0x0
* set odt input buffer during power down mode, 0x1914[5] to 0x1
*/
mask = (0x1 << 12) | (0x1 << 11) | (0x1 << 10) | (0x7 << 6) | (0x1 << 5) | 0x7;
val = (0x0 << 12) | (0x0 << 11) | (0x1 << 10) | g_rtt_park | (0x1 << 5) | 0x0;
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR5_REG,
val, mask);
if (status != MV_OK)
return status;
/* DDR4 MR6 */
/*
* set t_ccd_l, 0x1918[12:10] to 0x0, 0x2, or 0x4 (z1 supports only even
* values, to be fixed in a0)
* set vdq te, 0x1918[7] to 0x0
* set vdq tv, 0x1918[5:0] to vref training value
*/
mask = (0x7 << 10) | (0x1 << 7) | (0x1 << 6) | 0x3f;
val = (0x2 << 10) | (0x0 << 7) | (range << 6) | tap;
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR6_REG,
val, mask);
if (status != MV_OK)
return status;
}
return MV_OK;
}
/* enter mpr read mode */
static int mv_ddr4_mpr_read_mode_enable(u8 dev_num, u32 mpr_num, u32 page_num,
enum mv_ddr4_mpr_read_format read_format)
{
/*
* enable MPR page 2 mpr mode in DDR4 MR3
* read_format: 0 for serial, 1 for parallel, and 2 for staggered
* TODO: add support for cs, multicast or unicast, and if id
*/
int status;
u32 val, mask, if_id = 0;
if (page_num != 0) {
/* serial is the only read format if the page is other than 0 */
read_format = MV_DDR4_MPR_READ_SERIAL;
}
val = (page_num << 0) | (0x1 << 2) | (read_format << 11);
mask = (0x3 << 0) | (0x1 << 2) | (0x3 << 11);
/* cs0 */
status = ddr3_tip_if_write(dev_num, ACCESS_TYPE_UNICAST, if_id, DDR4_MR3_REG, val, mask);
if (status != MV_OK)
return status;
/* op cmd: cs0, cs1 are on, cs2, cs3 are off */
status = ddr3_tip_if_write(dev_num, ACCESS_TYPE_UNICAST, if_id, SDRAM_OP_REG,
(0x9 | (0xc << 8)) , (0x1f | (0xf << 8)));
if (status != MV_OK)
return status;
if (ddr3_tip_if_polling(dev_num, ACCESS_TYPE_UNICAST, if_id, 0, 0x1f, SDRAM_OP_REG,
MAX_POLLING_ITERATIONS) != MV_OK) {
DEBUG_TRAINING_IP(DEBUG_LEVEL_ERROR, ("mv_ddr4_mpr_read_mode_enable: DDR3 poll failed(MPR3)\n"));
}
return MV_OK;
}
/* exit mpr read or write mode */
static int mv_ddr4_mpr_mode_disable(u8 dev_num)
{
/* TODO: add support for cs, multicast or unicast, and if id */
int status;
u32 val, mask, if_id = 0;
/* exit mpr */
val = 0x0 << 2;
mask = 0x1 << 2;
/* cs0 */
status = ddr3_tip_if_write(dev_num, ACCESS_TYPE_UNICAST, if_id, DDR4_MR3_REG, val, mask);
if (status != MV_OK)
return status;
/* op cmd: cs0, cs1 are on, cs2, cs3 are off */
status = ddr3_tip_if_write(dev_num, ACCESS_TYPE_UNICAST, if_id, SDRAM_OP_REG,
(0x9 | (0xc << 8)) , (0x1f | (0xf << 8)));
if (status != MV_OK)
return status;
if (ddr3_tip_if_polling(dev_num, ACCESS_TYPE_UNICAST, if_id, 0, 0x1f, SDRAM_OP_REG,
MAX_POLLING_ITERATIONS) != MV_OK) {
DEBUG_TRAINING_IP(DEBUG_LEVEL_ERROR, ("mv_ddr4_mpr_mode_disable: DDR3 poll failed(MPR3)\n"));
}
return MV_OK;
}
/* translate dq read value per dram dq pin */
static int mv_ddr4_dq_decode(u8 dev_num, u32 *data)
{
u32 subphy_num, dq_num;
u32 dq_val = 0, raw_data, idx;
struct mv_ddr_topology_map *tm = mv_ddr_topology_map_get();
u32 subphy_max = ddr3_tip_dev_attr_get(dev_num, MV_ATTR_OCTET_PER_INTERFACE);
/* suppose the third word is stable */
raw_data = data[2];
/* skip ecc supbhy; TODO: check to add support for ecc */
if (subphy_max % 2)
subphy_max -= 1;
for (subphy_num = 0; subphy_num < subphy_max; subphy_num++) {
VALIDATE_BUS_ACTIVE(tm->bus_act_mask, subphy_num);
for (dq_num = 0; dq_num < BUS_WIDTH_IN_BITS; dq_num++) {
idx = (dram_to_mc_dq_map[subphy_num][dq_num] + (subphy_num * BUS_WIDTH_IN_BITS));
dq_val |= (((raw_data & (1 << idx)) >> idx) << ((subphy_num * BUS_WIDTH_IN_BITS) + dq_num));
}
}
/* update burst words[0..7] with correct mapping */
for (idx = 0; idx < EXT_ACCESS_BURST_LENGTH; idx++)
data[idx] = dq_val;
return MV_OK;
}
/*
* read mpr value per requested format and type
* note: for parallel decoded read, data is presented as stored in mpr on dram side,
* for all others, data to be presneted "as is" (i.e. per dq order from high to low
* and bus pins connectivity).
*/
int mv_ddr4_mpr_read(u8 dev_num, u32 mpr_num, u32 page_num,
enum mv_ddr4_mpr_read_format read_format,
enum mv_ddr4_mpr_read_type read_type,
u32 *data)
{
/* TODO: add support for multiple if_id, dev num, and cs */
u32 word_idx, if_id = 0;
volatile unsigned long *addr = NULL;
/* enter mpr read mode */
mv_ddr4_mpr_read_mode_enable(dev_num, mpr_num, page_num, read_format);
/* set pattern type*/
ddr3_tip_if_write(dev_num, ACCESS_TYPE_UNICAST, if_id, DDR4_MPR_WR_REG,
mpr_num << 8, 0x3 << 8);
for (word_idx = 0; word_idx < EXT_ACCESS_BURST_LENGTH; word_idx++) {
data[word_idx] = *addr;
DEBUG_TRAINING_IP(DEBUG_LEVEL_INFO, ("mv_ddr4_mpr_read: addr 0x%08lx, data 0x%08x\n",
(unsigned long)addr, data[word_idx]));
addr++;
}
/* exit mpr read mode */
mv_ddr4_mpr_mode_disable(dev_num);
/* decode mpr read value (only parallel mode supported) */
if ((read_type == MV_DDR4_MPR_READ_DECODED) && (read_format == MV_DDR4_MPR_READ_PARALLEL)) {
if (dq_map_enable == 1) {
mv_ddr4_dq_decode(dev_num, data);
} else {
DEBUG_TRAINING_IP(DEBUG_LEVEL_ERROR, ("mv_ddr4_mpr_read: run mv_ddr4_dq_pins_mapping()\n"));
return MV_FAIL;
}
}
return MV_OK;
}
/* enter mpr write mode */
static int mv_ddr4_mpr_write_mode_enable(u8 dev_num, u32 mpr_location, u32 page_num, u32 data)
{
/*
* enable MPR page 2 mpr mode in DDR4 MR3
* TODO: add support for cs, multicast or unicast, and if id
*/
int status;
u32 if_id = 0, val = 0, mask;
val = (page_num << 0) | (0x1 << 2);
mask = (0x3 << 0) | (0x1 << 2);
/* cs0 */
status = ddr3_tip_if_write(dev_num, ACCESS_TYPE_UNICAST, if_id, DDR4_MR3_REG, val, mask);
if (status != MV_OK)
return status;
/* cs0 */
status = ddr3_tip_if_write(dev_num, ACCESS_TYPE_UNICAST, if_id, DDR4_MPR_WR_REG,
(mpr_location << 8) | data, 0x3ff);
if (status != MV_OK)
return status;
/* op cmd: cs0, cs1 are on, cs2, cs3 are off */
status = ddr3_tip_if_write(dev_num, ACCESS_TYPE_UNICAST, if_id, SDRAM_OP_REG,
(0x13 | 0xc << 8) , (0x1f | (0xf << 8)));
if (status != MV_OK)
return status;
if (ddr3_tip_if_polling(dev_num, ACCESS_TYPE_UNICAST, if_id, 0, 0x1f, SDRAM_OP_REG,
MAX_POLLING_ITERATIONS) != MV_OK) {
DEBUG_TRAINING_IP(DEBUG_LEVEL_ERROR, ("mv_ddr4_mpr_write_mode_enable: DDR3 poll failed(MPR3)\n"));
}
return MV_OK;
}
/* write mpr value */
int mv_ddr4_mpr_write(u8 dev_num, u32 mpr_location, u32 mpr_num, u32 page_num, u32 data)
{
/* enter mpr write mode */
mv_ddr4_mpr_write_mode_enable(dev_num, mpr_location, page_num, data);
/* TODO: implement this function */
/* TODO: exit mpr write mode */
return MV_OK;
}
/*
* map physical on-board connection of dram dq pins to ddr4 controller pins
* note: supports only 32b width
* TODO: add support for 64-bit bus width and ecc subphy
*/
int mv_ddr4_dq_pins_mapping(u8 dev_num)
{
static int run_once;
u8 dq_val[MAX_BUS_NUM][BUS_WIDTH_IN_BITS] = { {0} };
u32 mpr_pattern[MV_DDR4_MPR_READ_PATTERN_NUM][EXT_ACCESS_BURST_LENGTH] = { {0} };
u32 subphy_num, dq_num, mpr_type;
u8 subphy_pattern[3];
struct mv_ddr_topology_map *tm = mv_ddr_topology_map_get();
u32 subphy_max = ddr3_tip_dev_attr_get(dev_num, MV_ATTR_OCTET_PER_INTERFACE);
if (run_once)
return MV_OK;
else
run_once++;
/* clear dq mapping */
memset(dram_to_mc_dq_map, 0, sizeof(dram_to_mc_dq_map));
/* stage 1: read page 0 mpr0..2 raw patterns */
for (mpr_type = 0; mpr_type < MV_DDR4_MPR_READ_PATTERN_NUM; mpr_type++)
mv_ddr4_mpr_read(dev_num, mpr_type, 0, MV_DDR4_MPR_READ_PARALLEL,
MV_DDR4_MPR_READ_RAW, mpr_pattern[mpr_type]);
/* stage 2: map every dq for each subphy to 3-bit value, create local database */
/* skip ecc supbhy; TODO: check to add support for ecc */
if (subphy_max % 2)
subphy_max -= 1;
for (subphy_num = 0; subphy_num < subphy_max; subphy_num++) {
VALIDATE_BUS_ACTIVE(tm->bus_act_mask, subphy_num);
/* extract pattern for each subphy */
for (mpr_type = 0; mpr_type < MV_DDR4_MPR_READ_PATTERN_NUM; mpr_type++)
subphy_pattern[mpr_type] = ((mpr_pattern[mpr_type][2] >> (subphy_num * 8)) & 0xff);
for (dq_num = 0; dq_num < BUS_WIDTH_IN_BITS; dq_num++)
for (mpr_type = 0; mpr_type < MV_DDR4_MPR_READ_PATTERN_NUM; mpr_type++)
dq_val[subphy_num][dq_num] += (((subphy_pattern[mpr_type] >> dq_num) & 1) *
(1 << mpr_type));
}
/* stage 3: map dram dq to mc dq and update database */
for (subphy_num = 0; subphy_num < subphy_max; subphy_num++) {
VALIDATE_BUS_ACTIVE(tm->bus_act_mask, subphy_num);
for (dq_num = 0; dq_num < BUS_WIDTH_IN_BITS; dq_num++)
dram_to_mc_dq_map[subphy_num][7 - dq_val[subphy_num][dq_num]] = dq_num;
}
/* set dq_map_enable */
dq_map_enable = 1;
return MV_OK;
}
/* enter to or exit from dram vref training mode */
int mv_ddr4_vref_training_mode_ctrl(u8 dev_num, u8 if_id, enum hws_access_type access_type, int enable)
{
int status;
u32 val, mask;
/* DDR4 MR6 */
/*
* set t_ccd_l, 0x1918[12:10] to 0x0, 0x2, or 0x4 (z1 supports only even
* values, to be fixed in a0)
* set vdq te, 0x1918[7] to 0x0
* set vdq tv, 0x1918[5:0] to vref training value
*/
val = (((enable == 1) ? 1 : 0) << 7);
mask = (0x1 << 7);
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR6_REG, val, mask);
if (status != MV_OK)
return status;
/* write DDR4 MR6 cs configuration; only cs0, cs1 supported */
if (effective_cs == 0)
val = 0xe;
else
val = 0xd;
val <<= 8;
/* write DDR4 MR6 command */
val |= 0x12;
mask = (0xf << 8) | 0x1f;
status = ddr3_tip_if_write(dev_num, access_type, if_id, SDRAM_OP_REG, val, mask);
if (status != MV_OK)
return status;
if (ddr3_tip_if_polling(dev_num, ACCESS_TYPE_UNICAST, if_id, 0, 0x1f, SDRAM_OP_REG,
MAX_POLLING_ITERATIONS) != MV_OK) {
DEBUG_TRAINING_IP(DEBUG_LEVEL_ERROR, ("mv_ddr4_vref_training_mode_ctrl: Polling command failed\n"));
}
return MV_OK;
}
/* set dram vref tap value */
int mv_ddr4_vref_tap_set(u8 dev_num, u8 if_id, enum hws_access_type access_type,
u32 taps_num, enum mv_ddr4_vref_tap_state state)
{
int status;
u32 range, vdq_tv;
/* disable and then enable the training with a new range */
if ((state == MV_DDR4_VREF_TAP_BUSY) && ((taps_num + MV_DDR4_VREF_STEP_SIZE) >= 23) &&
(taps_num < 23))
state = MV_DDR4_VREF_TAP_FLIP;
if (taps_num < 23) {
range = 1;
vdq_tv = taps_num;
} else {
range = 0;
vdq_tv = taps_num - 23;
}
if ((state == MV_DDR4_VREF_TAP_FLIP) | (state == MV_DDR4_VREF_TAP_START)) {
/* 0 to disable */
status = mv_ddr4_vref_set(dev_num, if_id, access_type, range, vdq_tv, 0);
if (status != MV_OK)
return status;
/* 1 to enable */
status = (mv_ddr4_vref_set(dev_num, if_id, access_type, range, vdq_tv, 1));
if (status != MV_OK)
return status;
} else if (state == MV_DDR4_VREF_TAP_END) {
/* 1 to enable */
status = (mv_ddr4_vref_set(dev_num, if_id, access_type, range, vdq_tv, 1));
if (status != MV_OK)
return status;
/* 0 to disable */
status = mv_ddr4_vref_set(dev_num, if_id, access_type, range, vdq_tv, 0);
if (status != MV_OK)
return status;
} else {
/* 1 to enable */
status = (mv_ddr4_vref_set(dev_num, if_id, access_type, range, vdq_tv, 1));
if (status != MV_OK)
return status;
}
return MV_OK;
}
/* set dram vref value */
int mv_ddr4_vref_set(u8 dev_num, u8 if_id, enum hws_access_type access_type,
u32 range, u32 vdq_tv, u8 vdq_training_ena)
{
int status;
u32 read_data;
u32 val, mask;
DEBUG_TRAINING_IP(DEBUG_LEVEL_INFO, ("mv_ddr4_vref_set: range %d, vdq_tv %d\n", range, vdq_tv));
/* DDR4 MR6 */
/*
* set t_ccd_l, 0x1918[12:10] to 0x0, 0x2, or 0x4 (z1 supports only even
* values, to be fixed in a0)
* set vdq te, 0x1918[7] to 0x0
* set vdq tr, 0x1918[6] to 0x0 to disable or 0x1 to enable
* set vdq tv, 0x1918[5:0] to vref training value
*/
val = (vdq_training_ena << 7) | (range << 6) | vdq_tv;
mask = (0x0 << 7) | (0x1 << 6) | 0x3f;
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR6_REG, val, mask);
if (status != MV_OK)
return status;
ddr3_tip_if_read(dev_num, access_type, if_id, DDR4_MR6_REG, &read_data, 0xffffffff);
DEBUG_TRAINING_IP(DEBUG_LEVEL_INFO, ("mv_ddr4_vref_set: MR6 = 0x%x\n", read_data));
/* write DDR4 MR6 cs configuration; only cs0, cs1 supported */
if (effective_cs == 0)
val = 0xe;
else
val = 0xd;
val <<= 8;
/* write DDR4 MR6 command */
val |= 0x12;
mask = (0xf << 8) | 0x1f;
status = ddr3_tip_if_write(dev_num, access_type, if_id, SDRAM_OP_REG, val, mask);
if (status != MV_OK)
return status;
if (ddr3_tip_if_polling(dev_num, ACCESS_TYPE_UNICAST, if_id, 0, 0x1F, SDRAM_OP_REG,
MAX_POLLING_ITERATIONS) != MV_OK) {
DEBUG_TRAINING_IP(DEBUG_LEVEL_ERROR, ("mv_ddr4_vref_set: Polling command failed\n"));
}
return MV_OK;
}
/* pda - load pattern to odpg */
int mv_ddr4_pda_pattern_odpg_load(u32 dev_num, enum hws_access_type access_type,
u32 if_id, u32 subphy_mask, u32 cs_num)
{
int status;
u32 pattern_len_count = 0;
u32 data_low[KILLER_PATTERN_LENGTH] = {0};
u32 data_high[KILLER_PATTERN_LENGTH] = {0};
u32 val, mask, subphy_num;
/*
* set 0x1630[10:5] bits to 0x3 (0x1 for 16-bit bus width)
* set 0x1630[14:11] bits to 0x3 (0x1 for 16-bit bus width)
*/
val = (cs_num << 26) | (0x1 << 25) | (0x3 << 11) | (0x3 << 5) | 0x1;
mask = (0x3 << 26) | (0x1 << 25) | (0x3f << 11) | (0x3f << 5) | 0x1;
status = ddr3_tip_if_write(dev_num, access_type, if_id, ODPG_DATA_CTRL_REG, val, mask);
if (status != MV_OK)
return status;
if (subphy_mask != 0xf) {
for (subphy_num = 0; subphy_num < 4; subphy_num++)
if (((subphy_mask >> subphy_num) & 0x1) == 0)
data_low[0] = (data_low[0] | (0xff << (subphy_num * 8)));
} else
data_low[0] = 0;
for (pattern_len_count = 0; pattern_len_count < 4; pattern_len_count++) {
data_low[pattern_len_count] = data_low[0];
data_high[pattern_len_count] = data_low[0];
}
for (pattern_len_count = 0; pattern_len_count < 4 ; pattern_len_count++) {
status = ddr3_tip_if_write(dev_num, access_type, if_id, ODPG_DATA_WR_DATA_LOW_REG,
data_low[pattern_len_count], MASK_ALL_BITS);
if (status != MV_OK)
return status;
status = ddr3_tip_if_write(dev_num, access_type, if_id, ODPG_DATA_WR_DATA_HIGH_REG,
data_high[pattern_len_count], MASK_ALL_BITS);
if (status != MV_OK)
return status;
status = ddr3_tip_if_write(dev_num, access_type, if_id, ODPG_DATA_WR_ADDR_REG,
pattern_len_count, MASK_ALL_BITS);
if (status != MV_OK)
return status;
}
status = ddr3_tip_if_write(dev_num, access_type, if_id, ODPG_DATA_BUFFER_OFFS_REG,
0x0, MASK_ALL_BITS);
if (status != MV_OK)
return status;
return MV_OK;
}
/* enable or disable pda */
int mv_ddr4_pda_ctrl(u8 dev_num, u8 if_id, u8 cs_num, int enable)
{
/*
* if enable is 0, exit
* mrs to be directed to all dram devices
* a calling function responsible to change odpg to 0x0
*/
int status;
enum hws_access_type access_type = ACCESS_TYPE_UNICAST;
u32 val, mask;
/* per dram addressability enable */
val = ((enable == 1) ? 1 : 0);
val <<= 4;
mask = 0x1 << 4;
status = ddr3_tip_if_write(dev_num, access_type, if_id, DDR4_MR3_REG, val, mask);
if (status != MV_OK)
return status;
/* write DDR4 MR3 cs configuration; only cs0, cs1 supported */
if (cs_num == 0)
val = 0xe;
else
val = 0xd;
val <<= 8;
/* write DDR4 MR3 command */
val |= 0x9;
mask = (0xf << 8) | 0x1f;
status = ddr3_tip_if_write(dev_num, access_type, if_id, SDRAM_OP_REG, val, mask);
if (status != MV_OK)
return status;
if (enable == 0) {
/* check odpg access is done */
if (mv_ddr_is_odpg_done(MAX_POLLING_ITERATIONS) != MV_OK)
return MV_FAIL;
}
if (ddr3_tip_if_polling(dev_num, ACCESS_TYPE_UNICAST, if_id, 0, 0x1f, SDRAM_OP_REG,
MAX_POLLING_ITERATIONS) != MV_OK)
DEBUG_TRAINING_IP(DEBUG_LEVEL_ERROR, ("mv_ddr4_pda_ctrl: Polling command failed\n"));
return MV_OK;
}
#endif /* CONFIG_DDR4 */