Commit 9b9d8632 authored by Joseph Lo's avatar Joseph Lo Committed by Thierry Reding

memory: tegra: Add EMC scaling sequence code for Tegra210

This patch includes the sequence for clock tuning and the dynamic
training mechanism for the clock above 800MHz.

And historically there have been different sequences to change the EMC
clock. The sequence to be used is specified in the EMC table.
However, for the currently supported upstreaming platform, only the most
recent sequence is used. So only support that in this patch.

Based on the work of Peter De Schrijver <pdeschrijver@nvidia.com>.
Signed-off-by: default avatarJoseph Lo <josephl@nvidia.com>
Signed-off-by: default avatarThierry Reding <treding@nvidia.com>
parent 10de2114
......@@ -18,4 +18,4 @@ obj-$(CONFIG_TEGRA210_EMC) += tegra210-emc.o
obj-$(CONFIG_ARCH_TEGRA_186_SOC) += tegra186.o tegra186-emc.o
obj-$(CONFIG_ARCH_TEGRA_194_SOC) += tegra186.o tegra186-emc.o
tegra210-emc-y := tegra210-emc-core.o
tegra210-emc-y := tegra210-emc-core.o tegra210-emc-cc-r21021.o
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2014-2020, NVIDIA CORPORATION. All rights reserved.
*/
#include <linux/kernel.h>
#include <linux/io.h>
#include <linux/clk.h>
#include <linux/delay.h>
#include <linux/of.h>
#include <soc/tegra/mc.h>
#include "tegra210-emc.h"
#include "tegra210-mc.h"
/*
* Enable flags for specifying verbosity.
*/
#define INFO (1 << 0)
#define STEPS (1 << 1)
#define SUB_STEPS (1 << 2)
#define PRELOCK (1 << 3)
#define PRELOCK_STEPS (1 << 4)
#define ACTIVE_EN (1 << 5)
#define PRAMP_UP (1 << 6)
#define PRAMP_DN (1 << 7)
#define EMA_WRITES (1 << 10)
#define EMA_UPDATES (1 << 11)
#define PER_TRAIN (1 << 16)
#define CC_PRINT (1 << 17)
#define CCFIFO (1 << 29)
#define REGS (1 << 30)
#define REG_LISTS (1 << 31)
#define emc_dbg(emc, flags, ...) dev_dbg(emc->dev, __VA_ARGS__)
#define DVFS_CLOCK_CHANGE_VERSION 21021
#define EMC_PRELOCK_VERSION 2101
enum {
DVFS_SEQUENCE = 1,
WRITE_TRAINING_SEQUENCE = 2,
PERIODIC_TRAINING_SEQUENCE = 3,
DVFS_PT1 = 10,
DVFS_UPDATE = 11,
TRAINING_PT1 = 12,
TRAINING_UPDATE = 13,
PERIODIC_TRAINING_UPDATE = 14
};
/*
* PTFV defines - basically just indexes into the per table PTFV array.
*/
#define PTFV_DQSOSC_MOVAVG_C0D0U0_INDEX 0
#define PTFV_DQSOSC_MOVAVG_C0D0U1_INDEX 1
#define PTFV_DQSOSC_MOVAVG_C0D1U0_INDEX 2
#define PTFV_DQSOSC_MOVAVG_C0D1U1_INDEX 3
#define PTFV_DQSOSC_MOVAVG_C1D0U0_INDEX 4
#define PTFV_DQSOSC_MOVAVG_C1D0U1_INDEX 5
#define PTFV_DQSOSC_MOVAVG_C1D1U0_INDEX 6
#define PTFV_DQSOSC_MOVAVG_C1D1U1_INDEX 7
#define PTFV_DVFS_SAMPLES_INDEX 9
#define PTFV_MOVAVG_WEIGHT_INDEX 10
#define PTFV_CONFIG_CTRL_INDEX 11
#define PTFV_CONFIG_CTRL_USE_PREVIOUS_EMA (1 << 0)
/*
* Do arithmetic in fixed point.
*/
#define MOVAVG_PRECISION_FACTOR 100
/*
* The division portion of the average operation.
*/
#define __AVERAGE_PTFV(dev) \
({ next->ptfv_list[PTFV_DQSOSC_MOVAVG_ ## dev ## _INDEX] = \
next->ptfv_list[PTFV_DQSOSC_MOVAVG_ ## dev ## _INDEX] / \
next->ptfv_list[PTFV_DVFS_SAMPLES_INDEX]; })
/*
* Convert val to fixed point and add it to the temporary average.
*/
#define __INCREMENT_PTFV(dev, val) \
({ next->ptfv_list[PTFV_DQSOSC_MOVAVG_ ## dev ## _INDEX] += \
((val) * MOVAVG_PRECISION_FACTOR); })
/*
* Convert a moving average back to integral form and return the value.
*/
#define __MOVAVG_AC(timing, dev) \
((timing)->ptfv_list[PTFV_DQSOSC_MOVAVG_ ## dev ## _INDEX] / \
MOVAVG_PRECISION_FACTOR)
/* Weighted update. */
#define __WEIGHTED_UPDATE_PTFV(dev, nval) \
do { \
int w = PTFV_MOVAVG_WEIGHT_INDEX; \
int dqs = PTFV_DQSOSC_MOVAVG_ ## dev ## _INDEX; \
\
next->ptfv_list[dqs] = \
((nval * MOVAVG_PRECISION_FACTOR) + \
(next->ptfv_list[dqs] * \
next->ptfv_list[w])) / \
(next->ptfv_list[w] + 1); \
\
emc_dbg(emc, EMA_UPDATES, "%s: (s=%lu) EMA: %u\n", \
__stringify(dev), nval, next->ptfv_list[dqs]); \
} while (0)
/* Access a particular average. */
#define __MOVAVG(timing, dev) \
((timing)->ptfv_list[PTFV_DQSOSC_MOVAVG_ ## dev ## _INDEX])
static u32 update_clock_tree_delay(struct tegra210_emc *emc, int type)
{
bool periodic_training_update = type == PERIODIC_TRAINING_UPDATE;
struct tegra210_emc_timing *last = emc->last;
struct tegra210_emc_timing *next = emc->next;
u32 last_timing_rate_mhz = last->rate / 1000;
u32 next_timing_rate_mhz = next->rate / 1000;
bool dvfs_update = type == DVFS_UPDATE;
s32 tdel = 0, tmdel = 0, adel = 0;
bool dvfs_pt1 = type == DVFS_PT1;
unsigned long cval = 0;
u32 temp[2][2], value;
unsigned int i;
/*
* Dev0 MSB.
*/
if (dvfs_pt1 || periodic_training_update) {
value = tegra210_emc_mrr_read(emc, 2, 19);
for (i = 0; i < emc->num_channels; i++) {
temp[i][0] = (value & 0x00ff) << 8;
temp[i][1] = (value & 0xff00) << 0;
value >>= 16;
}
/*
* Dev0 LSB.
*/
value = tegra210_emc_mrr_read(emc, 2, 18);
for (i = 0; i < emc->num_channels; i++) {
temp[i][0] |= (value & 0x00ff) >> 0;
temp[i][1] |= (value & 0xff00) >> 8;
value >>= 16;
}
}
if (dvfs_pt1 || periodic_training_update) {
cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
cval *= 1000000;
cval /= last_timing_rate_mhz * 2 * temp[0][0];
}
if (dvfs_pt1)
__INCREMENT_PTFV(C0D0U0, cval);
else if (dvfs_update)
__AVERAGE_PTFV(C0D0U0);
else if (periodic_training_update)
__WEIGHTED_UPDATE_PTFV(C0D0U0, cval);
if (dvfs_update || periodic_training_update) {
tdel = next->current_dram_clktree[C0D0U0] -
__MOVAVG_AC(next, C0D0U0);
tmdel = (tdel < 0) ? -1 * tdel : tdel;
adel = tmdel;
if (tmdel * 128 * next_timing_rate_mhz / 1000000 >
next->tree_margin)
next->current_dram_clktree[C0D0U0] =
__MOVAVG_AC(next, C0D0U0);
}
if (dvfs_pt1 || periodic_training_update) {
cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
cval *= 1000000;
cval /= last_timing_rate_mhz * 2 * temp[0][1];
}
if (dvfs_pt1)
__INCREMENT_PTFV(C0D0U1, cval);
else if (dvfs_update)
__AVERAGE_PTFV(C0D0U1);
else if (periodic_training_update)
__WEIGHTED_UPDATE_PTFV(C0D0U1, cval);
if (dvfs_update || periodic_training_update) {
tdel = next->current_dram_clktree[C0D0U1] -
__MOVAVG_AC(next, C0D0U1);
tmdel = (tdel < 0) ? -1 * tdel : tdel;
if (tmdel > adel)
adel = tmdel;
if (tmdel * 128 * next_timing_rate_mhz / 1000000 >
next->tree_margin)
next->current_dram_clktree[C0D0U1] =
__MOVAVG_AC(next, C0D0U1);
}
if (emc->num_channels > 1) {
if (dvfs_pt1 || periodic_training_update) {
cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
cval *= 1000000;
cval /= last_timing_rate_mhz * 2 * temp[1][0];
}
if (dvfs_pt1)
__INCREMENT_PTFV(C1D0U0, cval);
else if (dvfs_update)
__AVERAGE_PTFV(C1D0U0);
else if (periodic_training_update)
__WEIGHTED_UPDATE_PTFV(C1D0U0, cval);
if (dvfs_update || periodic_training_update) {
tdel = next->current_dram_clktree[C1D0U0] -
__MOVAVG_AC(next, C1D0U0);
tmdel = (tdel < 0) ? -1 * tdel : tdel;
if (tmdel > adel)
adel = tmdel;
if (tmdel * 128 * next_timing_rate_mhz / 1000000 >
next->tree_margin)
next->current_dram_clktree[C1D0U0] =
__MOVAVG_AC(next, C1D0U0);
}
if (dvfs_pt1 || periodic_training_update) {
cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
cval *= 1000000;
cval /= last_timing_rate_mhz * 2 * temp[1][1];
}
if (dvfs_pt1)
__INCREMENT_PTFV(C1D0U1, cval);
else if (dvfs_update)
__AVERAGE_PTFV(C1D0U1);
else if (periodic_training_update)
__WEIGHTED_UPDATE_PTFV(C1D0U1, cval);
if (dvfs_update || periodic_training_update) {
tdel = next->current_dram_clktree[C1D0U1] -
__MOVAVG_AC(next, C1D0U1);
tmdel = (tdel < 0) ? -1 * tdel : tdel;
if (tmdel > adel)
adel = tmdel;
if (tmdel * 128 * next_timing_rate_mhz / 1000000 >
next->tree_margin)
next->current_dram_clktree[C1D0U1] =
__MOVAVG_AC(next, C1D0U1);
}
}
if (emc->num_devices < 2)
goto done;
/*
* Dev1 MSB.
*/
if (dvfs_pt1 || periodic_training_update) {
value = tegra210_emc_mrr_read(emc, 1, 19);
for (i = 0; i < emc->num_channels; i++) {
temp[i][0] = (value & 0x00ff) << 8;
temp[i][1] = (value & 0xff00) << 0;
value >>= 16;
}
/*
* Dev1 LSB.
*/
value = tegra210_emc_mrr_read(emc, 2, 18);
for (i = 0; i < emc->num_channels; i++) {
temp[i][0] |= (value & 0x00ff) >> 0;
temp[i][1] |= (value & 0xff00) >> 8;
value >>= 16;
}
}
if (dvfs_pt1 || periodic_training_update) {
cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
cval *= 1000000;
cval /= last_timing_rate_mhz * 2 * temp[0][0];
}
if (dvfs_pt1)
__INCREMENT_PTFV(C0D1U0, cval);
else if (dvfs_update)
__AVERAGE_PTFV(C0D1U0);
else if (periodic_training_update)
__WEIGHTED_UPDATE_PTFV(C0D1U0, cval);
if (dvfs_update || periodic_training_update) {
tdel = next->current_dram_clktree[C0D1U0] -
__MOVAVG_AC(next, C0D1U0);
tmdel = (tdel < 0) ? -1 * tdel : tdel;
if (tmdel > adel)
adel = tmdel;
if (tmdel * 128 * next_timing_rate_mhz / 1000000 >
next->tree_margin)
next->current_dram_clktree[C0D1U0] =
__MOVAVG_AC(next, C0D1U0);
}
if (dvfs_pt1 || periodic_training_update) {
cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
cval *= 1000000;
cval /= last_timing_rate_mhz * 2 * temp[0][1];
}
if (dvfs_pt1)
__INCREMENT_PTFV(C0D1U1, cval);
else if (dvfs_update)
__AVERAGE_PTFV(C0D1U1);
else if (periodic_training_update)
__WEIGHTED_UPDATE_PTFV(C0D1U1, cval);
if (dvfs_update || periodic_training_update) {
tdel = next->current_dram_clktree[C0D1U1] -
__MOVAVG_AC(next, C0D1U1);
tmdel = (tdel < 0) ? -1 * tdel : tdel;
if (tmdel > adel)
adel = tmdel;
if (tmdel * 128 * next_timing_rate_mhz / 1000000 >
next->tree_margin)
next->current_dram_clktree[C0D1U1] =
__MOVAVG_AC(next, C0D1U1);
}
if (emc->num_channels > 1) {
if (dvfs_pt1 || periodic_training_update) {
cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
cval *= 1000000;
cval /= last_timing_rate_mhz * 2 * temp[1][0];
}
if (dvfs_pt1)
__INCREMENT_PTFV(C1D1U0, cval);
else if (dvfs_update)
__AVERAGE_PTFV(C1D1U0);
else if (periodic_training_update)
__WEIGHTED_UPDATE_PTFV(C1D1U0, cval);
if (dvfs_update || periodic_training_update) {
tdel = next->current_dram_clktree[C1D1U0] -
__MOVAVG_AC(next, C1D1U0);
tmdel = (tdel < 0) ? -1 * tdel : tdel;
if (tmdel > adel)
adel = tmdel;
if (tmdel * 128 * next_timing_rate_mhz / 1000000 >
next->tree_margin)
next->current_dram_clktree[C1D1U0] =
__MOVAVG_AC(next, C1D1U0);
}
if (dvfs_pt1 || periodic_training_update) {
cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
cval *= 1000000;
cval /= last_timing_rate_mhz * 2 * temp[1][1];
}
if (dvfs_pt1)
__INCREMENT_PTFV(C1D1U1, cval);
else if (dvfs_update)
__AVERAGE_PTFV(C1D1U1);
else if (periodic_training_update)
__WEIGHTED_UPDATE_PTFV(C1D1U1, cval);
if (dvfs_update || periodic_training_update) {
tdel = next->current_dram_clktree[C1D1U1] -
__MOVAVG_AC(next, C1D1U1);
tmdel = (tdel < 0) ? -1 * tdel : tdel;
if (tmdel > adel)
adel = tmdel;
if (tmdel * 128 * next_timing_rate_mhz / 1000000 >
next->tree_margin)
next->current_dram_clktree[C1D1U1] =
__MOVAVG_AC(next, C1D1U1);
}
}
done:
return adel;
}
static u32 periodic_compensation_handler(struct tegra210_emc *emc, u32 type,
struct tegra210_emc_timing *last,
struct tegra210_emc_timing *next)
{
#define __COPY_EMA(nt, lt, dev) \
({ __MOVAVG(nt, dev) = __MOVAVG(lt, dev) * \
(nt)->ptfv_list[PTFV_DVFS_SAMPLES_INDEX]; })
u32 i, adel = 0, samples = next->ptfv_list[PTFV_DVFS_SAMPLES_INDEX];
u32 delay;
delay = tegra210_emc_actual_osc_clocks(last->run_clocks);
delay *= 1000;
delay = 2 + (delay / last->rate);
if (!next->periodic_training)
return 0;
if (type == DVFS_SEQUENCE) {
if (last->periodic_training &&
(next->ptfv_list[PTFV_CONFIG_CTRL_INDEX] &
PTFV_CONFIG_CTRL_USE_PREVIOUS_EMA)) {
/*
* If the previous frequency was using periodic
* calibration then we can reuse the previous
* frequencies EMA data.
*/
__COPY_EMA(next, last, C0D0U0);
__COPY_EMA(next, last, C0D0U1);
__COPY_EMA(next, last, C1D0U0);
__COPY_EMA(next, last, C1D0U1);
__COPY_EMA(next, last, C0D1U0);
__COPY_EMA(next, last, C0D1U1);
__COPY_EMA(next, last, C1D1U0);
__COPY_EMA(next, last, C1D1U1);
} else {
/* Reset the EMA.*/
__MOVAVG(next, C0D0U0) = 0;
__MOVAVG(next, C0D0U1) = 0;
__MOVAVG(next, C1D0U0) = 0;
__MOVAVG(next, C1D0U1) = 0;
__MOVAVG(next, C0D1U0) = 0;
__MOVAVG(next, C0D1U1) = 0;
__MOVAVG(next, C1D1U0) = 0;
__MOVAVG(next, C1D1U1) = 0;
for (i = 0; i < samples; i++) {
tegra210_emc_start_periodic_compensation(emc);
udelay(delay);
/*
* Generate next sample of data.
*/
adel = update_clock_tree_delay(emc, DVFS_PT1);
}
}
/*
* Seems like it should be part of the
* 'if (last_timing->periodic_training)' conditional
* since is already done for the else clause.
*/
adel = update_clock_tree_delay(emc, DVFS_UPDATE);
}
if (type == PERIODIC_TRAINING_SEQUENCE) {
tegra210_emc_start_periodic_compensation(emc);
udelay(delay);
adel = update_clock_tree_delay(emc, PERIODIC_TRAINING_UPDATE);
}
return adel;
}
static u32 tegra210_emc_r21021_periodic_compensation(struct tegra210_emc *emc)
{
u32 emc_cfg, emc_cfg_o, emc_cfg_update, del, value;
u32 list[] = {
EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_0,
EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_1,
EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_2,
EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_3,
EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_0,
EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_1,
EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_2,
EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_3,
EMC_DATA_BRLSHFT_0,
EMC_DATA_BRLSHFT_1
};
struct tegra210_emc_timing *last = emc->last;
unsigned int items = ARRAY_SIZE(list), i;
unsigned long delay;
if (last->periodic_training) {
emc_dbg(emc, PER_TRAIN, "Periodic training starting\n");
value = emc_readl(emc, EMC_DBG);
emc_cfg_o = emc_readl(emc, EMC_CFG);
emc_cfg = emc_cfg_o & ~(EMC_CFG_DYN_SELF_REF |
EMC_CFG_DRAM_ACPD |
EMC_CFG_DRAM_CLKSTOP_PD |
EMC_CFG_DRAM_CLKSTOP_PD);
/*
* 1. Power optimizations should be off.
*/
emc_writel(emc, emc_cfg, EMC_CFG);
/* Does emc_timing_update() for above changes. */
tegra210_emc_dll_disable(emc);
for (i = 0; i < emc->num_channels; i++)
tegra210_emc_wait_for_update(emc, i, EMC_EMC_STATUS,
EMC_EMC_STATUS_DRAM_IN_POWERDOWN_MASK,
0);
for (i = 0; i < emc->num_channels; i++)
tegra210_emc_wait_for_update(emc, i, EMC_EMC_STATUS,
EMC_EMC_STATUS_DRAM_IN_SELF_REFRESH_MASK,
0);
emc_cfg_update = value = emc_readl(emc, EMC_CFG_UPDATE);
value &= ~EMC_CFG_UPDATE_UPDATE_DLL_IN_UPDATE_MASK;
value |= (2 << EMC_CFG_UPDATE_UPDATE_DLL_IN_UPDATE_SHIFT);
emc_writel(emc, value, EMC_CFG_UPDATE);
/*
* 2. osc kick off - this assumes training and dvfs have set
* correct MR23.
*/
tegra210_emc_start_periodic_compensation(emc);
/*
* 3. Let dram capture its clock tree delays.
*/
delay = tegra210_emc_actual_osc_clocks(last->run_clocks);
delay *= 1000;
delay /= last->rate + 1;
udelay(delay);
/*
* 4. Check delta wrt previous values (save value if margin
* exceeds what is set in table).
*/
del = periodic_compensation_handler(emc,
PERIODIC_TRAINING_SEQUENCE,
last, last);
/*
* 5. Apply compensation w.r.t. trained values (if clock tree
* has drifted more than the set margin).
*/
if (last->tree_margin < ((del * 128 * (last->rate / 1000)) / 1000000)) {
for (i = 0; i < items; i++) {
value = tegra210_emc_compensate(last, list[i]);
emc_dbg(emc, EMA_WRITES, "0x%08x <= 0x%08x\n",
list[i], value);
emc_writel(emc, value, list[i]);
}
}
emc_writel(emc, emc_cfg_o, EMC_CFG);
/*
* 6. Timing update actally applies the new trimmers.
*/
tegra210_emc_timing_update(emc);
/* 6.1. Restore the UPDATE_DLL_IN_UPDATE field. */
emc_writel(emc, emc_cfg_update, EMC_CFG_UPDATE);
/* 6.2. Restore the DLL. */
tegra210_emc_dll_enable(emc);
}
return 0;
}
/*
* Do the clock change sequence.
*/
static void tegra210_emc_r21021_set_clock(struct tegra210_emc *emc, u32 clksrc)
{
/* state variables */
static bool fsp_for_next_freq;
/* constant configuration parameters */
const bool save_restore_clkstop_pd = true;
const u32 zqcal_before_cc_cutoff = 2400;
const bool cya_allow_ref_cc = false;
const bool cya_issue_pc_ref = false;
const bool opt_cc_short_zcal = true;
const bool ref_b4_sref_en = false;
const u32 tZQCAL_lpddr4 = 1000000;
const bool opt_short_zcal = true;
const bool opt_do_sw_qrst = true;
const u32 opt_dvfs_mode = MAN_SR;
/*
* This is the timing table for the source frequency. It does _not_
* necessarily correspond to the actual timing values in the EMC at the
* moment. If the boot BCT differs from the table then this can happen.
* However, we need it for accessing the dram_timings (which are not
* really registers) array for the current frequency.
*/
struct tegra210_emc_timing *fake, *last = emc->last, *next = emc->next;
u32 tRTM, RP_war, R2P_war, TRPab_war, deltaTWATM, W2P_war, tRPST;
u32 mr13_flip_fspwr, mr13_flip_fspop, ramp_up_wait, ramp_down_wait;
u32 zq_wait_long, zq_latch_dvfs_wait_time, tZQCAL_lpddr4_fc_adj;
u32 emc_auto_cal_config, auto_cal_en, emc_cfg, emc_sel_dpd_ctrl;
u32 tFC_lpddr4 = 1000 * next->dram_timings[T_FC_LPDDR4];
u32 bg_reg_mode_change, enable_bglp_reg, enable_bg_reg;
bool opt_zcal_en_cc = false, is_lpddr3 = false;
bool compensate_trimmer_applicable = false;
u32 emc_dbg, emc_cfg_pipe_clk, emc_pin;
u32 src_clk_period, dst_clk_period; /* in picoseconds */
bool shared_zq_resistor = false;
u32 value, dram_type;
u32 opt_dll_mode = 0;
unsigned long delay;
unsigned int i;
emc_dbg(emc, INFO, "Running clock change.\n");
/* XXX fake == last */
fake = tegra210_emc_find_timing(emc, last->rate * 1000UL);
fsp_for_next_freq = !fsp_for_next_freq;
value = emc_readl(emc, EMC_FBIO_CFG5) & EMC_FBIO_CFG5_DRAM_TYPE_MASK;
dram_type = value >> EMC_FBIO_CFG5_DRAM_TYPE_SHIFT;
if (last->burst_regs[EMC_ZCAL_WAIT_CNT_INDEX] & BIT(31))
shared_zq_resistor = true;
if ((next->burst_regs[EMC_ZCAL_INTERVAL_INDEX] != 0 &&
last->burst_regs[EMC_ZCAL_INTERVAL_INDEX] == 0) ||
dram_type == DRAM_TYPE_LPDDR4)
opt_zcal_en_cc = true;
if (dram_type == DRAM_TYPE_DDR3)
opt_dll_mode = tegra210_emc_get_dll_state(next);
if ((next->burst_regs[EMC_FBIO_CFG5_INDEX] & BIT(25)) &&
(dram_type == DRAM_TYPE_LPDDR2))
is_lpddr3 = true;
emc_readl(emc, EMC_CFG);
emc_readl(emc, EMC_AUTO_CAL_CONFIG);
src_clk_period = 1000000000 / last->rate;
dst_clk_period = 1000000000 / next->rate;
if (dst_clk_period <= zqcal_before_cc_cutoff)
tZQCAL_lpddr4_fc_adj = tZQCAL_lpddr4 - tFC_lpddr4;
else
tZQCAL_lpddr4_fc_adj = tZQCAL_lpddr4;
tZQCAL_lpddr4_fc_adj /= dst_clk_period;
emc_dbg = emc_readl(emc, EMC_DBG);
emc_pin = emc_readl(emc, EMC_PIN);
emc_cfg_pipe_clk = emc_readl(emc, EMC_CFG_PIPE_CLK);
emc_cfg = next->burst_regs[EMC_CFG_INDEX];
emc_cfg &= ~(EMC_CFG_DYN_SELF_REF | EMC_CFG_DRAM_ACPD |
EMC_CFG_DRAM_CLKSTOP_SR | EMC_CFG_DRAM_CLKSTOP_PD);
emc_sel_dpd_ctrl = next->emc_sel_dpd_ctrl;
emc_sel_dpd_ctrl &= ~(EMC_SEL_DPD_CTRL_CLK_SEL_DPD_EN |
EMC_SEL_DPD_CTRL_CA_SEL_DPD_EN |
EMC_SEL_DPD_CTRL_RESET_SEL_DPD_EN |
EMC_SEL_DPD_CTRL_ODT_SEL_DPD_EN |
EMC_SEL_DPD_CTRL_DATA_SEL_DPD_EN);
emc_dbg(emc, INFO, "Clock change version: %d\n",
DVFS_CLOCK_CHANGE_VERSION);
emc_dbg(emc, INFO, "DRAM type = %d\n", dram_type);
emc_dbg(emc, INFO, "DRAM dev #: %u\n", emc->num_devices);
emc_dbg(emc, INFO, "Next EMC clksrc: 0x%08x\n", clksrc);
emc_dbg(emc, INFO, "DLL clksrc: 0x%08x\n", next->dll_clk_src);
emc_dbg(emc, INFO, "last rate: %u, next rate %u\n", last->rate,
next->rate);
emc_dbg(emc, INFO, "last period: %u, next period: %u\n",
src_clk_period, dst_clk_period);
emc_dbg(emc, INFO, " shared_zq_resistor: %d\n", !!shared_zq_resistor);
emc_dbg(emc, INFO, " num_channels: %u\n", emc->num_channels);
emc_dbg(emc, INFO, " opt_dll_mode: %d\n", opt_dll_mode);
/*
* Step 1:
* Pre DVFS SW sequence.
*/
emc_dbg(emc, STEPS, "Step 1\n");
emc_dbg(emc, STEPS, "Step 1.1: Disable DLL temporarily.\n");
value = emc_readl(emc, EMC_CFG_DIG_DLL);
value &= ~EMC_CFG_DIG_DLL_CFG_DLL_EN;
emc_writel(emc, value, EMC_CFG_DIG_DLL);
tegra210_emc_timing_update(emc);
for (i = 0; i < emc->num_channels; i++)
tegra210_emc_wait_for_update(emc, i, EMC_CFG_DIG_DLL,
EMC_CFG_DIG_DLL_CFG_DLL_EN, 0);
emc_dbg(emc, STEPS, "Step 1.2: Disable AUTOCAL temporarily.\n");
emc_auto_cal_config = next->emc_auto_cal_config;
auto_cal_en = emc_auto_cal_config & EMC_AUTO_CAL_CONFIG_AUTO_CAL_ENABLE;
emc_auto_cal_config &= ~EMC_AUTO_CAL_CONFIG_AUTO_CAL_START;
emc_auto_cal_config |= EMC_AUTO_CAL_CONFIG_AUTO_CAL_MEASURE_STALL;
emc_auto_cal_config |= EMC_AUTO_CAL_CONFIG_AUTO_CAL_UPDATE_STALL;
emc_auto_cal_config |= auto_cal_en;
emc_writel(emc, emc_auto_cal_config, EMC_AUTO_CAL_CONFIG);
emc_readl(emc, EMC_AUTO_CAL_CONFIG); /* Flush write. */
emc_dbg(emc, STEPS, "Step 1.3: Disable other power features.\n");
tegra210_emc_set_shadow_bypass(emc, ACTIVE);
emc_writel(emc, emc_cfg, EMC_CFG);
emc_writel(emc, emc_sel_dpd_ctrl, EMC_SEL_DPD_CTRL);
tegra210_emc_set_shadow_bypass(emc, ASSEMBLY);
if (next->periodic_training) {
tegra210_emc_reset_dram_clktree_values(next);
for (i = 0; i < emc->num_channels; i++)
tegra210_emc_wait_for_update(emc, i, EMC_EMC_STATUS,
EMC_EMC_STATUS_DRAM_IN_POWERDOWN_MASK,
0);
for (i = 0; i < emc->num_channels; i++)
tegra210_emc_wait_for_update(emc, i, EMC_EMC_STATUS,
EMC_EMC_STATUS_DRAM_IN_SELF_REFRESH_MASK,
0);
tegra210_emc_start_periodic_compensation(emc);
delay = 1000 * tegra210_emc_actual_osc_clocks(last->run_clocks);
udelay((delay / last->rate) + 2);
value = periodic_compensation_handler(emc, DVFS_SEQUENCE, fake,
next);
value = (value * 128 * next->rate / 1000) / 1000000;
if (next->periodic_training && value > next->tree_margin)
compensate_trimmer_applicable = true;
}
emc_writel(emc, EMC_INTSTATUS_CLKCHANGE_COMPLETE, EMC_INTSTATUS);
tegra210_emc_set_shadow_bypass(emc, ACTIVE);
emc_writel(emc, emc_cfg, EMC_CFG);
emc_writel(emc, emc_sel_dpd_ctrl, EMC_SEL_DPD_CTRL);
emc_writel(emc, emc_cfg_pipe_clk | EMC_CFG_PIPE_CLK_CLK_ALWAYS_ON,
EMC_CFG_PIPE_CLK);
emc_writel(emc, next->emc_fdpd_ctrl_cmd_no_ramp &
~EMC_FDPD_CTRL_CMD_NO_RAMP_CMD_DPD_NO_RAMP_ENABLE,
EMC_FDPD_CTRL_CMD_NO_RAMP);
bg_reg_mode_change =
((next->burst_regs[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
EMC_PMACRO_BG_BIAS_CTRL_0_BGLP_E_PWRD) ^
(last->burst_regs[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
EMC_PMACRO_BG_BIAS_CTRL_0_BGLP_E_PWRD)) ||
((next->burst_regs[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
EMC_PMACRO_BG_BIAS_CTRL_0_BG_E_PWRD) ^
(last->burst_regs[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
EMC_PMACRO_BG_BIAS_CTRL_0_BG_E_PWRD));
enable_bglp_reg =
(next->burst_regs[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
EMC_PMACRO_BG_BIAS_CTRL_0_BGLP_E_PWRD) == 0;
enable_bg_reg =
(next->burst_regs[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
EMC_PMACRO_BG_BIAS_CTRL_0_BG_E_PWRD) == 0;
if (bg_reg_mode_change) {
if (enable_bg_reg)
emc_writel(emc, last->burst_regs
[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
~EMC_PMACRO_BG_BIAS_CTRL_0_BG_E_PWRD,
EMC_PMACRO_BG_BIAS_CTRL_0);
if (enable_bglp_reg)
emc_writel(emc, last->burst_regs
[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
~EMC_PMACRO_BG_BIAS_CTRL_0_BGLP_E_PWRD,
EMC_PMACRO_BG_BIAS_CTRL_0);
}
/* Check if we need to turn on VREF generator. */
if ((((last->burst_regs[EMC_PMACRO_DATA_PAD_TX_CTRL_INDEX] &
EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQ_E_IVREF) == 0) &&
((next->burst_regs[EMC_PMACRO_DATA_PAD_TX_CTRL_INDEX] &
EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQ_E_IVREF) == 1)) ||
(((last->burst_regs[EMC_PMACRO_DATA_PAD_TX_CTRL_INDEX] &
EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQS_E_IVREF) == 0) &&
((next->burst_regs[EMC_PMACRO_DATA_PAD_TX_CTRL_INDEX] &
EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQS_E_IVREF) != 0))) {
u32 pad_tx_ctrl =
next->burst_regs[EMC_PMACRO_DATA_PAD_TX_CTRL_INDEX];
u32 last_pad_tx_ctrl =
last->burst_regs[EMC_PMACRO_DATA_PAD_TX_CTRL_INDEX];
u32 next_dq_e_ivref, next_dqs_e_ivref;
next_dqs_e_ivref = pad_tx_ctrl &
EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQS_E_IVREF;
next_dq_e_ivref = pad_tx_ctrl &
EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQ_E_IVREF;
value = (last_pad_tx_ctrl &
~EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQ_E_IVREF &
~EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQS_E_IVREF) |
next_dq_e_ivref | next_dqs_e_ivref;
emc_writel(emc, value, EMC_PMACRO_DATA_PAD_TX_CTRL);
udelay(1);
} else if (bg_reg_mode_change) {
udelay(1);
}
tegra210_emc_set_shadow_bypass(emc, ASSEMBLY);
/*
* Step 2:
* Prelock the DLL.
*/
emc_dbg(emc, STEPS, "Step 2\n");
if (next->burst_regs[EMC_CFG_DIG_DLL_INDEX] &
EMC_CFG_DIG_DLL_CFG_DLL_EN) {
emc_dbg(emc, INFO, "Prelock enabled for target frequency.\n");
value = tegra210_emc_dll_prelock(emc, clksrc);
emc_dbg(emc, INFO, "DLL out: 0x%03x\n", value);
} else {
emc_dbg(emc, INFO, "Disabling DLL for target frequency.\n");
tegra210_emc_dll_disable(emc);
}
/*
* Step 3:
* Prepare autocal for the clock change.
*/
emc_dbg(emc, STEPS, "Step 3\n");
tegra210_emc_set_shadow_bypass(emc, ACTIVE);
emc_writel(emc, next->emc_auto_cal_config2, EMC_AUTO_CAL_CONFIG2);
emc_writel(emc, next->emc_auto_cal_config3, EMC_AUTO_CAL_CONFIG3);
emc_writel(emc, next->emc_auto_cal_config4, EMC_AUTO_CAL_CONFIG4);
emc_writel(emc, next->emc_auto_cal_config5, EMC_AUTO_CAL_CONFIG5);
emc_writel(emc, next->emc_auto_cal_config6, EMC_AUTO_CAL_CONFIG6);
emc_writel(emc, next->emc_auto_cal_config7, EMC_AUTO_CAL_CONFIG7);
emc_writel(emc, next->emc_auto_cal_config8, EMC_AUTO_CAL_CONFIG8);
tegra210_emc_set_shadow_bypass(emc, ASSEMBLY);
emc_auto_cal_config |= (EMC_AUTO_CAL_CONFIG_AUTO_CAL_COMPUTE_START |
auto_cal_en);
emc_writel(emc, emc_auto_cal_config, EMC_AUTO_CAL_CONFIG);
/*
* Step 4:
* Update EMC_CFG. (??)
*/
emc_dbg(emc, STEPS, "Step 4\n");
if (src_clk_period > 50000 && dram_type == DRAM_TYPE_LPDDR4)
ccfifo_writel(emc, 1, EMC_SELF_REF, 0);
else
emc_writel(emc, next->emc_cfg_2, EMC_CFG_2);
/*
* Step 5:
* Prepare reference variables for ZQCAL regs.
*/
emc_dbg(emc, STEPS, "Step 5\n");
if (dram_type == DRAM_TYPE_LPDDR4)
zq_wait_long = max((u32)1, div_o3(1000000, dst_clk_period));
else if (dram_type == DRAM_TYPE_LPDDR2 || is_lpddr3)
zq_wait_long = max(next->min_mrs_wait,
div_o3(360000, dst_clk_period)) + 4;
else if (dram_type == DRAM_TYPE_DDR3)
zq_wait_long = max((u32)256,
div_o3(320000, dst_clk_period) + 2);
else
zq_wait_long = 0;
/*
* Step 6:
* Training code - removed.
*/
emc_dbg(emc, STEPS, "Step 6\n");
/*
* Step 7:
* Program FSP reference registers and send MRWs to new FSPWR.
*/
emc_dbg(emc, STEPS, "Step 7\n");
emc_dbg(emc, SUB_STEPS, "Step 7.1: Bug 200024907 - Patch RP R2P");
/* WAR 200024907 */
if (dram_type == DRAM_TYPE_LPDDR4) {
u32 nRTP = 16;
if (src_clk_period >= 1000000 / 1866) /* 535.91 ps */
nRTP = 14;
if (src_clk_period >= 1000000 / 1600) /* 625.00 ps */
nRTP = 12;
if (src_clk_period >= 1000000 / 1333) /* 750.19 ps */
nRTP = 10;
if (src_clk_period >= 1000000 / 1066) /* 938.09 ps */
nRTP = 8;
deltaTWATM = max_t(u32, div_o3(7500, src_clk_period), 8);
/*
* Originally there was a + .5 in the tRPST calculation.
* However since we can't do FP in the kernel and the tRTM
* computation was in a floating point ceiling function, adding
* one to tRTP should be ok. There is no other source of non
* integer values, so the result was always going to be
* something for the form: f_ceil(N + .5) = N + 1;
*/
tRPST = (last->emc_mrw & 0x80) >> 7;
tRTM = fake->dram_timings[RL] + div_o3(3600, src_clk_period) +
max_t(u32, div_o3(7500, src_clk_period), 8) + tRPST +
1 + nRTP;
emc_dbg(emc, INFO, "tRTM = %u, EMC_RP = %u\n", tRTM,
next->burst_regs[EMC_RP_INDEX]);
if (last->burst_regs[EMC_RP_INDEX] < tRTM) {
if (tRTM > (last->burst_regs[EMC_R2P_INDEX] +
last->burst_regs[EMC_RP_INDEX])) {
R2P_war = tRTM - last->burst_regs[EMC_RP_INDEX];
RP_war = last->burst_regs[EMC_RP_INDEX];
TRPab_war = last->burst_regs[EMC_TRPAB_INDEX];
if (R2P_war > 63) {
RP_war = R2P_war +
last->burst_regs[EMC_RP_INDEX] - 63;
if (TRPab_war < RP_war)
TRPab_war = RP_war;
R2P_war = 63;
}
} else {
R2P_war = last->burst_regs[EMC_R2P_INDEX];
RP_war = last->burst_regs[EMC_RP_INDEX];
TRPab_war = last->burst_regs[EMC_TRPAB_INDEX];
}
if (RP_war < deltaTWATM) {
W2P_war = last->burst_regs[EMC_W2P_INDEX]
+ deltaTWATM - RP_war;
if (W2P_war > 63) {
RP_war = RP_war + W2P_war - 63;
if (TRPab_war < RP_war)
TRPab_war = RP_war;
W2P_war = 63;
}
} else {
W2P_war = last->burst_regs[
EMC_W2P_INDEX];
}
if ((last->burst_regs[EMC_W2P_INDEX] ^ W2P_war) ||
(last->burst_regs[EMC_R2P_INDEX] ^ R2P_war) ||
(last->burst_regs[EMC_RP_INDEX] ^ RP_war) ||
(last->burst_regs[EMC_TRPAB_INDEX] ^ TRPab_war)) {
emc_writel(emc, RP_war, EMC_RP);
emc_writel(emc, R2P_war, EMC_R2P);
emc_writel(emc, W2P_war, EMC_W2P);
emc_writel(emc, TRPab_war, EMC_TRPAB);
}
tegra210_emc_timing_update(emc);
} else {
emc_dbg(emc, INFO, "Skipped WAR\n");
}
}
if (!fsp_for_next_freq) {
mr13_flip_fspwr = (next->emc_mrw3 & 0xffffff3f) | 0x80;
mr13_flip_fspop = (next->emc_mrw3 & 0xffffff3f) | 0x00;
} else {
mr13_flip_fspwr = (next->emc_mrw3 & 0xffffff3f) | 0x40;
mr13_flip_fspop = (next->emc_mrw3 & 0xffffff3f) | 0xc0;
}
if (dram_type == DRAM_TYPE_LPDDR4) {
emc_writel(emc, mr13_flip_fspwr, EMC_MRW3);
emc_writel(emc, next->emc_mrw, EMC_MRW);
emc_writel(emc, next->emc_mrw2, EMC_MRW2);
}
/*
* Step 8:
* Program the shadow registers.
*/
emc_dbg(emc, STEPS, "Step 8\n");
emc_dbg(emc, SUB_STEPS, "Writing burst_regs\n");
for (i = 0; i < next->num_burst; i++) {
const u16 *offsets = emc->offsets->burst;
u16 offset;
if (!offsets[i])
continue;
value = next->burst_regs[i];
offset = offsets[i];
if (dram_type != DRAM_TYPE_LPDDR4 &&
(offset == EMC_MRW6 || offset == EMC_MRW7 ||
offset == EMC_MRW8 || offset == EMC_MRW9 ||
offset == EMC_MRW10 || offset == EMC_MRW11 ||
offset == EMC_MRW12 || offset == EMC_MRW13 ||
offset == EMC_MRW14 || offset == EMC_MRW15 ||
offset == EMC_TRAINING_CTRL))
continue;
/* Pain... And suffering. */
if (offset == EMC_CFG) {
value &= ~EMC_CFG_DRAM_ACPD;
value &= ~EMC_CFG_DYN_SELF_REF;
if (dram_type == DRAM_TYPE_LPDDR4) {
value &= ~EMC_CFG_DRAM_CLKSTOP_SR;
value &= ~EMC_CFG_DRAM_CLKSTOP_PD;
}
} else if (offset == EMC_MRS_WAIT_CNT &&
dram_type == DRAM_TYPE_LPDDR2 &&
opt_zcal_en_cc && !opt_cc_short_zcal &&
opt_short_zcal) {
value = (value & ~(EMC_MRS_WAIT_CNT_SHORT_WAIT_MASK <<
EMC_MRS_WAIT_CNT_SHORT_WAIT_SHIFT)) |
((zq_wait_long & EMC_MRS_WAIT_CNT_SHORT_WAIT_MASK) <<
EMC_MRS_WAIT_CNT_SHORT_WAIT_SHIFT);
} else if (offset == EMC_ZCAL_WAIT_CNT &&
dram_type == DRAM_TYPE_DDR3 && opt_zcal_en_cc &&
!opt_cc_short_zcal && opt_short_zcal) {
value = (value & ~(EMC_ZCAL_WAIT_CNT_ZCAL_WAIT_CNT_MASK <<
EMC_ZCAL_WAIT_CNT_ZCAL_WAIT_CNT_SHIFT)) |
((zq_wait_long & EMC_ZCAL_WAIT_CNT_ZCAL_WAIT_CNT_MASK) <<
EMC_MRS_WAIT_CNT_SHORT_WAIT_SHIFT);
} else if (offset == EMC_ZCAL_INTERVAL && opt_zcal_en_cc) {
value = 0; /* EMC_ZCAL_INTERVAL reset value. */
} else if (offset == EMC_PMACRO_AUTOCAL_CFG_COMMON) {
value |= EMC_PMACRO_AUTOCAL_CFG_COMMON_E_CAL_BYPASS_DVFS;
} else if (offset == EMC_PMACRO_DATA_PAD_TX_CTRL) {
value &= ~(EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQSP_TX_E_DCC |
EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQSN_TX_E_DCC |
EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQ_TX_E_DCC |
EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_CMD_TX_E_DCC);
} else if (offset == EMC_PMACRO_CMD_PAD_TX_CTRL) {
value |= EMC_PMACRO_CMD_PAD_TX_CTRL_CMD_DQ_TX_DRVFORCEON;
value &= ~(EMC_PMACRO_CMD_PAD_TX_CTRL_CMD_DQSP_TX_E_DCC |
EMC_PMACRO_CMD_PAD_TX_CTRL_CMD_DQSN_TX_E_DCC |
EMC_PMACRO_CMD_PAD_TX_CTRL_CMD_DQ_TX_E_DCC |
EMC_PMACRO_CMD_PAD_TX_CTRL_CMD_CMD_TX_E_DCC);
} else if (offset == EMC_PMACRO_BRICK_CTRL_RFU1) {
value &= 0xf800f800;
} else if (offset == EMC_PMACRO_COMMON_PAD_TX_CTRL) {
value &= 0xfffffff0;
}
emc_writel(emc, value, offset);
}
if (dram_type == DRAM_TYPE_LPDDR4) {
value = (23 << EMC_MRW_MRW_MA_SHIFT) |
(next->run_clocks & EMC_MRW_MRW_OP_MASK);
emc_writel(emc, value, EMC_MRW);
}
/* Per channel burst registers. */
emc_dbg(emc, SUB_STEPS, "Writing burst_regs_per_ch\n");
for (i = 0; i < next->num_burst_per_ch; i++) {
const struct tegra210_emc_per_channel_regs *burst =
emc->offsets->burst_per_channel;
if (!burst[i].offset)
continue;
if (dram_type != DRAM_TYPE_LPDDR4 &&
(burst[i].offset == EMC_MRW6 ||
burst[i].offset == EMC_MRW7 ||
burst[i].offset == EMC_MRW8 ||
burst[i].offset == EMC_MRW9 ||
burst[i].offset == EMC_MRW10 ||
burst[i].offset == EMC_MRW11 ||
burst[i].offset == EMC_MRW12 ||
burst[i].offset == EMC_MRW13 ||
burst[i].offset == EMC_MRW14 ||
burst[i].offset == EMC_MRW15))
continue;
/* Filter out second channel if not in DUAL_CHANNEL mode. */
if (emc->num_channels < 2 && burst[i].bank >= 1)
continue;
emc_dbg(emc, REG_LISTS, "(%u) 0x%08x => 0x%08x\n", i,
next->burst_reg_per_ch[i], burst[i].offset);
emc_channel_writel(emc, burst[i].bank,
next->burst_reg_per_ch[i],
burst[i].offset);
}
/* Vref regs. */
emc_dbg(emc, SUB_STEPS, "Writing vref_regs\n");
for (i = 0; i < next->vref_num; i++) {
const struct tegra210_emc_per_channel_regs *vref =
emc->offsets->vref_per_channel;
if (!vref[i].offset)
continue;
if (emc->num_channels < 2 && vref[i].bank >= 1)
continue;
emc_dbg(emc, REG_LISTS, "(%u) 0x%08x => 0x%08x\n", i,
next->vref_perch_regs[i], vref[i].offset);
emc_channel_writel(emc, vref[i].bank, next->vref_perch_regs[i],
vref[i].offset);
}
/* Trimmers. */
emc_dbg(emc, SUB_STEPS, "Writing trim_regs\n");
for (i = 0; i < next->num_trim; i++) {
const u16 *offsets = emc->offsets->trim;
if (!offsets[i])
continue;
if (compensate_trimmer_applicable &&
(offsets[i] == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_0 ||
offsets[i] == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_1 ||
offsets[i] == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_2 ||
offsets[i] == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_3 ||
offsets[i] == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_0 ||
offsets[i] == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_1 ||
offsets[i] == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_2 ||
offsets[i] == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_3 ||
offsets[i] == EMC_DATA_BRLSHFT_0 ||
offsets[i] == EMC_DATA_BRLSHFT_1)) {
value = tegra210_emc_compensate(next, offsets[i]);
emc_dbg(emc, REG_LISTS, "(%u) 0x%08x => 0x%08x\n", i,
value, offsets[i]);
emc_dbg(emc, EMA_WRITES, "0x%08x <= 0x%08x\n",
(u32)(u64)offsets[i], value);
emc_writel(emc, value, offsets[i]);
} else {
emc_dbg(emc, REG_LISTS, "(%u) 0x%08x => 0x%08x\n", i,
next->trim_regs[i], offsets[i]);
emc_writel(emc, next->trim_regs[i], offsets[i]);
}
}
/* Per channel trimmers. */
emc_dbg(emc, SUB_STEPS, "Writing trim_regs_per_ch\n");
for (i = 0; i < next->num_trim_per_ch; i++) {
const struct tegra210_emc_per_channel_regs *trim =
&emc->offsets->trim_per_channel[0];
unsigned int offset;
if (!trim[i].offset)
continue;
if (emc->num_channels < 2 && trim[i].bank >= 1)
continue;
offset = trim[i].offset;
if (compensate_trimmer_applicable &&
(offset == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_0 ||
offset == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_1 ||
offset == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_2 ||
offset == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_3 ||
offset == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_0 ||
offset == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_1 ||
offset == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_2 ||
offset == EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_3 ||
offset == EMC_DATA_BRLSHFT_0 ||
offset == EMC_DATA_BRLSHFT_1)) {
value = tegra210_emc_compensate(next, offset);
emc_dbg(emc, REG_LISTS, "(%u) 0x%08x => 0x%08x\n", i,
value, offset);
emc_dbg(emc, EMA_WRITES, "0x%08x <= 0x%08x\n", offset,
value);
emc_channel_writel(emc, trim[i].bank, value, offset);
} else {
emc_dbg(emc, REG_LISTS, "(%u) 0x%08x => 0x%08x\n", i,
next->trim_perch_regs[i], offset);
emc_channel_writel(emc, trim[i].bank,
next->trim_perch_regs[i], offset);
}
}
emc_dbg(emc, SUB_STEPS, "Writing burst_mc_regs\n");
for (i = 0; i < next->num_mc_regs; i++) {
const u16 *offsets = emc->offsets->burst_mc;
u32 *values = next->burst_mc_regs;
emc_dbg(emc, REG_LISTS, "(%u) 0x%08x => 0x%08x\n", i,
values[i], offsets[i]);
mc_writel(emc->mc, values[i], offsets[i]);
}
/* Registers to be programmed on the faster clock. */
if (next->rate < last->rate) {
const u16 *la = emc->offsets->la_scale;
emc_dbg(emc, SUB_STEPS, "Writing la_scale_regs\n");
for (i = 0; i < next->num_up_down; i++) {
emc_dbg(emc, REG_LISTS, "(%u) 0x%08x => 0x%08x\n", i,
next->la_scale_regs[i], la[i]);
mc_writel(emc->mc, next->la_scale_regs[i], la[i]);
}
}
/* Flush all the burst register writes. */
mc_readl(emc->mc, MC_EMEM_ADR_CFG);
/*
* Step 9:
* LPDDR4 section A.
*/
emc_dbg(emc, STEPS, "Step 9\n");
value = next->burst_regs[EMC_ZCAL_WAIT_CNT_INDEX];
value &= ~EMC_ZCAL_WAIT_CNT_ZCAL_WAIT_CNT_MASK;
if (dram_type == DRAM_TYPE_LPDDR4) {
emc_writel(emc, 0, EMC_ZCAL_INTERVAL);
emc_writel(emc, value, EMC_ZCAL_WAIT_CNT);
value = emc_dbg | (EMC_DBG_WRITE_MUX_ACTIVE |
EMC_DBG_WRITE_ACTIVE_ONLY);
emc_writel(emc, value, EMC_DBG);
emc_writel(emc, 0, EMC_ZCAL_INTERVAL);
emc_writel(emc, emc_dbg, EMC_DBG);
}
/*
* Step 10:
* LPDDR4 and DDR3 common section.
*/
emc_dbg(emc, STEPS, "Step 10\n");
if (opt_dvfs_mode == MAN_SR || dram_type == DRAM_TYPE_LPDDR4) {
if (dram_type == DRAM_TYPE_LPDDR4)
ccfifo_writel(emc, 0x101, EMC_SELF_REF, 0);
else
ccfifo_writel(emc, 0x1, EMC_SELF_REF, 0);
if (dram_type == DRAM_TYPE_LPDDR4 &&
dst_clk_period <= zqcal_before_cc_cutoff) {
ccfifo_writel(emc, mr13_flip_fspwr ^ 0x40, EMC_MRW3, 0);
ccfifo_writel(emc, (next->burst_regs[EMC_MRW6_INDEX] &
0xFFFF3F3F) |
(last->burst_regs[EMC_MRW6_INDEX] &
0x0000C0C0), EMC_MRW6, 0);
ccfifo_writel(emc, (next->burst_regs[EMC_MRW14_INDEX] &
0xFFFF0707) |
(last->burst_regs[EMC_MRW14_INDEX] &
0x00003838), EMC_MRW14, 0);
if (emc->num_devices > 1) {
ccfifo_writel(emc,
(next->burst_regs[EMC_MRW7_INDEX] &
0xFFFF3F3F) |
(last->burst_regs[EMC_MRW7_INDEX] &
0x0000C0C0), EMC_MRW7, 0);
ccfifo_writel(emc,
(next->burst_regs[EMC_MRW15_INDEX] &
0xFFFF0707) |
(last->burst_regs[EMC_MRW15_INDEX] &
0x00003838), EMC_MRW15, 0);
}
if (opt_zcal_en_cc) {
if (emc->num_devices < 2)
ccfifo_writel(emc,
2UL << EMC_ZQ_CAL_DEV_SEL_SHIFT
| EMC_ZQ_CAL_ZQ_CAL_CMD,
EMC_ZQ_CAL, 0);
else if (shared_zq_resistor)
ccfifo_writel(emc,
2UL << EMC_ZQ_CAL_DEV_SEL_SHIFT
| EMC_ZQ_CAL_ZQ_CAL_CMD,
EMC_ZQ_CAL, 0);
else
ccfifo_writel(emc,
EMC_ZQ_CAL_ZQ_CAL_CMD,
EMC_ZQ_CAL, 0);
}
}
}
if (dram_type == DRAM_TYPE_LPDDR4) {
value = (1000 * fake->dram_timings[T_RP]) / src_clk_period;
ccfifo_writel(emc, mr13_flip_fspop | 0x8, EMC_MRW3, value);
ccfifo_writel(emc, 0, 0, tFC_lpddr4 / src_clk_period);
}
if (dram_type == DRAM_TYPE_LPDDR4 || opt_dvfs_mode != MAN_SR) {
delay = 30;
if (cya_allow_ref_cc) {
delay += (1000 * fake->dram_timings[T_RP]) /
src_clk_period;
delay += 4000 * fake->dram_timings[T_RFC];
}
ccfifo_writel(emc, emc_pin & ~(EMC_PIN_PIN_CKE_PER_DEV |
EMC_PIN_PIN_CKEB |
EMC_PIN_PIN_CKE),
EMC_PIN, delay);
}
/* calculate reference delay multiplier */
value = 1;
if (ref_b4_sref_en)
value++;
if (cya_allow_ref_cc)
value++;
if (cya_issue_pc_ref)
value++;
if (dram_type != DRAM_TYPE_LPDDR4) {
delay = ((1000 * fake->dram_timings[T_RP] / src_clk_period) +
(1000 * fake->dram_timings[T_RFC] / src_clk_period));
delay = value * delay + 20;
} else {
delay = 0;
}
/*
* Step 11:
* Ramp down.
*/
emc_dbg(emc, STEPS, "Step 11\n");
ccfifo_writel(emc, 0x0, EMC_CFG_SYNC, delay);
value = emc_dbg | EMC_DBG_WRITE_MUX_ACTIVE | EMC_DBG_WRITE_ACTIVE_ONLY;
ccfifo_writel(emc, value, EMC_DBG, 0);
ramp_down_wait = tegra210_emc_dvfs_power_ramp_down(emc, src_clk_period,
0);
/*
* Step 12:
* And finally - trigger the clock change.
*/
emc_dbg(emc, STEPS, "Step 12\n");
ccfifo_writel(emc, 1, EMC_STALL_THEN_EXE_AFTER_CLKCHANGE, 0);
value &= ~EMC_DBG_WRITE_ACTIVE_ONLY;
ccfifo_writel(emc, value, EMC_DBG, 0);
/*
* Step 13:
* Ramp up.
*/
emc_dbg(emc, STEPS, "Step 13\n");
ramp_up_wait = tegra210_emc_dvfs_power_ramp_up(emc, dst_clk_period, 0);
ccfifo_writel(emc, emc_dbg, EMC_DBG, 0);
/*
* Step 14:
* Bringup CKE pins.
*/
emc_dbg(emc, STEPS, "Step 14\n");
if (dram_type == DRAM_TYPE_LPDDR4) {
value = emc_pin | EMC_PIN_PIN_CKE;
if (emc->num_devices <= 1)
value &= ~(EMC_PIN_PIN_CKEB | EMC_PIN_PIN_CKE_PER_DEV);
else
value |= EMC_PIN_PIN_CKEB | EMC_PIN_PIN_CKE_PER_DEV;
ccfifo_writel(emc, value, EMC_PIN, 0);
}
/*
* Step 15: (two step 15s ??)
* Calculate zqlatch wait time; has dependency on ramping times.
*/
emc_dbg(emc, STEPS, "Step 15\n");
if (dst_clk_period <= zqcal_before_cc_cutoff) {
s32 t = (s32)(ramp_up_wait + ramp_down_wait) /
(s32)dst_clk_period;
zq_latch_dvfs_wait_time = (s32)tZQCAL_lpddr4_fc_adj - t;
} else {
zq_latch_dvfs_wait_time = tZQCAL_lpddr4_fc_adj -
div_o3(1000 * next->dram_timings[T_PDEX],
dst_clk_period);
}
emc_dbg(emc, INFO, "tZQCAL_lpddr4_fc_adj = %u\n", tZQCAL_lpddr4_fc_adj);
emc_dbg(emc, INFO, "dst_clk_period = %u\n",
dst_clk_period);
emc_dbg(emc, INFO, "next->dram_timings[T_PDEX] = %u\n",
next->dram_timings[T_PDEX]);
emc_dbg(emc, INFO, "zq_latch_dvfs_wait_time = %d\n",
max_t(s32, 0, zq_latch_dvfs_wait_time));
if (dram_type == DRAM_TYPE_LPDDR4 && opt_zcal_en_cc) {
delay = div_o3(1000 * next->dram_timings[T_PDEX],
dst_clk_period);
if (emc->num_devices < 2) {
if (dst_clk_period > zqcal_before_cc_cutoff)
ccfifo_writel(emc,
2UL << EMC_ZQ_CAL_DEV_SEL_SHIFT |
EMC_ZQ_CAL_ZQ_CAL_CMD, EMC_ZQ_CAL,
delay);
value = (mr13_flip_fspop & 0xfffffff7) | 0x0c000000;
ccfifo_writel(emc, value, EMC_MRW3, delay);
ccfifo_writel(emc, 0, EMC_SELF_REF, 0);
ccfifo_writel(emc, 0, EMC_REF, 0);
ccfifo_writel(emc, 2UL << EMC_ZQ_CAL_DEV_SEL_SHIFT |
EMC_ZQ_CAL_ZQ_LATCH_CMD,
EMC_ZQ_CAL,
max_t(s32, 0, zq_latch_dvfs_wait_time));
} else if (shared_zq_resistor) {
if (dst_clk_period > zqcal_before_cc_cutoff)
ccfifo_writel(emc,
2UL << EMC_ZQ_CAL_DEV_SEL_SHIFT |
EMC_ZQ_CAL_ZQ_CAL_CMD, EMC_ZQ_CAL,
delay);
ccfifo_writel(emc, 2UL << EMC_ZQ_CAL_DEV_SEL_SHIFT |
EMC_ZQ_CAL_ZQ_LATCH_CMD, EMC_ZQ_CAL,
max_t(s32, 0, zq_latch_dvfs_wait_time) +
delay);
ccfifo_writel(emc, 1UL << EMC_ZQ_CAL_DEV_SEL_SHIFT |
EMC_ZQ_CAL_ZQ_LATCH_CMD,
EMC_ZQ_CAL, 0);
value = (mr13_flip_fspop & 0xfffffff7) | 0x0c000000;
ccfifo_writel(emc, value, EMC_MRW3, 0);
ccfifo_writel(emc, 0, EMC_SELF_REF, 0);
ccfifo_writel(emc, 0, EMC_REF, 0);
ccfifo_writel(emc, 1UL << EMC_ZQ_CAL_DEV_SEL_SHIFT |
EMC_ZQ_CAL_ZQ_LATCH_CMD, EMC_ZQ_CAL,
tZQCAL_lpddr4 / dst_clk_period);
} else {
if (dst_clk_period > zqcal_before_cc_cutoff)
ccfifo_writel(emc, EMC_ZQ_CAL_ZQ_CAL_CMD,
EMC_ZQ_CAL, delay);
value = (mr13_flip_fspop & 0xfffffff7) | 0x0c000000;
ccfifo_writel(emc, value, EMC_MRW3, delay);
ccfifo_writel(emc, 0, EMC_SELF_REF, 0);
ccfifo_writel(emc, 0, EMC_REF, 0);
ccfifo_writel(emc, EMC_ZQ_CAL_ZQ_LATCH_CMD, EMC_ZQ_CAL,
max_t(s32, 0, zq_latch_dvfs_wait_time));
}
}
/* WAR: delay for zqlatch */
ccfifo_writel(emc, 0, 0, 10);
/*
* Step 16:
* LPDDR4 Conditional Training Kickoff. Removed.
*/
/*
* Step 17:
* MANSR exit self refresh.
*/
emc_dbg(emc, STEPS, "Step 17\n");
if (opt_dvfs_mode == MAN_SR && dram_type != DRAM_TYPE_LPDDR4)
ccfifo_writel(emc, 0, EMC_SELF_REF, 0);
/*
* Step 18:
* Send MRWs to LPDDR3/DDR3.
*/
emc_dbg(emc, STEPS, "Step 18\n");
if (dram_type == DRAM_TYPE_LPDDR2) {
ccfifo_writel(emc, next->emc_mrw2, EMC_MRW2, 0);
ccfifo_writel(emc, next->emc_mrw, EMC_MRW, 0);
if (is_lpddr3)
ccfifo_writel(emc, next->emc_mrw4, EMC_MRW4, 0);
} else if (dram_type == DRAM_TYPE_DDR3) {
if (opt_dll_mode)
ccfifo_writel(emc, next->emc_emrs &
~EMC_EMRS_USE_EMRS_LONG_CNT, EMC_EMRS, 0);
ccfifo_writel(emc, next->emc_emrs2 &
~EMC_EMRS2_USE_EMRS2_LONG_CNT, EMC_EMRS2, 0);
ccfifo_writel(emc, next->emc_mrs |
EMC_EMRS_USE_EMRS_LONG_CNT, EMC_MRS, 0);
}
/*
* Step 19:
* ZQCAL for LPDDR3/DDR3
*/
emc_dbg(emc, STEPS, "Step 19\n");
if (opt_zcal_en_cc) {
if (dram_type == DRAM_TYPE_LPDDR2) {
value = opt_cc_short_zcal ? 90000 : 360000;
value = div_o3(value, dst_clk_period);
value = value <<
EMC_MRS_WAIT_CNT2_MRS_EXT2_WAIT_CNT_SHIFT |
value <<
EMC_MRS_WAIT_CNT2_MRS_EXT1_WAIT_CNT_SHIFT;
ccfifo_writel(emc, value, EMC_MRS_WAIT_CNT2, 0);
value = opt_cc_short_zcal ? 0x56 : 0xab;
ccfifo_writel(emc, 2 << EMC_MRW_MRW_DEV_SELECTN_SHIFT |
EMC_MRW_USE_MRW_EXT_CNT |
10 << EMC_MRW_MRW_MA_SHIFT |
value << EMC_MRW_MRW_OP_SHIFT,
EMC_MRW, 0);
if (emc->num_devices > 1) {
value = 1 << EMC_MRW_MRW_DEV_SELECTN_SHIFT |
EMC_MRW_USE_MRW_EXT_CNT |
10 << EMC_MRW_MRW_MA_SHIFT |
value << EMC_MRW_MRW_OP_SHIFT;
ccfifo_writel(emc, value, EMC_MRW, 0);
}
} else if (dram_type == DRAM_TYPE_DDR3) {
value = opt_cc_short_zcal ? 0 : EMC_ZQ_CAL_LONG;
ccfifo_writel(emc, value |
2 << EMC_ZQ_CAL_DEV_SEL_SHIFT |
EMC_ZQ_CAL_ZQ_CAL_CMD, EMC_ZQ_CAL,
0);
if (emc->num_devices > 1) {
value = value | 1 << EMC_ZQ_CAL_DEV_SEL_SHIFT |
EMC_ZQ_CAL_ZQ_CAL_CMD;
ccfifo_writel(emc, value, EMC_ZQ_CAL, 0);
}
}
}
if (bg_reg_mode_change) {
tegra210_emc_set_shadow_bypass(emc, ACTIVE);
if (ramp_up_wait <= 1250000)
delay = (1250000 - ramp_up_wait) / dst_clk_period;
else
delay = 0;
ccfifo_writel(emc,
next->burst_regs[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX],
EMC_PMACRO_BG_BIAS_CTRL_0, delay);
tegra210_emc_set_shadow_bypass(emc, ASSEMBLY);
}
/*
* Step 20:
* Issue ref and optional QRST.
*/
emc_dbg(emc, STEPS, "Step 20\n");
if (dram_type != DRAM_TYPE_LPDDR4)
ccfifo_writel(emc, 0, EMC_REF, 0);
if (opt_do_sw_qrst) {
ccfifo_writel(emc, 1, EMC_ISSUE_QRST, 0);
ccfifo_writel(emc, 0, EMC_ISSUE_QRST, 2);
}
/*
* Step 21:
* Restore ZCAL and ZCAL interval.
*/
emc_dbg(emc, STEPS, "Step 21\n");
if (save_restore_clkstop_pd || opt_zcal_en_cc) {
ccfifo_writel(emc, emc_dbg | EMC_DBG_WRITE_MUX_ACTIVE,
EMC_DBG, 0);
if (opt_zcal_en_cc && dram_type != DRAM_TYPE_LPDDR4)
ccfifo_writel(emc, next->burst_regs[EMC_ZCAL_INTERVAL_INDEX],
EMC_ZCAL_INTERVAL, 0);
if (save_restore_clkstop_pd)
ccfifo_writel(emc, next->burst_regs[EMC_CFG_INDEX] &
~EMC_CFG_DYN_SELF_REF,
EMC_CFG, 0);
ccfifo_writel(emc, emc_dbg, EMC_DBG, 0);
}
/*
* Step 22:
* Restore EMC_CFG_PIPE_CLK.
*/
emc_dbg(emc, STEPS, "Step 22\n");
ccfifo_writel(emc, emc_cfg_pipe_clk, EMC_CFG_PIPE_CLK, 0);
if (bg_reg_mode_change) {
if (enable_bg_reg)
emc_writel(emc,
next->burst_regs[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
~EMC_PMACRO_BG_BIAS_CTRL_0_BGLP_E_PWRD,
EMC_PMACRO_BG_BIAS_CTRL_0);
else
emc_writel(emc,
next->burst_regs[EMC_PMACRO_BG_BIAS_CTRL_0_INDEX] &
~EMC_PMACRO_BG_BIAS_CTRL_0_BG_E_PWRD,
EMC_PMACRO_BG_BIAS_CTRL_0);
}
/*
* Step 23:
*/
emc_dbg(emc, STEPS, "Step 23\n");
value = emc_readl(emc, EMC_CFG_DIG_DLL);
value |= EMC_CFG_DIG_DLL_CFG_DLL_STALL_ALL_TRAFFIC;
value &= ~EMC_CFG_DIG_DLL_CFG_DLL_STALL_RW_UNTIL_LOCK;
value &= ~EMC_CFG_DIG_DLL_CFG_DLL_STALL_ALL_UNTIL_LOCK;
value &= ~EMC_CFG_DIG_DLL_CFG_DLL_EN;
value = (value & ~EMC_CFG_DIG_DLL_CFG_DLL_MODE_MASK) |
(2 << EMC_CFG_DIG_DLL_CFG_DLL_MODE_SHIFT);
emc_writel(emc, value, EMC_CFG_DIG_DLL);
tegra210_emc_do_clock_change(emc, clksrc);
/*
* Step 24:
* Save training results. Removed.
*/
/*
* Step 25:
* Program MC updown registers.
*/
emc_dbg(emc, STEPS, "Step 25\n");
if (next->rate > last->rate) {
for (i = 0; i < next->num_up_down; i++)
mc_writel(emc->mc, next->la_scale_regs[i],
emc->offsets->la_scale[i]);
tegra210_emc_timing_update(emc);
}
/*
* Step 26:
* Restore ZCAL registers.
*/
emc_dbg(emc, STEPS, "Step 26\n");
if (dram_type == DRAM_TYPE_LPDDR4) {
tegra210_emc_set_shadow_bypass(emc, ACTIVE);
emc_writel(emc, next->burst_regs[EMC_ZCAL_WAIT_CNT_INDEX],
EMC_ZCAL_WAIT_CNT);
emc_writel(emc, next->burst_regs[EMC_ZCAL_INTERVAL_INDEX],
EMC_ZCAL_INTERVAL);
tegra210_emc_set_shadow_bypass(emc, ASSEMBLY);
}
if (dram_type != DRAM_TYPE_LPDDR4 && opt_zcal_en_cc &&
!opt_short_zcal && opt_cc_short_zcal) {
udelay(2);
tegra210_emc_set_shadow_bypass(emc, ACTIVE);
if (dram_type == DRAM_TYPE_LPDDR2)
emc_writel(emc, next->burst_regs[EMC_MRS_WAIT_CNT_INDEX],
EMC_MRS_WAIT_CNT);
else if (dram_type == DRAM_TYPE_DDR3)
emc_writel(emc, next->burst_regs[EMC_ZCAL_WAIT_CNT_INDEX],
EMC_ZCAL_WAIT_CNT);
tegra210_emc_set_shadow_bypass(emc, ASSEMBLY);
}
/*
* Step 27:
* Restore EMC_CFG, FDPD registers.
*/
emc_dbg(emc, STEPS, "Step 27\n");
tegra210_emc_set_shadow_bypass(emc, ACTIVE);
emc_writel(emc, next->burst_regs[EMC_CFG_INDEX], EMC_CFG);
tegra210_emc_set_shadow_bypass(emc, ASSEMBLY);
emc_writel(emc, next->emc_fdpd_ctrl_cmd_no_ramp,
EMC_FDPD_CTRL_CMD_NO_RAMP);
emc_writel(emc, next->emc_sel_dpd_ctrl, EMC_SEL_DPD_CTRL);
/*
* Step 28:
* Training recover. Removed.
*/
emc_dbg(emc, STEPS, "Step 28\n");
tegra210_emc_set_shadow_bypass(emc, ACTIVE);
emc_writel(emc,
next->burst_regs[EMC_PMACRO_AUTOCAL_CFG_COMMON_INDEX],
EMC_PMACRO_AUTOCAL_CFG_COMMON);
tegra210_emc_set_shadow_bypass(emc, ASSEMBLY);
/*
* Step 29:
* Power fix WAR.
*/
emc_dbg(emc, STEPS, "Step 29\n");
emc_writel(emc, EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE0 |
EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE1 |
EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE2 |
EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE3 |
EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE4 |
EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE5 |
EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE6 |
EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE7,
EMC_PMACRO_CFG_PM_GLOBAL_0);
emc_writel(emc, EMC_PMACRO_TRAINING_CTRL_0_CH0_TRAINING_E_WRPTR,
EMC_PMACRO_TRAINING_CTRL_0);
emc_writel(emc, EMC_PMACRO_TRAINING_CTRL_1_CH1_TRAINING_E_WRPTR,
EMC_PMACRO_TRAINING_CTRL_1);
emc_writel(emc, 0, EMC_PMACRO_CFG_PM_GLOBAL_0);
/*
* Step 30:
* Re-enable autocal.
*/
emc_dbg(emc, STEPS, "Step 30: Re-enable DLL and AUTOCAL\n");
if (next->burst_regs[EMC_CFG_DIG_DLL_INDEX] & EMC_CFG_DIG_DLL_CFG_DLL_EN) {
value = emc_readl(emc, EMC_CFG_DIG_DLL);
value |= EMC_CFG_DIG_DLL_CFG_DLL_STALL_ALL_TRAFFIC;
value |= EMC_CFG_DIG_DLL_CFG_DLL_EN;
value &= ~EMC_CFG_DIG_DLL_CFG_DLL_STALL_RW_UNTIL_LOCK;
value &= ~EMC_CFG_DIG_DLL_CFG_DLL_STALL_ALL_UNTIL_LOCK;
value = (value & ~EMC_CFG_DIG_DLL_CFG_DLL_MODE_MASK) |
(2 << EMC_CFG_DIG_DLL_CFG_DLL_MODE_SHIFT);
emc_writel(emc, value, EMC_CFG_DIG_DLL);
tegra210_emc_timing_update(emc);
}
emc_writel(emc, next->emc_auto_cal_config, EMC_AUTO_CAL_CONFIG);
/* Done! Yay. */
}
const struct tegra210_emc_sequence tegra210_emc_r21021 = {
.revision = 0x7,
.set_clock = tegra210_emc_r21021_set_clock,
.periodic_compensation = tegra210_emc_r21021_periodic_compensation,
};
......@@ -84,6 +84,7 @@
(((value) & 0xffff0000) | ((value) & 0xffff) * (speedup))
static const struct tegra210_emc_sequence *tegra210_emc_sequences[] = {
&tegra210_emc_r21021,
};
static const struct tegra210_emc_table_register_offsets
......
......@@ -23,7 +23,16 @@
#define EMC_INTSTATUS_CLKCHANGE_COMPLETE BIT(4)
#define EMC_DBG 0x8
#define EMC_DBG_WRITE_MUX_ACTIVE BIT(1)
#define EMC_DBG_WRITE_ACTIVE_ONLY BIT(30)
#define EMC_CFG 0xc
#define EMC_CFG_DRAM_CLKSTOP_PD BIT(31)
#define EMC_CFG_DRAM_CLKSTOP_SR BIT(30)
#define EMC_CFG_DRAM_ACPD BIT(29)
#define EMC_CFG_DYN_SELF_REF BIT(28)
#define EMC_PIN 0x24
#define EMC_PIN_PIN_CKE BIT(0)
#define EMC_PIN_PIN_CKEB BIT(1)
#define EMC_PIN_PIN_CKE_PER_DEV BIT(2)
#define EMC_TIMING_CONTROL 0x28
#define EMC_RC 0x2c
#define EMC_RFC 0x30
......@@ -63,6 +72,8 @@
#define EMC_WEXT 0xb8
#define EMC_RFC_SLR 0xc0
#define EMC_MRS_WAIT_CNT2 0xc4
#define EMC_MRS_WAIT_CNT2_MRS_EXT2_WAIT_CNT_SHIFT 16
#define EMC_MRS_WAIT_CNT2_MRS_EXT1_WAIT_CNT_SHIFT 0
#define EMC_MRS_WAIT_CNT 0xc8
#define EMC_MRS_WAIT_CNT_SHORT_WAIT_SHIFT 0
#define EMC_MRS_WAIT_CNT_SHORT_WAIT_MASK \
......@@ -99,15 +110,34 @@
#define EMC_PDEX2CKE 0x118
#define EMC_CKE2PDEN 0x11c
#define EMC_MPC 0x128
#define EMC_EMRS2 0x12c
#define EMC_EMRS2_USE_EMRS2_LONG_CNT BIT(26)
#define EMC_MRW2 0x134
#define EMC_MRW3 0x138
#define EMC_MRW4 0x13c
#define EMC_R2R 0x144
#define EMC_EINPUT 0x14c
#define EMC_EINPUT_DURATION 0x150
#define EMC_PUTERM_EXTRA 0x154
#define EMC_TCKESR 0x158
#define EMC_TPD 0x15c
#define EMC_AUTO_CAL_CONFIG 0x2a4
#define EMC_AUTO_CAL_CONFIG_AUTO_CAL_COMPUTE_START BIT(0)
#define EMC_AUTO_CAL_CONFIG_AUTO_CAL_MEASURE_STALL BIT(9)
#define EMC_AUTO_CAL_CONFIG_AUTO_CAL_UPDATE_STALL BIT(10)
#define EMC_AUTO_CAL_CONFIG_AUTO_CAL_ENABLE BIT(29)
#define EMC_AUTO_CAL_CONFIG_AUTO_CAL_START BIT(31)
#define EMC_EMC_STATUS 0x2b4
#define EMC_EMC_STATUS_MRR_DIVLD BIT(20)
#define EMC_EMC_STATUS_TIMING_UPDATE_STALLED BIT(23)
#define EMC_EMC_STATUS_DRAM_IN_POWERDOWN_SHIFT 4
#define EMC_EMC_STATUS_DRAM_IN_POWERDOWN_MASK \
(0x3 << EMC_EMC_STATUS_DRAM_IN_POWERDOWN_SHIFT)
#define EMC_EMC_STATUS_DRAM_IN_SELF_REFRESH_SHIFT 8
#define EMC_EMC_STATUS_DRAM_IN_SELF_REFRESH_MASK \
(0x3 << EMC_EMC_STATUS_DRAM_IN_SELF_REFRESH_SHIFT)
#define EMC_CFG_2 0x2b8
#define EMC_CFG_DIG_DLL 0x2bc
#define EMC_CFG_DIG_DLL_CFG_DLL_EN BIT(0)
#define EMC_CFG_DIG_DLL_CFG_DLL_STALL_ALL_UNTIL_LOCK BIT(1)
......@@ -133,8 +163,17 @@
#define EMC_WDV_MASK 0x2d0
#define EMC_RDV_EARLY_MASK 0x2d4
#define EMC_RDV_EARLY 0x2d8
#define EMC_AUTO_CAL_CONFIG8 0x2dc
#define EMC_ZCAL_INTERVAL 0x2e0
#define EMC_ZCAL_WAIT_CNT 0x2e4
#define EMC_ZCAL_WAIT_CNT_ZCAL_WAIT_CNT_MASK 0x7ff
#define EMC_ZCAL_WAIT_CNT_ZCAL_WAIT_CNT_SHIFT 0
#define EMC_ZQ_CAL 0x2ec
#define EMC_ZQ_CAL_DEV_SEL_SHIFT 30
#define EMC_ZQ_CAL_LONG BIT(4)
#define EMC_ZQ_CAL_ZQ_LATCH_CMD BIT(1)
#define EMC_ZQ_CAL_ZQ_CAL_CMD BIT(0)
#define EMC_FDPD_CTRL_DQ 0x310
#define EMC_FDPD_CTRL_CMD 0x314
#define EMC_PMACRO_CMD_BRICK_CTRL_FDPD 0x318
......@@ -144,6 +183,13 @@
#define EMC_TR_TIMING_0 0x3b4
#define EMC_TR_CTRL_1 0x3bc
#define EMC_TR_RDV 0x3c4
#define EMC_STALL_THEN_EXE_AFTER_CLKCHANGE 0x3cc
#define EMC_SEL_DPD_CTRL 0x3d8
#define EMC_SEL_DPD_CTRL_DATA_SEL_DPD_EN BIT(8)
#define EMC_SEL_DPD_CTRL_ODT_SEL_DPD_EN BIT(5)
#define EMC_SEL_DPD_CTRL_RESET_SEL_DPD_EN BIT(4)
#define EMC_SEL_DPD_CTRL_CA_SEL_DPD_EN BIT(3)
#define EMC_SEL_DPD_CTRL_CLK_SEL_DPD_EN BIT(2)
#define EMC_PRE_REFRESH_REQ_CNT 0x3dc
#define EMC_DYN_SELF_REF_CONTROL 0x3e0
#define EMC_TXSRDLL 0x3e4
......@@ -156,6 +202,9 @@
#define EMC_TR_RDV_MASK 0x3f8
#define EMC_TR_QSAFE 0x3fc
#define EMC_TR_QRST 0x400
#define EMC_ISSUE_QRST 0x428
#define EMC_AUTO_CAL_CONFIG2 0x458
#define EMC_AUTO_CAL_CONFIG3 0x45c
#define EMC_TR_DVFS 0x460
#define EMC_AUTO_CAL_CHANNEL 0x464
#define EMC_IBDLY 0x468
......@@ -169,19 +218,26 @@
#define EMC_MRW6 0x4a4
#define EMC_MRW7 0x4a8
#define EMC_MRW8 0x4ac
#define EMC_MRW9 0x4b0
#define EMC_MRW10 0x4b4
#define EMC_MRW11 0x4b8
#define EMC_MRW12 0x4bc
#define EMC_MRW13 0x4c0
#define EMC_MRW14 0x4c4
#define EMC_MRW15 0x4d0
#define EMC_CFG_SYNC 0x4d4
#define EMC_FDPD_CTRL_CMD_NO_RAMP 0x4d8
#define EMC_FDPD_CTRL_CMD_NO_RAMP_CMD_DPD_NO_RAMP_ENABLE BIT(0)
#define EMC_WDV_CHK 0x4e0
#define EMC_CFG_PIPE_2 0x554
#define EMC_CFG_PIPE_CLK 0x558
#define EMC_CFG_PIPE_CLK_CLK_ALWAYS_ON BIT(0)
#define EMC_CFG_PIPE_1 0x55c
#define EMC_CFG_PIPE 0x560
#define EMC_QPOP 0x564
#define EMC_QUSE_WIDTH 0x568
#define EMC_PUTERM_WIDTH 0x56c
#define EMC_AUTO_CAL_CONFIG7 0x574
#define EMC_REFCTRL2 0x580
#define EMC_FBIO_CFG7 0x584
#define EMC_FBIO_CFG7_CH0_ENABLE BIT(1)
......@@ -246,10 +302,13 @@
#define EMC_CMD_BRLSHFT_2 0x5a4
#define EMC_CMD_BRLSHFT_3 0x5a8
#define EMC_QUSE_BRLSHFT_0 0x5ac
#define EMC_AUTO_CAL_CONFIG4 0x5b0
#define EMC_AUTO_CAL_CONFIG5 0x5b4
#define EMC_QUSE_BRLSHFT_1 0x5b8
#define EMC_QUSE_BRLSHFT_2 0x5bc
#define EMC_CCDMW 0x5c0
#define EMC_QUSE_BRLSHFT_3 0x5c4
#define EMC_AUTO_CAL_CONFIG6 0x5cc
#define EMC_DLL_CFG_0 0x5e4
#define EMC_DLL_CFG_1 0x5e8
#define EMC_DLL_CFG_1_DDLLCAL_CTRL_START_TRIM_SHIFT 10
......@@ -257,6 +316,11 @@
(0x7ff << EMC_DLL_CFG_1_DDLLCAL_CTRL_START_TRIM_SHIFT)
#define EMC_CONFIG_SAMPLE_DELAY 0x5f0
#define EMC_CFG_UPDATE 0x5f4
#define EMC_CFG_UPDATE_UPDATE_DLL_IN_UPDATE_SHIFT 9
#define EMC_CFG_UPDATE_UPDATE_DLL_IN_UPDATE_MASK \
(0x3 << EMC_CFG_UPDATE_UPDATE_DLL_IN_UPDATE_SHIFT)
#define EMC_PMACRO_QUSE_DDLL_RANK0_0 0x600
#define EMC_PMACRO_QUSE_DDLL_RANK0_1 0x604
#define EMC_PMACRO_QUSE_DDLL_RANK0_2 0x608
......@@ -565,9 +629,20 @@
#define EMC_PMACRO_DDLL_SHORT_CMD_0 0xc20
#define EMC_PMACRO_DDLL_SHORT_CMD_1 0xc24
#define EMC_PMACRO_DDLL_SHORT_CMD_2 0xc28
#define EMC_PMACRO_CFG_PM_GLOBAL_0 0xc30
#define EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE0 BIT(16)
#define EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE1 BIT(17)
#define EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE2 BIT(18)
#define EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE3 BIT(19)
#define EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE4 BIT(20)
#define EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE5 BIT(21)
#define EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE6 BIT(22)
#define EMC_PMACRO_CFG_PM_GLOBAL_0_DISABLE_CFG_BYTE7 BIT(23)
#define EMC_PMACRO_VTTGEN_CTRL_0 0xc34
#define EMC_PMACRO_VTTGEN_CTRL_1 0xc38
#define EMC_PMACRO_BG_BIAS_CTRL_0 0xc3c
#define EMC_PMACRO_BG_BIAS_CTRL_0_BG_E_PWRD BIT(0)
#define EMC_PMACRO_BG_BIAS_CTRL_0_BGLP_E_PWRD BIT(2)
#define EMC_PMACRO_PAD_CFG_CTRL 0xc40
#define EMC_PMACRO_ZCTRL 0xc44
#define EMC_PMACRO_CMD_PAD_RX_CTRL 0xc50
......@@ -582,15 +657,22 @@
#define EMC_PMACRO_CMD_PAD_TX_CTRL_CMD_DQ_TX_DRVFORCEON BIT(26)
#define EMC_PMACRO_DATA_PAD_TX_CTRL 0xc64
#define EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQ_E_IVREF BIT(0)
#define EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQ_TX_E_DCC BIT(1)
#define EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQS_E_IVREF BIT(8)
#define EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQSP_TX_E_DCC BIT(9)
#define EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_DQSN_TX_E_DCC BIT(16)
#define EMC_PMACRO_DATA_PAD_TX_CTRL_DATA_CMD_TX_E_DCC BIT(24)
#define EMC_PMACRO_COMMON_PAD_TX_CTRL 0xc68
#define EMC_PMACRO_AUTOCAL_CFG_COMMON 0xc78
#define EMC_PMACRO_AUTOCAL_CFG_COMMON_E_CAL_BYPASS_DVFS BIT(16)
#define EMC_PMACRO_VTTGEN_CTRL_2 0xcf0
#define EMC_PMACRO_IB_RXRT 0xcf4
#define EMC_PMACRO_TRAINING_CTRL_0 0xcf8
#define EMC_PMACRO_TRAINING_CTRL_0_CH0_TRAINING_E_WRPTR BIT(3)
#define EMC_PMACRO_TRAINING_CTRL_1 0xcfc
#define EMC_PMACRO_TRAINING_CTRL_1_CH1_TRAINING_E_WRPTR BIT(3)
#define EMC_TRAINING_CTRL 0xe04
#define EMC_TRAINING_QUSE_CORS_CTRL 0xe0c
#define EMC_TRAINING_QUSE_FINE_CTRL 0xe10
......@@ -616,15 +698,31 @@
#define EMC_COPY_TABLE_PARAM_TRIM_REGS BIT(1)
enum burst_regs_list {
EMC_RP_INDEX = 6,
EMC_R2P_INDEX = 9,
EMC_W2P_INDEX,
EMC_MRW6_INDEX = 31,
EMC_REFRESH_INDEX = 41,
EMC_PRE_REFRESH_REQ_CNT_INDEX = 43,
EMC_TRPAB_INDEX = 59,
EMC_MRW7_INDEX = 62,
EMC_FBIO_CFG5_INDEX = 65,
EMC_FBIO_CFG7_INDEX,
EMC_CFG_DIG_DLL_INDEX,
EMC_ZCAL_INTERVAL_INDEX = 139,
EMC_ZCAL_WAIT_CNT_INDEX,
EMC_MRS_WAIT_CNT_INDEX = 141,
EMC_DLL_CFG_0_INDEX = 144,
EMC_PMACRO_AUTOCAL_CFG_COMMON_INDEX = 146,
EMC_CFG_INDEX = 148,
EMC_DYN_SELF_REF_CONTROL_INDEX = 150,
EMC_PMACRO_CMD_PAD_TX_CTRL_INDEX = 161,
EMC_PMACRO_DATA_PAD_TX_CTRL_INDEX,
EMC_PMACRO_COMMON_PAD_TX_CTRL_INDEX,
EMC_PMACRO_BRICK_CTRL_RFU1_INDEX = 167,
EMC_PMACRO_BG_BIAS_CTRL_0_INDEX = 171,
EMC_MRW14_INDEX = 199,
EMC_MRW15_INDEX = 220,
};
enum trim_regs_list {
......@@ -866,6 +964,9 @@ static inline u32 div_o3(u32 a, u32 b)
return result;
}
/* from tegra210-emc-r21021.c */
extern const struct tegra210_emc_sequence tegra210_emc_r21021;
u32 tegra210_emc_mrr_read(struct tegra210_emc *emc, unsigned int chip,
unsigned int address);
void tegra210_emc_do_clock_change(struct tegra210_emc *emc, u32 clksrc);
......
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