linux/drivers/memory/samsung/exynos5422-dmc.c
Lukasz Luba bbf918863e memory: samsung: exynos5422-dmc: Add support for interrupt from performance counters
Introduce a new interrupt driven mechanism for managing speed of the
memory controller. The interrupts are generated due to performance
counters overflow. The performance counters might track memory reads,
writes, transfers, page misses, etc. In the basic algorithm tracking
read transfers and calculating memory pressure should be enough to skip
polling mode in devfreq.

Signed-off-by: Lukasz Luba <l.luba@partner.samsung.com>
Signed-off-by: Krzysztof Kozlowski <krzk@kernel.org>
2019-10-02 19:37:37 +02:00

1551 lines
45 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2019 Samsung Electronics Co., Ltd.
* Author: Lukasz Luba <l.luba@partner.samsung.com>
*/
#include <linux/clk.h>
#include <linux/devfreq.h>
#include <linux/devfreq-event.h>
#include <linux/device.h>
#include <linux/interrupt.h>
#include <linux/io.h>
#include <linux/mfd/syscon.h>
#include <linux/module.h>
#include <linux/of_device.h>
#include <linux/pm_opp.h>
#include <linux/platform_device.h>
#include <linux/regmap.h>
#include <linux/regulator/consumer.h>
#include <linux/slab.h>
#include "../jedec_ddr.h"
#include "../of_memory.h"
#define EXYNOS5_DREXI_TIMINGAREF (0x0030)
#define EXYNOS5_DREXI_TIMINGROW0 (0x0034)
#define EXYNOS5_DREXI_TIMINGDATA0 (0x0038)
#define EXYNOS5_DREXI_TIMINGPOWER0 (0x003C)
#define EXYNOS5_DREXI_TIMINGROW1 (0x00E4)
#define EXYNOS5_DREXI_TIMINGDATA1 (0x00E8)
#define EXYNOS5_DREXI_TIMINGPOWER1 (0x00EC)
#define CDREX_PAUSE (0x2091c)
#define CDREX_LPDDR3PHY_CON3 (0x20a20)
#define CDREX_LPDDR3PHY_CLKM_SRC (0x20700)
#define EXYNOS5_TIMING_SET_SWI BIT(28)
#define USE_MX_MSPLL_TIMINGS (1)
#define USE_BPLL_TIMINGS (0)
#define EXYNOS5_AREF_NORMAL (0x2e)
#define DREX_PPCCLKCON (0x0130)
#define DREX_PEREV2CONFIG (0x013c)
#define DREX_PMNC_PPC (0xE000)
#define DREX_CNTENS_PPC (0xE010)
#define DREX_CNTENC_PPC (0xE020)
#define DREX_INTENS_PPC (0xE030)
#define DREX_INTENC_PPC (0xE040)
#define DREX_FLAG_PPC (0xE050)
#define DREX_PMCNT2_PPC (0xE130)
/*
* A value for register DREX_PMNC_PPC which should be written to reset
* the cycle counter CCNT (a reference wall clock). It sets zero to the
* CCNT counter.
*/
#define CC_RESET BIT(2)
/*
* A value for register DREX_PMNC_PPC which does the reset of all performance
* counters to zero.
*/
#define PPC_COUNTER_RESET BIT(1)
/*
* Enables all configured counters (including cycle counter). The value should
* be written to the register DREX_PMNC_PPC.
*/
#define PPC_ENABLE BIT(0)
/* A value for register DREX_PPCCLKCON which enables performance events clock.
* Must be written before first access to the performance counters register
* set, otherwise it could crash.
*/
#define PEREV_CLK_EN BIT(0)
/*
* Values which are used to enable counters, interrupts or configure flags of
* the performance counters. They configure counter 2 and cycle counter.
*/
#define PERF_CNT2 BIT(2)
#define PERF_CCNT BIT(31)
/*
* Performance event types which are used for setting the preferred event
* to track in the counters.
* There is a set of different types, the values are from range 0 to 0x6f.
* These settings should be written to the configuration register which manages
* the type of the event (register DREX_PEREV2CONFIG).
*/
#define READ_TRANSFER_CH0 (0x6d)
#define READ_TRANSFER_CH1 (0x6f)
#define PERF_COUNTER_START_VALUE 0xff000000
#define PERF_EVENT_UP_DOWN_THRESHOLD 900000000ULL
/**
* struct dmc_opp_table - Operating level desciption
*
* Covers frequency and voltage settings of the DMC operating mode.
*/
struct dmc_opp_table {
u32 freq_hz;
u32 volt_uv;
};
/**
* struct exynos5_dmc - main structure describing DMC device
*
* The main structure for the Dynamic Memory Controller which covers clocks,
* memory regions, HW information, parameters and current operating mode.
*/
struct exynos5_dmc {
struct device *dev;
struct devfreq *df;
struct devfreq_simple_ondemand_data gov_data;
void __iomem *base_drexi0;
void __iomem *base_drexi1;
struct regmap *clk_regmap;
struct mutex lock;
unsigned long curr_rate;
unsigned long curr_volt;
unsigned long bypass_rate;
struct dmc_opp_table *opp;
struct dmc_opp_table opp_bypass;
int opp_count;
u32 timings_arr_size;
u32 *timing_row;
u32 *timing_data;
u32 *timing_power;
const struct lpddr3_timings *timings;
const struct lpddr3_min_tck *min_tck;
u32 bypass_timing_row;
u32 bypass_timing_data;
u32 bypass_timing_power;
struct regulator *vdd_mif;
struct clk *fout_spll;
struct clk *fout_bpll;
struct clk *mout_spll;
struct clk *mout_bpll;
struct clk *mout_mclk_cdrex;
struct clk *mout_mx_mspll_ccore;
struct clk *mx_mspll_ccore_phy;
struct clk *mout_mx_mspll_ccore_phy;
struct devfreq_event_dev **counter;
int num_counters;
u64 last_overflow_ts[2];
unsigned long load;
unsigned long total;
bool in_irq_mode;
};
#define TIMING_FIELD(t_name, t_bit_beg, t_bit_end) \
{ .name = t_name, .bit_beg = t_bit_beg, .bit_end = t_bit_end }
#define TIMING_VAL2REG(timing, t_val) \
({ \
u32 __val; \
__val = (t_val) << (timing)->bit_beg; \
__val; \
})
struct timing_reg {
char *name;
int bit_beg;
int bit_end;
unsigned int val;
};
static const struct timing_reg timing_row[] = {
TIMING_FIELD("tRFC", 24, 31),
TIMING_FIELD("tRRD", 20, 23),
TIMING_FIELD("tRP", 16, 19),
TIMING_FIELD("tRCD", 12, 15),
TIMING_FIELD("tRC", 6, 11),
TIMING_FIELD("tRAS", 0, 5),
};
static const struct timing_reg timing_data[] = {
TIMING_FIELD("tWTR", 28, 31),
TIMING_FIELD("tWR", 24, 27),
TIMING_FIELD("tRTP", 20, 23),
TIMING_FIELD("tW2W-C2C", 14, 14),
TIMING_FIELD("tR2R-C2C", 12, 12),
TIMING_FIELD("WL", 8, 11),
TIMING_FIELD("tDQSCK", 4, 7),
TIMING_FIELD("RL", 0, 3),
};
static const struct timing_reg timing_power[] = {
TIMING_FIELD("tFAW", 26, 31),
TIMING_FIELD("tXSR", 16, 25),
TIMING_FIELD("tXP", 8, 15),
TIMING_FIELD("tCKE", 4, 7),
TIMING_FIELD("tMRD", 0, 3),
};
#define TIMING_COUNT (ARRAY_SIZE(timing_row) + ARRAY_SIZE(timing_data) + \
ARRAY_SIZE(timing_power))
static int exynos5_counters_set_event(struct exynos5_dmc *dmc)
{
int i, ret;
for (i = 0; i < dmc->num_counters; i++) {
if (!dmc->counter[i])
continue;
ret = devfreq_event_set_event(dmc->counter[i]);
if (ret < 0)
return ret;
}
return 0;
}
static int exynos5_counters_enable_edev(struct exynos5_dmc *dmc)
{
int i, ret;
for (i = 0; i < dmc->num_counters; i++) {
if (!dmc->counter[i])
continue;
ret = devfreq_event_enable_edev(dmc->counter[i]);
if (ret < 0)
return ret;
}
return 0;
}
static int exynos5_counters_disable_edev(struct exynos5_dmc *dmc)
{
int i, ret;
for (i = 0; i < dmc->num_counters; i++) {
if (!dmc->counter[i])
continue;
ret = devfreq_event_disable_edev(dmc->counter[i]);
if (ret < 0)
return ret;
}
return 0;
}
/**
* find_target_freq_id() - Finds requested frequency in local DMC configuration
* @dmc: device for which the information is checked
* @target_rate: requested frequency in KHz
*
* Seeks in the local DMC driver structure for the requested frequency value
* and returns index or error value.
*/
static int find_target_freq_idx(struct exynos5_dmc *dmc,
unsigned long target_rate)
{
int i;
for (i = dmc->opp_count - 1; i >= 0; i--)
if (dmc->opp[i].freq_hz <= target_rate)
return i;
return -EINVAL;
}
/**
* exynos5_switch_timing_regs() - Changes bank register set for DRAM timings
* @dmc: device for which the new settings is going to be applied
* @set: boolean variable passing set value
*
* Changes the register set, which holds timing parameters.
* There is two register sets: 0 and 1. The register set 0
* is used in normal operation when the clock is provided from main PLL.
* The bank register set 1 is used when the main PLL frequency is going to be
* changed and the clock is taken from alternative, stable source.
* This function switches between these banks according to the
* currently used clock source.
*/
static void exynos5_switch_timing_regs(struct exynos5_dmc *dmc, bool set)
{
unsigned int reg;
int ret;
ret = regmap_read(dmc->clk_regmap, CDREX_LPDDR3PHY_CON3, &reg);
if (set)
reg |= EXYNOS5_TIMING_SET_SWI;
else
reg &= ~EXYNOS5_TIMING_SET_SWI;
regmap_write(dmc->clk_regmap, CDREX_LPDDR3PHY_CON3, reg);
}
/**
* exynos5_init_freq_table() - Initialized PM OPP framework
* @dmc: DMC device for which the frequencies are used for OPP init
* @profile: devfreq device's profile
*
* Populate the devfreq device's OPP table based on current frequency, voltage.
*/
static int exynos5_init_freq_table(struct exynos5_dmc *dmc,
struct devfreq_dev_profile *profile)
{
int i, ret;
int idx;
unsigned long freq;
ret = dev_pm_opp_of_add_table(dmc->dev);
if (ret < 0) {
dev_err(dmc->dev, "Failed to get OPP table\n");
return ret;
}
dmc->opp_count = dev_pm_opp_get_opp_count(dmc->dev);
dmc->opp = devm_kmalloc_array(dmc->dev, dmc->opp_count,
sizeof(struct dmc_opp_table), GFP_KERNEL);
if (!dmc->opp)
goto err_opp;
idx = dmc->opp_count - 1;
for (i = 0, freq = ULONG_MAX; i < dmc->opp_count; i++, freq--) {
struct dev_pm_opp *opp;
opp = dev_pm_opp_find_freq_floor(dmc->dev, &freq);
if (IS_ERR(opp))
goto err_opp;
dmc->opp[idx - i].freq_hz = freq;
dmc->opp[idx - i].volt_uv = dev_pm_opp_get_voltage(opp);
dev_pm_opp_put(opp);
}
return 0;
err_opp:
dev_pm_opp_of_remove_table(dmc->dev);
return -EINVAL;
}
/**
* exynos5_set_bypass_dram_timings() - Low-level changes of the DRAM timings
* @dmc: device for which the new settings is going to be applied
* @param: DRAM parameters which passes timing data
*
* Low-level function for changing timings for DRAM memory clocking from
* 'bypass' clock source (fixed frequency @400MHz).
* It uses timing bank registers set 1.
*/
static void exynos5_set_bypass_dram_timings(struct exynos5_dmc *dmc)
{
writel(EXYNOS5_AREF_NORMAL,
dmc->base_drexi0 + EXYNOS5_DREXI_TIMINGAREF);
writel(dmc->bypass_timing_row,
dmc->base_drexi0 + EXYNOS5_DREXI_TIMINGROW1);
writel(dmc->bypass_timing_row,
dmc->base_drexi1 + EXYNOS5_DREXI_TIMINGROW1);
writel(dmc->bypass_timing_data,
dmc->base_drexi0 + EXYNOS5_DREXI_TIMINGDATA1);
writel(dmc->bypass_timing_data,
dmc->base_drexi1 + EXYNOS5_DREXI_TIMINGDATA1);
writel(dmc->bypass_timing_power,
dmc->base_drexi0 + EXYNOS5_DREXI_TIMINGPOWER1);
writel(dmc->bypass_timing_power,
dmc->base_drexi1 + EXYNOS5_DREXI_TIMINGPOWER1);
}
/**
* exynos5_dram_change_timings() - Low-level changes of the DRAM final timings
* @dmc: device for which the new settings is going to be applied
* @target_rate: target frequency of the DMC
*
* Low-level function for changing timings for DRAM memory operating from main
* clock source (BPLL), which can have different frequencies. Thus, each
* frequency must have corresponding timings register values in order to keep
* the needed delays.
* It uses timing bank registers set 0.
*/
static int exynos5_dram_change_timings(struct exynos5_dmc *dmc,
unsigned long target_rate)
{
int idx;
for (idx = dmc->opp_count - 1; idx >= 0; idx--)
if (dmc->opp[idx].freq_hz <= target_rate)
break;
if (idx < 0)
return -EINVAL;
writel(EXYNOS5_AREF_NORMAL,
dmc->base_drexi0 + EXYNOS5_DREXI_TIMINGAREF);
writel(dmc->timing_row[idx],
dmc->base_drexi0 + EXYNOS5_DREXI_TIMINGROW0);
writel(dmc->timing_row[idx],
dmc->base_drexi1 + EXYNOS5_DREXI_TIMINGROW0);
writel(dmc->timing_data[idx],
dmc->base_drexi0 + EXYNOS5_DREXI_TIMINGDATA0);
writel(dmc->timing_data[idx],
dmc->base_drexi1 + EXYNOS5_DREXI_TIMINGDATA0);
writel(dmc->timing_power[idx],
dmc->base_drexi0 + EXYNOS5_DREXI_TIMINGPOWER0);
writel(dmc->timing_power[idx],
dmc->base_drexi1 + EXYNOS5_DREXI_TIMINGPOWER0);
return 0;
}
/**
* exynos5_dmc_align_target_voltage() - Sets the final voltage for the DMC
* @dmc: device for which it is going to be set
* @target_volt: new voltage which is chosen to be final
*
* Function tries to align voltage to the safe level for 'normal' mode.
* It checks the need of higher voltage and changes the value. The target
* voltage might be lower that currently set and still the system will be
* stable.
*/
static int exynos5_dmc_align_target_voltage(struct exynos5_dmc *dmc,
unsigned long target_volt)
{
int ret = 0;
if (dmc->curr_volt <= target_volt)
return 0;
ret = regulator_set_voltage(dmc->vdd_mif, target_volt,
target_volt);
if (!ret)
dmc->curr_volt = target_volt;
return ret;
}
/**
* exynos5_dmc_align_bypass_voltage() - Sets the voltage for the DMC
* @dmc: device for which it is going to be set
* @target_volt: new voltage which is chosen to be final
*
* Function tries to align voltage to the safe level for the 'bypass' mode.
* It checks the need of higher voltage and changes the value.
* The target voltage must not be less than currently needed, because
* for current frequency the device might become unstable.
*/
static int exynos5_dmc_align_bypass_voltage(struct exynos5_dmc *dmc,
unsigned long target_volt)
{
int ret = 0;
unsigned long bypass_volt = dmc->opp_bypass.volt_uv;
target_volt = max(bypass_volt, target_volt);
if (dmc->curr_volt >= target_volt)
return 0;
ret = regulator_set_voltage(dmc->vdd_mif, target_volt,
target_volt);
if (!ret)
dmc->curr_volt = target_volt;
return ret;
}
/**
* exynos5_dmc_align_bypass_dram_timings() - Chooses and sets DRAM timings
* @dmc: device for which it is going to be set
* @target_rate: new frequency which is chosen to be final
*
* Function changes the DRAM timings for the temporary 'bypass' mode.
*/
static int exynos5_dmc_align_bypass_dram_timings(struct exynos5_dmc *dmc,
unsigned long target_rate)
{
int idx = find_target_freq_idx(dmc, target_rate);
if (idx < 0)
return -EINVAL;
exynos5_set_bypass_dram_timings(dmc);
return 0;
}
/**
* exynos5_dmc_switch_to_bypass_configuration() - Switching to temporary clock
* @dmc: DMC device for which the switching is going to happen
* @target_rate: new frequency which is going to be set as a final
* @target_volt: new voltage which is going to be set as a final
*
* Function configures DMC and clocks for operating in temporary 'bypass' mode.
* This mode is used only temporary but if required, changes voltage and timings
* for DRAM chips. It switches the main clock to stable clock source for the
* period of the main PLL reconfiguration.
*/
static int
exynos5_dmc_switch_to_bypass_configuration(struct exynos5_dmc *dmc,
unsigned long target_rate,
unsigned long target_volt)
{
int ret;
/*
* Having higher voltage for a particular frequency does not harm
* the chip. Use it for the temporary frequency change when one
* voltage manipulation might be avoided.
*/
ret = exynos5_dmc_align_bypass_voltage(dmc, target_volt);
if (ret)
return ret;
/*
* Longer delays for DRAM does not cause crash, the opposite does.
*/
ret = exynos5_dmc_align_bypass_dram_timings(dmc, target_rate);
if (ret)
return ret;
/*
* Delays are long enough, so use them for the new coming clock.
*/
exynos5_switch_timing_regs(dmc, USE_MX_MSPLL_TIMINGS);
return ret;
}
/**
* exynos5_dmc_change_freq_and_volt() - Changes voltage and frequency of the DMC
* using safe procedure
* @dmc: device for which the frequency is going to be changed
* @target_rate: requested new frequency
* @target_volt: requested voltage which corresponds to the new frequency
*
* The DMC frequency change procedure requires a few steps.
* The main requirement is to change the clock source in the clk mux
* for the time of main clock PLL locking. The assumption is that the
* alternative clock source set as parent is stable.
* The second parent's clock frequency is fixed to 400MHz, it is named 'bypass'
* clock. This requires alignment in DRAM timing parameters for the new
* T-period. There is two bank sets for keeping DRAM
* timings: set 0 and set 1. The set 0 is used when main clock source is
* chosen. The 2nd set of regs is used for 'bypass' clock. Switching between
* the two bank sets is part of the process.
* The voltage must also be aligned to the minimum required level. There is
* this intermediate step with switching to 'bypass' parent clock source.
* if the old voltage is lower, it requires an increase of the voltage level.
* The complexity of the voltage manipulation is hidden in low level function.
* In this function there is last alignment of the voltage level at the end.
*/
static int
exynos5_dmc_change_freq_and_volt(struct exynos5_dmc *dmc,
unsigned long target_rate,
unsigned long target_volt)
{
int ret;
ret = exynos5_dmc_switch_to_bypass_configuration(dmc, target_rate,
target_volt);
if (ret)
return ret;
/*
* Voltage is set at least to a level needed for this frequency,
* so switching clock source is safe now.
*/
clk_prepare_enable(dmc->fout_spll);
clk_prepare_enable(dmc->mout_spll);
clk_prepare_enable(dmc->mout_mx_mspll_ccore);
ret = clk_set_parent(dmc->mout_mclk_cdrex, dmc->mout_mx_mspll_ccore);
if (ret)
goto disable_clocks;
/*
* We are safe to increase the timings for current bypass frequency.
* Thanks to this the settings will be ready for the upcoming clock
* source change.
*/
exynos5_dram_change_timings(dmc, target_rate);
clk_set_rate(dmc->fout_bpll, target_rate);
exynos5_switch_timing_regs(dmc, USE_BPLL_TIMINGS);
ret = clk_set_parent(dmc->mout_mclk_cdrex, dmc->mout_bpll);
if (ret)
goto disable_clocks;
/*
* Make sure if the voltage is not from 'bypass' settings and align to
* the right level for power efficiency.
*/
ret = exynos5_dmc_align_target_voltage(dmc, target_volt);
disable_clocks:
clk_disable_unprepare(dmc->mout_mx_mspll_ccore);
clk_disable_unprepare(dmc->mout_spll);
clk_disable_unprepare(dmc->fout_spll);
return ret;
}
/**
* exynos5_dmc_get_volt_freq() - Gets the frequency and voltage from the OPP
* table.
* @dmc: device for which the frequency is going to be changed
* @freq: requested frequency in KHz
* @target_rate: returned frequency which is the same or lower than
* requested
* @target_volt: returned voltage which corresponds to the returned
* frequency
*
* Function gets requested frequency and checks OPP framework for needed
* frequency and voltage. It populates the values 'target_rate' and
* 'target_volt' or returns error value when OPP framework fails.
*/
static int exynos5_dmc_get_volt_freq(struct exynos5_dmc *dmc,
unsigned long *freq,
unsigned long *target_rate,
unsigned long *target_volt, u32 flags)
{
struct dev_pm_opp *opp;
opp = devfreq_recommended_opp(dmc->dev, freq, flags);
if (IS_ERR(opp))
return PTR_ERR(opp);
*target_rate = dev_pm_opp_get_freq(opp);
*target_volt = dev_pm_opp_get_voltage(opp);
dev_pm_opp_put(opp);
return 0;
}
/**
* exynos5_dmc_target() - Function responsible for changing frequency of DMC
* @dev: device for which the frequency is going to be changed
* @freq: requested frequency in KHz
* @flags: flags provided for this frequency change request
*
* An entry function provided to the devfreq framework which provides frequency
* change of the DMC. The function gets the possible rate from OPP table based
* on requested frequency. It calls the next function responsible for the
* frequency and voltage change. In case of failure, does not set 'curr_rate'
* and returns error value to the framework.
*/
static int exynos5_dmc_target(struct device *dev, unsigned long *freq,
u32 flags)
{
struct exynos5_dmc *dmc = dev_get_drvdata(dev);
unsigned long target_rate = 0;
unsigned long target_volt = 0;
int ret;
ret = exynos5_dmc_get_volt_freq(dmc, freq, &target_rate, &target_volt,
flags);
if (ret)
return ret;
if (target_rate == dmc->curr_rate)
return 0;
mutex_lock(&dmc->lock);
ret = exynos5_dmc_change_freq_and_volt(dmc, target_rate, target_volt);
if (ret) {
mutex_unlock(&dmc->lock);
return ret;
}
dmc->curr_rate = target_rate;
mutex_unlock(&dmc->lock);
return 0;
}
/**
* exynos5_counters_get() - Gets the performance counters values.
* @dmc: device for which the counters are going to be checked
* @load_count: variable which is populated with counter value
* @total_count: variable which is used as 'wall clock' reference
*
* Function which provides performance counters values. It sums up counters for
* two DMC channels. The 'total_count' is used as a reference and max value.
* The ratio 'load_count/total_count' shows the busy percentage [0%, 100%].
*/
static int exynos5_counters_get(struct exynos5_dmc *dmc,
unsigned long *load_count,
unsigned long *total_count)
{
unsigned long total = 0;
struct devfreq_event_data event;
int ret, i;
*load_count = 0;
/* Take into account only read+write counters, but stop all */
for (i = 0; i < dmc->num_counters; i++) {
if (!dmc->counter[i])
continue;
ret = devfreq_event_get_event(dmc->counter[i], &event);
if (ret < 0)
return ret;
*load_count += event.load_count;
if (total < event.total_count)
total = event.total_count;
}
*total_count = total;
return 0;
}
/**
* exynos5_dmc_start_perf_events() - Setup and start performance event counters
* @dmc: device for which the counters are going to be checked
* @beg_value: initial value for the counter
*
* Function which enables needed counters, interrupts and sets initial values
* then starts the counters.
*/
static void exynos5_dmc_start_perf_events(struct exynos5_dmc *dmc,
u32 beg_value)
{
/* Enable interrupts for counter 2 */
writel(PERF_CNT2, dmc->base_drexi0 + DREX_INTENS_PPC);
writel(PERF_CNT2, dmc->base_drexi1 + DREX_INTENS_PPC);
/* Enable counter 2 and CCNT */
writel(PERF_CNT2 | PERF_CCNT, dmc->base_drexi0 + DREX_CNTENS_PPC);
writel(PERF_CNT2 | PERF_CCNT, dmc->base_drexi1 + DREX_CNTENS_PPC);
/* Clear overflow flag for all counters */
writel(PERF_CNT2 | PERF_CCNT, dmc->base_drexi0 + DREX_FLAG_PPC);
writel(PERF_CNT2 | PERF_CCNT, dmc->base_drexi1 + DREX_FLAG_PPC);
/* Reset all counters */
writel(CC_RESET | PPC_COUNTER_RESET, dmc->base_drexi0 + DREX_PMNC_PPC);
writel(CC_RESET | PPC_COUNTER_RESET, dmc->base_drexi1 + DREX_PMNC_PPC);
/*
* Set start value for the counters, the number of samples that
* will be gathered is calculated as: 0xffffffff - beg_value
*/
writel(beg_value, dmc->base_drexi0 + DREX_PMCNT2_PPC);
writel(beg_value, dmc->base_drexi1 + DREX_PMCNT2_PPC);
/* Start all counters */
writel(PPC_ENABLE, dmc->base_drexi0 + DREX_PMNC_PPC);
writel(PPC_ENABLE, dmc->base_drexi1 + DREX_PMNC_PPC);
}
/**
* exynos5_dmc_perf_events_calc() - Calculate utilization
* @dmc: device for which the counters are going to be checked
* @diff_ts: time between last interrupt and current one
*
* Function which calculates needed utilization for the devfreq governor.
* It prepares values for 'busy_time' and 'total_time' based on elapsed time
* between interrupts, which approximates utilization.
*/
static void exynos5_dmc_perf_events_calc(struct exynos5_dmc *dmc, u64 diff_ts)
{
/*
* This is a simple algorithm for managing traffic on DMC.
* When there is almost no load the counters overflow every 4s,
* no mater the DMC frequency.
* The high load might be approximated using linear function.
* Knowing that, simple calculation can provide 'busy_time' and
* 'total_time' to the devfreq governor which picks up target
* frequency.
* We want a fast ramp up and slow decay in frequency change function.
*/
if (diff_ts < PERF_EVENT_UP_DOWN_THRESHOLD) {
/*
* Set higher utilization for the simple_ondemand governor.
* The governor should increase the frequency of the DMC.
*/
dmc->load = 70;
dmc->total = 100;
} else {
/*
* Set low utilization for the simple_ondemand governor.
* The governor should decrease the frequency of the DMC.
*/
dmc->load = 35;
dmc->total = 100;
}
dev_dbg(dmc->dev, "diff_ts=%llu\n", diff_ts);
}
/**
* exynos5_dmc_perf_events_check() - Checks the status of the counters
* @dmc: device for which the counters are going to be checked
*
* Function which is called from threaded IRQ to check the counters state
* and to call approximation for the needed utilization.
*/
static void exynos5_dmc_perf_events_check(struct exynos5_dmc *dmc)
{
u32 val;
u64 diff_ts, ts;
ts = ktime_get_ns();
/* Stop all counters */
writel(0, dmc->base_drexi0 + DREX_PMNC_PPC);
writel(0, dmc->base_drexi1 + DREX_PMNC_PPC);
/* Check the source in interrupt flag registers (which channel) */
val = readl(dmc->base_drexi0 + DREX_FLAG_PPC);
if (val) {
diff_ts = ts - dmc->last_overflow_ts[0];
dmc->last_overflow_ts[0] = ts;
dev_dbg(dmc->dev, "drex0 0xE050 val= 0x%08x\n", val);
} else {
val = readl(dmc->base_drexi1 + DREX_FLAG_PPC);
diff_ts = ts - dmc->last_overflow_ts[1];
dmc->last_overflow_ts[1] = ts;
dev_dbg(dmc->dev, "drex1 0xE050 val= 0x%08x\n", val);
}
exynos5_dmc_perf_events_calc(dmc, diff_ts);
exynos5_dmc_start_perf_events(dmc, PERF_COUNTER_START_VALUE);
}
/**
* exynos5_dmc_enable_perf_events() - Enable performance events
* @dmc: device for which the counters are going to be checked
*
* Function which is setup needed environment and enables counters.
*/
static void exynos5_dmc_enable_perf_events(struct exynos5_dmc *dmc)
{
u64 ts;
/* Enable Performance Event Clock */
writel(PEREV_CLK_EN, dmc->base_drexi0 + DREX_PPCCLKCON);
writel(PEREV_CLK_EN, dmc->base_drexi1 + DREX_PPCCLKCON);
/* Select read transfers as performance event2 */
writel(READ_TRANSFER_CH0, dmc->base_drexi0 + DREX_PEREV2CONFIG);
writel(READ_TRANSFER_CH1, dmc->base_drexi1 + DREX_PEREV2CONFIG);
ts = ktime_get_ns();
dmc->last_overflow_ts[0] = ts;
dmc->last_overflow_ts[1] = ts;
/* Devfreq shouldn't be faster than initialization, play safe though. */
dmc->load = 99;
dmc->total = 100;
}
/**
* exynos5_dmc_disable_perf_events() - Disable performance events
* @dmc: device for which the counters are going to be checked
*
* Function which stops, disables performance event counters and interrupts.
*/
static void exynos5_dmc_disable_perf_events(struct exynos5_dmc *dmc)
{
/* Stop all counters */
writel(0, dmc->base_drexi0 + DREX_PMNC_PPC);
writel(0, dmc->base_drexi1 + DREX_PMNC_PPC);
/* Disable interrupts for counter 2 */
writel(PERF_CNT2, dmc->base_drexi0 + DREX_INTENC_PPC);
writel(PERF_CNT2, dmc->base_drexi1 + DREX_INTENC_PPC);
/* Disable counter 2 and CCNT */
writel(PERF_CNT2 | PERF_CCNT, dmc->base_drexi0 + DREX_CNTENC_PPC);
writel(PERF_CNT2 | PERF_CCNT, dmc->base_drexi1 + DREX_CNTENC_PPC);
/* Clear overflow flag for all counters */
writel(PERF_CNT2 | PERF_CCNT, dmc->base_drexi0 + DREX_FLAG_PPC);
writel(PERF_CNT2 | PERF_CCNT, dmc->base_drexi1 + DREX_FLAG_PPC);
}
/**
* exynos5_dmc_get_status() - Read current DMC performance statistics.
* @dev: device for which the statistics are requested
* @stat: structure which has statistic fields
*
* Function reads the DMC performance counters and calculates 'busy_time'
* and 'total_time'. To protect from overflow, the values are shifted right
* by 10. After read out the counters are setup to count again.
*/
static int exynos5_dmc_get_status(struct device *dev,
struct devfreq_dev_status *stat)
{
struct exynos5_dmc *dmc = dev_get_drvdata(dev);
unsigned long load, total;
int ret;
if (dmc->in_irq_mode) {
stat->current_frequency = dmc->curr_rate;
stat->busy_time = dmc->load;
stat->total_time = dmc->total;
} else {
ret = exynos5_counters_get(dmc, &load, &total);
if (ret < 0)
return -EINVAL;
/* To protect from overflow, divide by 1024 */
stat->busy_time = load >> 10;
stat->total_time = total >> 10;
ret = exynos5_counters_set_event(dmc);
if (ret < 0) {
dev_err(dev, "could not set event counter\n");
return ret;
}
}
return 0;
}
/**
* exynos5_dmc_get_cur_freq() - Function returns current DMC frequency
* @dev: device for which the framework checks operating frequency
* @freq: returned frequency value
*
* It returns the currently used frequency of the DMC. The real operating
* frequency might be lower when the clock source value could not be divided
* to the requested value.
*/
static int exynos5_dmc_get_cur_freq(struct device *dev, unsigned long *freq)
{
struct exynos5_dmc *dmc = dev_get_drvdata(dev);
mutex_lock(&dmc->lock);
*freq = dmc->curr_rate;
mutex_unlock(&dmc->lock);
return 0;
}
/**
* exynos5_dmc_df_profile - Devfreq governor's profile structure
*
* It provides to the devfreq framework needed functions and polling period.
*/
static struct devfreq_dev_profile exynos5_dmc_df_profile = {
.target = exynos5_dmc_target,
.get_dev_status = exynos5_dmc_get_status,
.get_cur_freq = exynos5_dmc_get_cur_freq,
};
/**
* exynos5_dmc_align_initial_frequency() - Align initial frequency value
* @dmc: device for which the frequency is going to be set
* @bootloader_init_freq: initial frequency set by the bootloader in KHz
*
* The initial bootloader frequency, which is present during boot, might be
* different that supported frequency values in the driver. It is possible
* due to different PLL settings or used PLL as a source.
* This function provides the 'initial_freq' for the devfreq framework
* statistics engine which supports only registered values. Thus, some alignment
* must be made.
*/
static unsigned long
exynos5_dmc_align_init_freq(struct exynos5_dmc *dmc,
unsigned long bootloader_init_freq)
{
unsigned long aligned_freq;
int idx;
idx = find_target_freq_idx(dmc, bootloader_init_freq);
if (idx >= 0)
aligned_freq = dmc->opp[idx].freq_hz;
else
aligned_freq = dmc->opp[dmc->opp_count - 1].freq_hz;
return aligned_freq;
}
/**
* create_timings_aligned() - Create register values and align with standard
* @dmc: device for which the frequency is going to be set
* @idx: speed bin in the OPP table
* @clk_period_ps: the period of the clock, known as tCK
*
* The function calculates timings and creates a register value ready for
* a frequency transition. The register contains a few timings. They are
* shifted by a known offset. The timing value is calculated based on memory
* specyfication: minimal time required and minimal cycles required.
*/
static int create_timings_aligned(struct exynos5_dmc *dmc, u32 *reg_timing_row,
u32 *reg_timing_data, u32 *reg_timing_power,
u32 clk_period_ps)
{
u32 val;
const struct timing_reg *reg;
if (clk_period_ps == 0)
return -EINVAL;
*reg_timing_row = 0;
*reg_timing_data = 0;
*reg_timing_power = 0;
val = dmc->timings->tRFC / clk_period_ps;
val += dmc->timings->tRFC % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tRFC);
reg = &timing_row[0];
*reg_timing_row |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tRRD / clk_period_ps;
val += dmc->timings->tRRD % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tRRD);
reg = &timing_row[1];
*reg_timing_row |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tRPab / clk_period_ps;
val += dmc->timings->tRPab % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tRPab);
reg = &timing_row[2];
*reg_timing_row |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tRCD / clk_period_ps;
val += dmc->timings->tRCD % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tRCD);
reg = &timing_row[3];
*reg_timing_row |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tRC / clk_period_ps;
val += dmc->timings->tRC % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tRC);
reg = &timing_row[4];
*reg_timing_row |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tRAS / clk_period_ps;
val += dmc->timings->tRAS % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tRAS);
reg = &timing_row[5];
*reg_timing_row |= TIMING_VAL2REG(reg, val);
/* data related timings */
val = dmc->timings->tWTR / clk_period_ps;
val += dmc->timings->tWTR % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tWTR);
reg = &timing_data[0];
*reg_timing_data |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tWR / clk_period_ps;
val += dmc->timings->tWR % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tWR);
reg = &timing_data[1];
*reg_timing_data |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tRTP / clk_period_ps;
val += dmc->timings->tRTP % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tRTP);
reg = &timing_data[2];
*reg_timing_data |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tW2W_C2C / clk_period_ps;
val += dmc->timings->tW2W_C2C % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tW2W_C2C);
reg = &timing_data[3];
*reg_timing_data |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tR2R_C2C / clk_period_ps;
val += dmc->timings->tR2R_C2C % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tR2R_C2C);
reg = &timing_data[4];
*reg_timing_data |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tWL / clk_period_ps;
val += dmc->timings->tWL % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tWL);
reg = &timing_data[5];
*reg_timing_data |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tDQSCK / clk_period_ps;
val += dmc->timings->tDQSCK % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tDQSCK);
reg = &timing_data[6];
*reg_timing_data |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tRL / clk_period_ps;
val += dmc->timings->tRL % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tRL);
reg = &timing_data[7];
*reg_timing_data |= TIMING_VAL2REG(reg, val);
/* power related timings */
val = dmc->timings->tFAW / clk_period_ps;
val += dmc->timings->tFAW % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tXP);
reg = &timing_power[0];
*reg_timing_power |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tXSR / clk_period_ps;
val += dmc->timings->tXSR % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tXSR);
reg = &timing_power[1];
*reg_timing_power |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tXP / clk_period_ps;
val += dmc->timings->tXP % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tXP);
reg = &timing_power[2];
*reg_timing_power |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tCKE / clk_period_ps;
val += dmc->timings->tCKE % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tCKE);
reg = &timing_power[3];
*reg_timing_power |= TIMING_VAL2REG(reg, val);
val = dmc->timings->tMRD / clk_period_ps;
val += dmc->timings->tMRD % clk_period_ps ? 1 : 0;
val = max(val, dmc->min_tck->tMRD);
reg = &timing_power[4];
*reg_timing_power |= TIMING_VAL2REG(reg, val);
return 0;
}
/**
* of_get_dram_timings() - helper function for parsing DT settings for DRAM
* @dmc: device for which the frequency is going to be set
*
* The function parses DT entries with DRAM information.
*/
static int of_get_dram_timings(struct exynos5_dmc *dmc)
{
int ret = 0;
int idx;
struct device_node *np_ddr;
u32 freq_mhz, clk_period_ps;
np_ddr = of_parse_phandle(dmc->dev->of_node, "device-handle", 0);
if (!np_ddr) {
dev_warn(dmc->dev, "could not find 'device-handle' in DT\n");
return -EINVAL;
}
dmc->timing_row = devm_kmalloc_array(dmc->dev, TIMING_COUNT,
sizeof(u32), GFP_KERNEL);
if (!dmc->timing_row)
return -ENOMEM;
dmc->timing_data = devm_kmalloc_array(dmc->dev, TIMING_COUNT,
sizeof(u32), GFP_KERNEL);
if (!dmc->timing_data)
return -ENOMEM;
dmc->timing_power = devm_kmalloc_array(dmc->dev, TIMING_COUNT,
sizeof(u32), GFP_KERNEL);
if (!dmc->timing_power)
return -ENOMEM;
dmc->timings = of_lpddr3_get_ddr_timings(np_ddr, dmc->dev,
DDR_TYPE_LPDDR3,
&dmc->timings_arr_size);
if (!dmc->timings) {
of_node_put(np_ddr);
dev_warn(dmc->dev, "could not get timings from DT\n");
return -EINVAL;
}
dmc->min_tck = of_lpddr3_get_min_tck(np_ddr, dmc->dev);
if (!dmc->min_tck) {
of_node_put(np_ddr);
dev_warn(dmc->dev, "could not get tck from DT\n");
return -EINVAL;
}
/* Sorted array of OPPs with frequency ascending */
for (idx = 0; idx < dmc->opp_count; idx++) {
freq_mhz = dmc->opp[idx].freq_hz / 1000000;
clk_period_ps = 1000000 / freq_mhz;
ret = create_timings_aligned(dmc, &dmc->timing_row[idx],
&dmc->timing_data[idx],
&dmc->timing_power[idx],
clk_period_ps);
}
of_node_put(np_ddr);
/* Take the highest frequency's timings as 'bypass' */
dmc->bypass_timing_row = dmc->timing_row[idx - 1];
dmc->bypass_timing_data = dmc->timing_data[idx - 1];
dmc->bypass_timing_power = dmc->timing_power[idx - 1];
return ret;
}
/**
* exynos5_dmc_init_clks() - Initialize clocks needed for DMC operation.
* @dmc: DMC structure containing needed fields
*
* Get the needed clocks defined in DT device, enable and set the right parents.
* Read current frequency and initialize the initial rate for governor.
*/
static int exynos5_dmc_init_clks(struct exynos5_dmc *dmc)
{
int ret;
unsigned long target_volt = 0;
unsigned long target_rate = 0;
unsigned int tmp;
dmc->fout_spll = devm_clk_get(dmc->dev, "fout_spll");
if (IS_ERR(dmc->fout_spll))
return PTR_ERR(dmc->fout_spll);
dmc->fout_bpll = devm_clk_get(dmc->dev, "fout_bpll");
if (IS_ERR(dmc->fout_bpll))
return PTR_ERR(dmc->fout_bpll);
dmc->mout_mclk_cdrex = devm_clk_get(dmc->dev, "mout_mclk_cdrex");
if (IS_ERR(dmc->mout_mclk_cdrex))
return PTR_ERR(dmc->mout_mclk_cdrex);
dmc->mout_bpll = devm_clk_get(dmc->dev, "mout_bpll");
if (IS_ERR(dmc->mout_bpll))
return PTR_ERR(dmc->mout_bpll);
dmc->mout_mx_mspll_ccore = devm_clk_get(dmc->dev,
"mout_mx_mspll_ccore");
if (IS_ERR(dmc->mout_mx_mspll_ccore))
return PTR_ERR(dmc->mout_mx_mspll_ccore);
dmc->mout_spll = devm_clk_get(dmc->dev, "ff_dout_spll2");
if (IS_ERR(dmc->mout_spll)) {
dmc->mout_spll = devm_clk_get(dmc->dev, "mout_sclk_spll");
if (IS_ERR(dmc->mout_spll))
return PTR_ERR(dmc->mout_spll);
}
/*
* Convert frequency to KHz values and set it for the governor.
*/
dmc->curr_rate = clk_get_rate(dmc->mout_mclk_cdrex);
dmc->curr_rate = exynos5_dmc_align_init_freq(dmc, dmc->curr_rate);
exynos5_dmc_df_profile.initial_freq = dmc->curr_rate;
ret = exynos5_dmc_get_volt_freq(dmc, &dmc->curr_rate, &target_rate,
&target_volt, 0);
if (ret)
return ret;
dmc->curr_volt = target_volt;
clk_set_parent(dmc->mout_mx_mspll_ccore, dmc->mout_spll);
dmc->bypass_rate = clk_get_rate(dmc->mout_mx_mspll_ccore);
clk_prepare_enable(dmc->fout_bpll);
clk_prepare_enable(dmc->mout_bpll);
/*
* Some bootloaders do not set clock routes correctly.
* Stop one path in clocks to PHY.
*/
regmap_read(dmc->clk_regmap, CDREX_LPDDR3PHY_CLKM_SRC, &tmp);
tmp &= ~(BIT(1) | BIT(0));
regmap_write(dmc->clk_regmap, CDREX_LPDDR3PHY_CLKM_SRC, tmp);
return 0;
}
/**
* exynos5_performance_counters_init() - Initializes performance DMC's counters
* @dmc: DMC for which it does the setup
*
* Initialization of performance counters in DMC for estimating usage.
* The counter's values are used for calculation of a memory bandwidth and based
* on that the governor changes the frequency.
* The counters are not used when the governor is GOVERNOR_USERSPACE.
*/
static int exynos5_performance_counters_init(struct exynos5_dmc *dmc)
{
int counters_size;
int ret, i;
dmc->num_counters = devfreq_event_get_edev_count(dmc->dev);
if (dmc->num_counters < 0) {
dev_err(dmc->dev, "could not get devfreq-event counters\n");
return dmc->num_counters;
}
counters_size = sizeof(struct devfreq_event_dev) * dmc->num_counters;
dmc->counter = devm_kzalloc(dmc->dev, counters_size, GFP_KERNEL);
if (!dmc->counter)
return -ENOMEM;
for (i = 0; i < dmc->num_counters; i++) {
dmc->counter[i] =
devfreq_event_get_edev_by_phandle(dmc->dev, i);
if (IS_ERR_OR_NULL(dmc->counter[i]))
return -EPROBE_DEFER;
}
ret = exynos5_counters_enable_edev(dmc);
if (ret < 0) {
dev_err(dmc->dev, "could not enable event counter\n");
return ret;
}
ret = exynos5_counters_set_event(dmc);
if (ret < 0) {
exynos5_counters_disable_edev(dmc);
dev_err(dmc->dev, "could not set event counter\n");
return ret;
}
return 0;
}
/**
* exynos5_dmc_set_pause_on_switching() - Controls a pause feature in DMC
* @dmc: device which is used for changing this feature
* @set: a boolean state passing enable/disable request
*
* There is a need of pausing DREX DMC when divider or MUX in clock tree
* changes its configuration. In such situation access to the memory is blocked
* in DMC automatically. This feature is used when clock frequency change
* request appears and touches clock tree.
*/
static inline int exynos5_dmc_set_pause_on_switching(struct exynos5_dmc *dmc)
{
unsigned int val;
int ret;
ret = regmap_read(dmc->clk_regmap, CDREX_PAUSE, &val);
if (ret)
return ret;
val |= 1UL;
regmap_write(dmc->clk_regmap, CDREX_PAUSE, val);
return 0;
}
static irqreturn_t dmc_irq_thread(int irq, void *priv)
{
int res;
struct exynos5_dmc *dmc = priv;
mutex_lock(&dmc->df->lock);
exynos5_dmc_perf_events_check(dmc);
res = update_devfreq(dmc->df);
if (res)
dev_warn(dmc->dev, "devfreq failed with %d\n", res);
mutex_unlock(&dmc->df->lock);
return IRQ_HANDLED;
}
/**
* exynos5_dmc_probe() - Probe function for the DMC driver
* @pdev: platform device for which the driver is going to be initialized
*
* Initialize basic components: clocks, regulators, performance counters, etc.
* Read out product version and based on the information setup
* internal structures for the controller (frequency and voltage) and for DRAM
* memory parameters: timings for each operating frequency.
* Register new devfreq device for controlling DVFS of the DMC.
*/
static int exynos5_dmc_probe(struct platform_device *pdev)
{
int ret = 0;
struct device *dev = &pdev->dev;
struct device_node *np = dev->of_node;
struct exynos5_dmc *dmc;
struct resource *res;
int irq[2];
dmc = devm_kzalloc(dev, sizeof(*dmc), GFP_KERNEL);
if (!dmc)
return -ENOMEM;
mutex_init(&dmc->lock);
dmc->dev = dev;
platform_set_drvdata(pdev, dmc);
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
dmc->base_drexi0 = devm_ioremap_resource(dev, res);
if (IS_ERR(dmc->base_drexi0))
return PTR_ERR(dmc->base_drexi0);
res = platform_get_resource(pdev, IORESOURCE_MEM, 1);
dmc->base_drexi1 = devm_ioremap_resource(dev, res);
if (IS_ERR(dmc->base_drexi1))
return PTR_ERR(dmc->base_drexi1);
dmc->clk_regmap = syscon_regmap_lookup_by_phandle(np,
"samsung,syscon-clk");
if (IS_ERR(dmc->clk_regmap))
return PTR_ERR(dmc->clk_regmap);
ret = exynos5_init_freq_table(dmc, &exynos5_dmc_df_profile);
if (ret) {
dev_warn(dev, "couldn't initialize frequency settings\n");
return ret;
}
dmc->vdd_mif = devm_regulator_get(dev, "vdd");
if (IS_ERR(dmc->vdd_mif)) {
ret = PTR_ERR(dmc->vdd_mif);
return ret;
}
ret = exynos5_dmc_init_clks(dmc);
if (ret)
return ret;
ret = of_get_dram_timings(dmc);
if (ret) {
dev_warn(dev, "couldn't initialize timings settings\n");
goto remove_clocks;
}
ret = exynos5_dmc_set_pause_on_switching(dmc);
if (ret) {
dev_warn(dev, "couldn't get access to PAUSE register\n");
goto remove_clocks;
}
/* There is two modes in which the driver works: polling or IRQ */
irq[0] = platform_get_irq_byname(pdev, "drex_0");
irq[1] = platform_get_irq_byname(pdev, "drex_1");
if (irq[0] > 0 && irq[1] > 0) {
ret = devm_request_threaded_irq(dev, irq[0], NULL,
dmc_irq_thread, IRQF_ONESHOT,
dev_name(dev), dmc);
if (ret) {
dev_err(dev, "couldn't grab IRQ\n");
goto remove_clocks;
}
ret = devm_request_threaded_irq(dev, irq[1], NULL,
dmc_irq_thread, IRQF_ONESHOT,
dev_name(dev), dmc);
if (ret) {
dev_err(dev, "couldn't grab IRQ\n");
goto remove_clocks;
}
/*
* Setup default thresholds for the devfreq governor.
* The values are chosen based on experiments.
*/
dmc->gov_data.upthreshold = 55;
dmc->gov_data.downdifferential = 5;
exynos5_dmc_enable_perf_events(dmc);
dmc->in_irq_mode = 1;
} else {
ret = exynos5_performance_counters_init(dmc);
if (ret) {
dev_warn(dev, "couldn't probe performance counters\n");
goto remove_clocks;
}
/*
* Setup default thresholds for the devfreq governor.
* The values are chosen based on experiments.
*/
dmc->gov_data.upthreshold = 30;
dmc->gov_data.downdifferential = 5;
exynos5_dmc_df_profile.polling_ms = 500;
}
dmc->df = devm_devfreq_add_device(dev, &exynos5_dmc_df_profile,
DEVFREQ_GOV_SIMPLE_ONDEMAND,
&dmc->gov_data);
if (IS_ERR(dmc->df)) {
ret = PTR_ERR(dmc->df);
goto err_devfreq_add;
}
if (dmc->in_irq_mode)
exynos5_dmc_start_perf_events(dmc, PERF_COUNTER_START_VALUE);
dev_info(dev, "DMC initialized\n");
return 0;
err_devfreq_add:
if (dmc->in_irq_mode)
exynos5_dmc_disable_perf_events(dmc);
else
exynos5_counters_disable_edev(dmc);
remove_clocks:
clk_disable_unprepare(dmc->mout_bpll);
clk_disable_unprepare(dmc->fout_bpll);
return ret;
}
/**
* exynos5_dmc_remove() - Remove function for the platform device
* @pdev: platform device which is going to be removed
*
* The function relies on 'devm' framework function which automatically
* clean the device's resources. It just calls explicitly disable function for
* the performance counters.
*/
static int exynos5_dmc_remove(struct platform_device *pdev)
{
struct exynos5_dmc *dmc = dev_get_drvdata(&pdev->dev);
if (dmc->in_irq_mode)
exynos5_dmc_disable_perf_events(dmc);
else
exynos5_counters_disable_edev(dmc);
clk_disable_unprepare(dmc->mout_bpll);
clk_disable_unprepare(dmc->fout_bpll);
dev_pm_opp_remove_table(dmc->dev);
return 0;
}
static const struct of_device_id exynos5_dmc_of_match[] = {
{ .compatible = "samsung,exynos5422-dmc", },
{ },
};
MODULE_DEVICE_TABLE(of, exynos5_dmc_of_match);
static struct platform_driver exynos5_dmc_platdrv = {
.probe = exynos5_dmc_probe,
.remove = exynos5_dmc_remove,
.driver = {
.name = "exynos5-dmc",
.of_match_table = exynos5_dmc_of_match,
},
};
module_platform_driver(exynos5_dmc_platdrv);
MODULE_DESCRIPTION("Driver for Exynos5422 Dynamic Memory Controller dynamic frequency and voltage change");
MODULE_LICENSE("GPL v2");
MODULE_AUTHOR("Lukasz Luba");