Re: [PATCH v5 3/3] PM / AVS: SVS: Introduce SVS engine

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Hi Roger,

Roger Lu <roger.lu@xxxxxxxxxxxx> writes:

> The SVS (Smart Voltage Scaling) engine is a piece of hardware which is
> used to calculate optimized voltage values of several power domains, e.g.
> CPU/GPU/CCI, according to chip process corner, temperatures, and other
> factors. Then DVFS driver could apply those optimized voltage values to
> reduce power consumption.
>
> Signed-off-by: Roger Lu <roger.lu@xxxxxxxxxxxx>

I don't have any documentation on this SVS hardware, so I won't be able
to comment on the specific functionality, so I attempted a first-pass
high-level review...

In the absence of documentation, it would be helpful to give a high
level description of how this hardware works.  In particular, a
high-level overview of the control loop, which appears to be primarily
interrupt driven, would be helpful.  e.g. how often are the interrupts
firing, and why.

It's hard to understand the "init01" vs the "init02" patch since
those names aren't very descriptive. :)

Also, there are lots of hard-coded constants (masks, shifts, etc.) used
throughout the calculations.  #defines could help readability for many
of these, especially the masks.

> ---
>  drivers/power/avs/Kconfig     |   10 +
>  drivers/power/avs/Makefile    |    1 +
>  drivers/power/avs/mtk_svs.c   | 2075 +++++++++++++++++++++++++++++++++
>  include/linux/power/mtk_svs.h |   23 +
>  4 files changed, 2109 insertions(+)
>  create mode 100644 drivers/power/avs/mtk_svs.c
>  create mode 100644 include/linux/power/mtk_svs.h
>
> diff --git a/drivers/power/avs/Kconfig b/drivers/power/avs/Kconfig
> index b5a217b828dc..7c72504d5593 100644
> --- a/drivers/power/avs/Kconfig
> +++ b/drivers/power/avs/Kconfig
> @@ -19,3 +19,13 @@ config ROCKCHIP_IODOMAIN
>            Say y here to enable support io domains on Rockchip SoCs. It is
>            necessary for the io domain setting of the SoC to match the
>            voltage supplied by the regulators.
> +
> +config MTK_SVS
> +	bool "MediaTek Smart Voltage Scaling(SVS)"
> +	depends on POWER_AVS && MTK_EFUSE
> +	help
> +	  The SVS engine is a piece of hardware which is used to calculate
> +	  optimized voltage values of several power domains, e.g.
> +	  CPU clusters/GPU/CCI, according to chip process corner, temperatures,
> +	  and other factors. Then DVFS driver could apply those optimized voltage
> +	  values to reduce power consumption.
> diff --git a/drivers/power/avs/Makefile b/drivers/power/avs/Makefile
> index a1b8cd453f19..57246b977a93 100644
> --- a/drivers/power/avs/Makefile
> +++ b/drivers/power/avs/Makefile
> @@ -1,3 +1,4 @@
>  # SPDX-License-Identifier: GPL-2.0-only
>  obj-$(CONFIG_POWER_AVS_OMAP)		+= smartreflex.o
>  obj-$(CONFIG_ROCKCHIP_IODOMAIN)		+= rockchip-io-domain.o
> +obj-$(CONFIG_MTK_SVS)			+= mtk_svs.o
> diff --git a/drivers/power/avs/mtk_svs.c b/drivers/power/avs/mtk_svs.c
> new file mode 100644
> index 000000000000..78ec93c3a4a5
> --- /dev/null
> +++ b/drivers/power/avs/mtk_svs.c
> @@ -0,0 +1,2075 @@
> +// SPDX-License-Identifier: GPL-2.0
> +/*
> + * Copyright (C) 2018 MediaTek Inc.
> + */
> +
> +#define pr_fmt(fmt)	"[mtk_svs] " fmt
> +
> +#include <linux/clk.h>
> +#include <linux/completion.h>
> +#include <linux/init.h>
> +#include <linux/interrupt.h>
> +#include <linux/kthread.h>
> +#include <linux/module.h>
> +#include <linux/mutex.h>
> +#include <linux/nvmem-consumer.h>
> +#include <linux/of_address.h>
> +#include <linux/of_irq.h>
> +#include <linux/platform_device.h>
> +#include <linux/pm_domain.h>
> +#include <linux/pm_opp.h>
> +#include <linux/pm_qos.h>
> +#include <linux/pm_runtime.h>
> +#include <linux/power/mtk_svs.h>
> +#include <linux/proc_fs.h>
> +#include <linux/regulator/consumer.h>
> +#include <linux/seq_file.h>
> +#include <linux/spinlock.h>
> +#include <linux/thermal.h>
> +#include <linux/uaccess.h>
> +
> +#define SVS_INIT01_VOLT_IGNORE		1
> +#define SVS_INIT01_VOLT_INC_ONLY	2
> +
> +#define SVS_PHASE_INIT01		0
> +#define SVS_PHASE_INIT02		1
> +#define SVS_PHASE_MON			2
> +#define SVS_PHASE_ERROR			3
> +
> +#define SVS_CPU_LITTLE			1
> +#define SVS_CPU_BIG			2
> +#define SVS_CCI				3
> +#define SVS_GPU				4
> +
> +#define proc_fops_rw(name) \
> +	static int name ## _proc_open(struct inode *inode,	\
> +		struct file *file)				\
> +	{							\
> +		return single_open(file, name ## _proc_show,	\
> +			PDE_DATA(inode));			\
> +	}							\
> +	static const struct file_operations name ## _proc_fops = {	\
> +		.owner          = THIS_MODULE,				\
> +		.open           = name ## _proc_open,			\
> +		.read           = seq_read,				\
> +		.llseek         = seq_lseek,				\
> +		.release        = single_release,			\
> +		.write          = name ## _proc_write,			\
> +	}
> +
> +#define proc_fops_ro(name) \
> +	static int name ## _proc_open(struct inode *inode,	\
> +		struct file *file)				\
> +	{							\
> +		return single_open(file, name ## _proc_show,	\
> +			PDE_DATA(inode));			\
> +	}							\
> +	static const struct file_operations name ## _proc_fops = {	\
> +		.owner          = THIS_MODULE,				\
> +		.open           = name ## _proc_open,			\
> +		.read           = seq_read,				\
> +		.llseek         = seq_lseek,				\
> +		.release        = single_release,			\
> +	}
> +
> +#define proc_entry(name)	{__stringify(name), &name ## _proc_fops}
> +
> +static DEFINE_SPINLOCK(mtk_svs_lock);
> +struct mtk_svs;
> +
> +enum reg_index {
> +	TEMPMONCTL0 = 0,
> +	TEMPMONCTL1,
> +	TEMPMONCTL2,
> +	TEMPMONINT,
> +	TEMPMONINTSTS,
> +	TEMPMONIDET0,
> +	TEMPMONIDET1,
> +	TEMPMONIDET2,
> +	TEMPH2NTHRE,
> +	TEMPHTHRE,
> +	TEMPCTHRE,
> +	TEMPOFFSETH,
> +	TEMPOFFSETL,
> +	TEMPMSRCTL0,
> +	TEMPMSRCTL1,
> +	TEMPAHBPOLL,
> +	TEMPAHBTO,
> +	TEMPADCPNP0,
> +	TEMPADCPNP1,
> +	TEMPADCPNP2,
> +	TEMPADCMUX,
> +	TEMPADCEXT,
> +	TEMPADCEXT1,
> +	TEMPADCEN,
> +	TEMPPNPMUXADDR,
> +	TEMPADCMUXADDR,
> +	TEMPADCEXTADDR,
> +	TEMPADCEXT1ADDR,
> +	TEMPADCENADDR,
> +	TEMPADCVALIDADDR,
> +	TEMPADCVOLTADDR,
> +	TEMPRDCTRL,
> +	TEMPADCVALIDMASK,
> +	TEMPADCVOLTAGESHIFT,
> +	TEMPADCWRITECTRL,
> +	TEMPMSR0,
> +	TEMPMSR1,
> +	TEMPMSR2,
> +	TEMPADCHADDR,
> +	TEMPIMMD0,
> +	TEMPIMMD1,
> +	TEMPIMMD2,
> +	TEMPMONIDET3,
> +	TEMPADCPNP3,
> +	TEMPMSR3,
> +	TEMPIMMD3,
> +	TEMPPROTCTL,
> +	TEMPPROTTA,
> +	TEMPPROTTB,
> +	TEMPPROTTC,
> +	TEMPSPARE0,
> +	TEMPSPARE1,
> +	TEMPSPARE2,
> +	TEMPSPARE3,
> +	TEMPMSR0_1,
> +	TEMPMSR1_1,
> +	TEMPMSR2_1,
> +	TEMPMSR3_1,
> +	DESCHAR,
> +	TEMPCHAR,
> +	DETCHAR,
> +	AGECHAR,
> +	DCCONFIG,
> +	AGECONFIG,
> +	FREQPCT30,
> +	FREQPCT74,
> +	LIMITVALS,
> +	VBOOT,
> +	DETWINDOW,
> +	CONFIG,
> +	TSCALCS,
> +	RUNCONFIG,
> +	SVSEN,
> +	INIT2VALS,
> +	DCVALUES,
> +	AGEVALUES,
> +	VOP30,
> +	VOP74,
> +	TEMP,
> +	INTSTS,
> +	INTSTSRAW,
> +	INTEN,
> +	CHKINT,
> +	CHKSHIFT,
> +	STATUS,
> +	VDESIGN30,
> +	VDESIGN74,
> +	DVT30,
> +	DVT74,
> +	AGECOUNT,
> +	SMSTATE0,
> +	SMSTATE1,
> +	CTL0,
> +	DESDETSEC,
> +	TEMPAGESEC,
> +	CTRLSPARE0,
> +	CTRLSPARE1,
> +	CTRLSPARE2,
> +	CTRLSPARE3,
> +	CORESEL,
> +	THERMINTST,
> +	INTST,
> +	THSTAGE0ST,
> +	THSTAGE1ST,
> +	THSTAGE2ST,
> +	THAHBST0,
> +	THAHBST1,
> +	SPARE0,
> +	SPARE1,
> +	SPARE2,
> +	SPARE3,
> +	THSLPEVEB,
> +	reg_num,
> +};
> +
> +static const u32 svs_regs_v2[] = {
> +	[TEMPMONCTL0]		= 0x000,
> +	[TEMPMONCTL1]		= 0x004,
> +	[TEMPMONCTL2]		= 0x008,
> +	[TEMPMONINT]		= 0x00c,
> +	[TEMPMONINTSTS]		= 0x010,
> +	[TEMPMONIDET0]		= 0x014,
> +	[TEMPMONIDET1]		= 0x018,
> +	[TEMPMONIDET2]		= 0x01c,
> +	[TEMPH2NTHRE]		= 0x024,
> +	[TEMPHTHRE]		= 0x028,
> +	[TEMPCTHRE]		= 0x02c,
> +	[TEMPOFFSETH]		= 0x030,
> +	[TEMPOFFSETL]		= 0x034,
> +	[TEMPMSRCTL0]		= 0x038,
> +	[TEMPMSRCTL1]		= 0x03c,
> +	[TEMPAHBPOLL]		= 0x040,
> +	[TEMPAHBTO]		= 0x044,
> +	[TEMPADCPNP0]		= 0x048,
> +	[TEMPADCPNP1]		= 0x04c,
> +	[TEMPADCPNP2]		= 0x050,
> +	[TEMPADCMUX]		= 0x054,
> +	[TEMPADCEXT]		= 0x058,
> +	[TEMPADCEXT1]		= 0x05c,
> +	[TEMPADCEN]		= 0x060,
> +	[TEMPPNPMUXADDR]	= 0x064,
> +	[TEMPADCMUXADDR]	= 0x068,
> +	[TEMPADCEXTADDR]	= 0x06c,
> +	[TEMPADCEXT1ADDR]	= 0x070,
> +	[TEMPADCENADDR]		= 0x074,
> +	[TEMPADCVALIDADDR]	= 0x078,
> +	[TEMPADCVOLTADDR]	= 0x07c,
> +	[TEMPRDCTRL]		= 0x080,
> +	[TEMPADCVALIDMASK]	= 0x084,
> +	[TEMPADCVOLTAGESHIFT]	= 0x088,
> +	[TEMPADCWRITECTRL]	= 0x08c,
> +	[TEMPMSR0]		= 0x090,
> +	[TEMPMSR1]		= 0x094,
> +	[TEMPMSR2]		= 0x098,
> +	[TEMPADCHADDR]		= 0x09c,
> +	[TEMPIMMD0]		= 0x0a0,
> +	[TEMPIMMD1]		= 0x0a4,
> +	[TEMPIMMD2]		= 0x0a8,
> +	[TEMPMONIDET3]		= 0x0b0,
> +	[TEMPADCPNP3]		= 0x0b4,
> +	[TEMPMSR3]		= 0x0b8,
> +	[TEMPIMMD3]		= 0x0bc,
> +	[TEMPPROTCTL]		= 0x0c0,
> +	[TEMPPROTTA]		= 0x0c4,
> +	[TEMPPROTTB]		= 0x0c8,
> +	[TEMPPROTTC]		= 0x0cc,
> +	[TEMPSPARE0]		= 0x0f0,
> +	[TEMPSPARE1]		= 0x0f4,
> +	[TEMPSPARE2]		= 0x0f8,
> +	[TEMPSPARE3]		= 0x0fc,
> +	[TEMPMSR0_1]		= 0x190,
> +	[TEMPMSR1_1]		= 0x194,
> +	[TEMPMSR2_1]		= 0x198,
> +	[TEMPMSR3_1]		= 0x1b8,
> +	[DESCHAR]		= 0xc00,
> +	[TEMPCHAR]		= 0xc04,
> +	[DETCHAR]		= 0xc08,
> +	[AGECHAR]		= 0xc0c,
> +	[DCCONFIG]		= 0xc10,
> +	[AGECONFIG]		= 0xc14,
> +	[FREQPCT30]		= 0xc18,
> +	[FREQPCT74]		= 0xc1c,
> +	[LIMITVALS]		= 0xc20,
> +	[VBOOT]			= 0xc24,
> +	[DETWINDOW]		= 0xc28,
> +	[CONFIG]		= 0xc2c,
> +	[TSCALCS]		= 0xc30,
> +	[RUNCONFIG]		= 0xc34,
> +	[SVSEN]			= 0xc38,
> +	[INIT2VALS]		= 0xc3c,
> +	[DCVALUES]		= 0xc40,
> +	[AGEVALUES]		= 0xc44,
> +	[VOP30]			= 0xc48,
> +	[VOP74]			= 0xc4c,
> +	[TEMP]			= 0xc50,
> +	[INTSTS]		= 0xc54,
> +	[INTSTSRAW]		= 0xc58,
> +	[INTEN]			= 0xc5c,
> +	[CHKINT]		= 0xc60,
> +	[CHKSHIFT]		= 0xc64,
> +	[STATUS]		= 0xc68,
> +	[VDESIGN30]		= 0xc6c,
> +	[VDESIGN74]		= 0xc70,
> +	[DVT30]			= 0xc74,
> +	[DVT74]			= 0xc78,
> +	[AGECOUNT]		= 0xc7c,
> +	[SMSTATE0]		= 0xc80,
> +	[SMSTATE1]		= 0xc84,
> +	[CTL0]			= 0xc88,
> +	[DESDETSEC]		= 0xce0,
> +	[TEMPAGESEC]		= 0xce4,
> +	[CTRLSPARE0]		= 0xcf0,
> +	[CTRLSPARE1]		= 0xcf4,
> +	[CTRLSPARE2]		= 0xcf8,
> +	[CTRLSPARE3]		= 0xcfc,
> +	[CORESEL]		= 0xf00,
> +	[THERMINTST]		= 0xf04,
> +	[INTST]			= 0xf08,
> +	[THSTAGE0ST]		= 0xf0c,
> +	[THSTAGE1ST]		= 0xf10,
> +	[THSTAGE2ST]		= 0xf14,
> +	[THAHBST0]		= 0xf18,
> +	[THAHBST1]		= 0xf1c,
> +	[SPARE0]		= 0xf20,
> +	[SPARE1]		= 0xf24,
> +	[SPARE2]		= 0xf28,
> +	[SPARE3]		= 0xf2c,
> +	[THSLPEVEB]		= 0xf30,
> +};
> +
> +struct thermal_parameter {
> +	int adc_ge_t;
> +	int adc_oe_t;
> +	int ge;
> +	int oe;
> +	int gain;
> +	int o_vtsabb;
> +	int o_vtsmcu1;
> +	int o_vtsmcu2;
> +	int o_vtsmcu3;
> +	int o_vtsmcu4;
> +	int o_vtsmcu5;
> +	int degc_cali;
> +	int adc_cali_en_t;
> +	int o_slope;
> +	int o_slope_sign;
> +	int ts_id;
> +};
> +
> +struct svs_bank_ops {
> +	void (*set_freqs_pct)(struct mtk_svs *svs);
> +	void (*get_vops)(struct mtk_svs *svs);
> +};
> +
> +struct svs_bank {
> +	struct svs_bank_ops *ops;
> +	struct completion init_completion;
> +	struct device *dev;
> +	struct regulator *buck;
> +	struct mutex lock;	/* lock to protect update voltage process */
> +	bool suspended;
> +	bool mtcmos_request;
> +	bool init01_support;
> +	bool init02_support;
> +	bool mon_mode_support;
> +	s32 volt_offset;
> +	u32 *opp_freqs;
> +	u32 *freqs_pct;
> +	u32 *opp_volts;
> +	u32 *init02_volts;
> +	u32 *volts;
> +	u32 reg_data[3][reg_num];
> +	u32 freq_base;
> +	u32 vboot;
> +	u32 volt_step;
> +	u32 volt_base;
> +	u32 init01_volt_flag;
> +	u32 phase;
> +	u32 vmax;
> +	u32 vmin;
> +	u32 bts;
> +	u32 mts;
> +	u32 bdes;
> +	u32 mdes;
> +	u32 mtdes;
> +	u32 dcbdet;
> +	u32 dcmdet;
> +	u32 dthi;
> +	u32 dtlo;
> +	u32 det_window;
> +	u32 det_max;
> +	u32 age_config;
> +	u32 age_voffset_in;
> +	u32 agem;
> +	u32 dc_config;
> +	u32 dc_voffset_in;
> +	u32 dvt_fixed;
> +	u32 vco;
> +	u32 chkshift;
> +	u32 svs_temp;
> +	u32 upper_temp_bound;
> +	u32 lower_temp_bound;
> +	u32 low_temp_threashold;
> +	u32 low_temp_offset;
> +	u32 coresel;
> +	u32 opp_count;
> +	u32 intst;
> +	u32 systemclk_en;
> +	u32 sw_id;
> +	u32 hw_id;
> +	u32 ctl0;
> +	u8 *of_compatible;
> +	u8 *name;
> +	u8 *zone_name;
> +	u8 *buck_name;
> +};
> +
> +struct svs_platform {
> +	struct svs_bank *banks;
> +	int (*efuse_parsing)(struct mtk_svs *svs);
> +	bool fake_efuse;
> +	const u32 *regs;
> +	u32 bank_num;
> +	u32 efuse_num;
> +	u32 efuse_check;
> +	u32 thermal_efuse_num;
> +	u8 *name;
> +};
> +
> +struct mtk_svs {
> +	const struct svs_platform *platform;
> +	struct svs_bank *bank;
> +	struct device *dev;
> +	void __iomem *base;
> +	struct clk *main_clk;
> +	u32 *efuse;
> +	u32 *thermal_efuse;
> +};
> +
> +unsigned long claim_mtk_svs_lock(void)
> +{
> +	unsigned long flags;
> +
> +	spin_lock_irqsave(&mtk_svs_lock, flags);
> +
> +	return flags;
> +}
> +EXPORT_SYMBOL_GPL(claim_mtk_svs_lock);
> +
> +void release_mtk_svs_lock(unsigned long flags)
> +{
> +	spin_unlock_irqrestore(&mtk_svs_lock, flags);
> +}
> +EXPORT_SYMBOL_GPL(release_mtk_svs_lock);

I don't see the need for these wrapper functions.  You seem to be
declaring this lock in the header which implies there are external
users, but there is none in this series, so this lock should stay local
IMO.

> +static u32 percent(u32 numerator, u32 denominator)
> +{
> +	u32 percent;
> +
> +	/* If not divide 1000, "numerator * 100" would be data overflow. */
> +	numerator /= 1000;
> +	denominator /= 1000;
> +	percent = ((numerator * 100) + denominator - 1) / denominator;
> +
> +	return percent;
> +}

Maybe some math helpers from math64.h would help you not have to
open-code this?

> +static u32 svs_readl(struct mtk_svs *svs, enum reg_index i)
> +{
> +	return readl(svs->base + svs->platform->regs[i]);
> +}
> +
> +static void svs_writel(struct mtk_svs *svs, u32 val, enum reg_index i)
> +{
> +	writel(val, svs->base + svs->platform->regs[i]);
> +}
> +
> +static void svs_switch_bank(struct mtk_svs *svs)
> +{
> +	struct svs_bank *svsb = svs->bank;
> +
> +	svs_writel(svs, svsb->coresel, CORESEL);
> +}
> +
> +static u32 svs_volt_to_opp_volt(u32 svsb_volt,
> +				u32 svsb_volt_step, u32 svsb_volt_base)
> +{
> +	u32 u_volt;
> +
> +	u_volt = (svsb_volt * svsb_volt_step) + svsb_volt_base;
> +
> +	return u_volt;
> +}
> +
> +static int svs_get_zone_temperature(struct svs_bank *svsb, int *zone_temp)
> +{
> +	struct thermal_zone_device *tzd;
> +	int ret;
> +
> +	tzd = thermal_zone_get_zone_by_name(svsb->zone_name);
> +	ret = thermal_zone_get_temp(tzd, zone_temp);
> +
> +	return ret;
> +}
> +
> +static int svs_set_volts(struct svs_bank *svsb, bool force_update)
> +{
> +	u32 i, svsb_volt, opp_volt, low_temp_offset = 0;
> +	int zone_temp, ret;
> +
> +	mutex_lock(&svsb->lock);
> +
> +	/* If bank is suspended, it means init02 voltage is applied.
> +	 * Don't need to update opp voltage anymore.
> +	 */

minor nit: fix multi-line comment style

> +	if (svsb->suspended && !force_update) {
> +		pr_notice("%s: bank is suspended\n", svsb->name);
> +		mutex_unlock(&svsb->lock);
> +		return -EPERM;
> +	}
> +
> +	/* get thermal effect */
> +	if (svsb->phase == SVS_PHASE_MON) {
> +		if (svsb->svs_temp > svsb->upper_temp_bound &&
> +		    svsb->svs_temp < svsb->lower_temp_bound) {
> +			pr_err("%s: svs_temp is abnormal (0x%x)?\n",
> +			       svsb->name, svsb->svs_temp);
> +			mutex_unlock(&svsb->lock);
> +			return -EINVAL;
> +		}
> +
> +		ret = svs_get_zone_temperature(svsb, &zone_temp);
> +		if (ret) {
> +			pr_err("%s: cannot get zone \"%s\" temperature\n",
> +			       svsb->name, svsb->zone_name);
> +			pr_err("%s: add low_temp_offset = %u\n",
> +			       svsb->name, svsb->low_temp_offset);
> +			zone_temp = svsb->low_temp_threashold;
> +		}
> +
> +		if (zone_temp <= svsb->low_temp_threashold)
> +			low_temp_offset = svsb->low_temp_offset;
> +	}
> +
> +	/* vmin <= svsb_volt (opp_volt) <= signed-off voltage */
> +	for (i = 0; i < svsb->opp_count; i++) {
> +		if (svsb->phase == SVS_PHASE_MON) {
> +			svsb_volt = max((svsb->volts[i] + svsb->volt_offset +
> +					 low_temp_offset), svsb->vmin);
> +			opp_volt = svs_volt_to_opp_volt(svsb_volt,
> +							svsb->volt_step,
> +							svsb->volt_base);
> +		} else if (svsb->phase == SVS_PHASE_INIT02) {
> +			svsb_volt = max((svsb->init02_volts[i] +
> +					 svsb->volt_offset), svsb->vmin);
> +			opp_volt = svs_volt_to_opp_volt(svsb_volt,
> +							svsb->volt_step,
> +							svsb->volt_base);
> +		} else if (svsb->phase == SVS_PHASE_ERROR) {
> +			opp_volt = svsb->opp_volts[i];
> +		} else {
> +			pr_err("%s: unknown phase: %u?\n",
> +			       svsb->name, svsb->phase);
> +			mutex_unlock(&svsb->lock);
> +			return -EINVAL;
> +		}
> +
> +		opp_volt = min(opp_volt, svsb->opp_volts[i]);
> +		ret = dev_pm_opp_adjust_voltage(svsb->dev, svsb->opp_freqs[i],
> +						opp_volt);
> +		if (ret) {
> +			pr_err("%s: set voltage failed: %d\n", svsb->name, ret);
> +			mutex_unlock(&svsb->lock);
> +			return ret;
> +		}
> +	}
> +
> +	mutex_unlock(&svsb->lock);
> +
> +	return 0;
> +}
> +
> +static u32 interpolate(u32 f0, u32 f1, u32 v0, u32 v1, u32 fx)
> +{
> +	u32 vy;
> +
> +	if (v0 == v1 || f0 == f1)
> +		return v0;
> +
> +	/* *100 to have decimal fraction factor, +99 for rounding up. */
> +	vy = (v0 * 100) - ((((v0 - v1) * 100) / (f0 - f1)) * (f0 - fx));
> +	vy = (vy + 99) / 100;
> +
> +	return vy;
> +}
> +
> +static void svs_get_vops_v2(struct mtk_svs *svs)
> +{
> +	struct svs_bank *svsb = svs->bank;
> +	u32 temp, i;
> +
> +	temp = svs_readl(svs, VOP30);
> +	svsb->volts[6] = (temp >> 24) & 0xff;
> +	svsb->volts[4] = (temp >> 16) & 0xff;
> +	svsb->volts[2] = (temp >> 8)  & 0xff;
> +	svsb->volts[0] = (temp & 0xff);
> +
> +	temp = svs_readl(svs, VOP74);
> +	svsb->volts[14] = (temp >> 24) & 0xff;
> +	svsb->volts[12] = (temp >> 16) & 0xff;
> +	svsb->volts[10] = (temp >> 8)  & 0xff;
> +	svsb->volts[8] = (temp & 0xff);
> +
> +	for (i = 0; i <= 7; i++) {
> +		if (i < 7) {
> +			svsb->volts[(i * 2) + 1] =
> +				interpolate(svsb->freqs_pct[i * 2],
> +					    svsb->freqs_pct[(i + 1) * 2],
> +					    svsb->volts[i * 2],
> +					    svsb->volts[(i + 1) * 2],
> +					    svsb->freqs_pct[(i * 2) + 1]);
> +		} else if (i == 7) {
> +			svsb->volts[(i * 2) + 1] =
> +				interpolate(svsb->freqs_pct[(i - 1) * 2],
> +					    svsb->freqs_pct[i * 2],
> +					    svsb->volts[(i - 1) * 2],
> +					    svsb->volts[i * 2],
> +					    svsb->freqs_pct[(i * 2) + 1]);
> +		}
> +	}
> +}
> +
> +static void svs_set_freqs_pct_v2(struct mtk_svs *svs)
> +{
> +	struct svs_bank *svsb = svs->bank;
> +
> +	svs_writel(svs,
> +		   ((svsb->freqs_pct[6] << 24) & 0xff000000) |
> +		   ((svsb->freqs_pct[4] << 16) & 0xff0000) |
> +		   ((svsb->freqs_pct[2] << 8) & 0xff00) |
> +		   (svsb->freqs_pct[0] & 0xff),
> +		   FREQPCT30);
> +	svs_writel(svs,
> +		   ((svsb->freqs_pct[14] << 24) & 0xff000000) |
> +		   ((svsb->freqs_pct[12] << 16) & 0xff0000) |
> +		   ((svsb->freqs_pct[10] << 8) & 0xff00) |
> +		   ((svsb->freqs_pct[8]) & 0xff),
> +		   FREQPCT74);
> +}
> +
> +static void svs_set_phase(struct mtk_svs *svs, u32 target_phase)
> +{
> +	struct svs_bank *svsb = svs->bank;
> +	u32 des_char, temp_char, det_char, limit_vals;
> +	u32 init2vals, ts_calcs, val, filter, i;
> +
> +	svs_switch_bank(svs);
> +
> +	des_char = ((svsb->bdes << 8) & 0xff00) | (svsb->mdes & 0xff);
> +	svs_writel(svs, des_char, DESCHAR);
> +
> +	temp_char = ((svsb->vco << 16) & 0xff0000) |
> +		    ((svsb->mtdes << 8) & 0xff00) |
> +		    (svsb->dvt_fixed & 0xff);
> +	svs_writel(svs, temp_char, TEMPCHAR);
> +
> +	det_char = ((svsb->dcbdet << 8) & 0xff00) | (svsb->dcmdet & 0xff);
> +	svs_writel(svs, det_char, DETCHAR);
> +
> +	svs_writel(svs, svsb->dc_config, DCCONFIG);
> +	svs_writel(svs, svsb->age_config, AGECONFIG);
> +
> +	if (svsb->agem == 0x0) {
> +		svs_writel(svs, 0x80000000, RUNCONFIG);
> +	} else {
> +		val = 0x0;
> +
> +		for (i = 0; i < 24; i += 2) {
> +			filter = 0x3 << i;
> +
> +			if ((svsb->age_config & filter) == 0x0)
> +				val |= (0x1 << i);
> +			else
> +				val |= (svsb->age_config & filter);
> +		}
> +		svs_writel(svs, val, RUNCONFIG);
> +	}
> +
> +	svsb->ops->set_freqs_pct(svs);
> +
> +	limit_vals = ((svsb->vmax << 24) & 0xff000000) |
> +		     ((svsb->vmin << 16) & 0xff0000) |
> +		     ((svsb->dthi << 8) & 0xff00) |
> +		     (svsb->dtlo & 0xff);
> +	svs_writel(svs, limit_vals, LIMITVALS);
> +	svs_writel(svs, (svsb->vboot & 0xff), VBOOT);
> +	svs_writel(svs, (svsb->det_window & 0xffff), DETWINDOW);
> +	svs_writel(svs, (svsb->det_max & 0xffff), CONFIG);
> +
> +	if (svsb->chkshift != 0)
> +		svs_writel(svs, (svsb->chkshift & 0xff), CHKSHIFT);
> +
> +	if (svsb->ctl0 != 0)
> +		svs_writel(svs, svsb->ctl0, CTL0);
> +
> +	svs_writel(svs, 0x00ffffff, INTSTS);
> +
> +	switch (target_phase) {
> +	case SVS_PHASE_INIT01:
> +		svs_writel(svs, 0x00005f01, INTEN);
> +		svs_writel(svs, 0x00000001, SVSEN);
> +		break;
> +	case SVS_PHASE_INIT02:
> +		svs_writel(svs, 0x00005f01, INTEN);
> +		init2vals = ((svsb->age_voffset_in << 16) & 0xffff0000) |
> +			    (svsb->dc_voffset_in & 0xffff);
> +		svs_writel(svs, init2vals, INIT2VALS);
> +		svs_writel(svs, 0x00000005, SVSEN);
> +		break;
> +	case SVS_PHASE_MON:
> +		ts_calcs = ((svsb->bts << 12) & 0xfff000) | (svsb->mts & 0xfff);
> +		svs_writel(svs, ts_calcs, TSCALCS);
> +		svs_writel(svs, 0x00FF0000, INTEN);
> +		svs_writel(svs, 0x00000002, SVSEN);
> +		break;
> +	default:
> +		WARN_ON(1);
> +		break;
> +	}
> +}

lots of  magic constants for these register writes.  #defines w/bit
descriptions would be very helpful for the reader.

> +static inline void svs_init01_isr_handler(struct mtk_svs *svs)
> +{
> +	struct svs_bank *svsb = svs->bank;
> +	enum reg_index rg_i;
> +
> +	pr_notice("%s: %s: VDN74:0x%08x, VDN30:0x%08x, DCVALUES:0x%08x\n",
> +		  svsb->name, __func__, svs_readl(svs, VDESIGN74),
> +		  svs_readl(svs, VDESIGN30), svs_readl(svs, DCVALUES));
> +
> +	for (rg_i = TEMPMONCTL0; rg_i < reg_num; rg_i++)
> +		svsb->reg_data[SVS_PHASE_INIT01][rg_i] = svs_readl(svs, rg_i);
> +
> +	svsb->dc_voffset_in = ~(svs_readl(svs, DCVALUES) & 0xffff) + 1;
> +	if (svsb->init01_volt_flag == SVS_INIT01_VOLT_IGNORE)
> +		svsb->dc_voffset_in = 0;
> +	else if ((svsb->dc_voffset_in & 0x8000) &&
> +		 (svsb->init01_volt_flag == SVS_INIT01_VOLT_INC_ONLY))
> +		svsb->dc_voffset_in = 0;
> +
> +	svsb->age_voffset_in = svs_readl(svs, AGEVALUES) & 0xffff;
> +
> +	svs_writel(svs, 0x0, SVSEN);
> +	svs_writel(svs, 0x1, INTSTS);
> +
> +	/* svs init01 clock gating */
> +	svsb->coresel &= ~svsb->systemclk_en;
> +
> +	svsb->phase = SVS_PHASE_INIT01;
> +	complete(&svsb->init_completion);
> +}
> +
> +static inline void svs_init02_isr_handler(struct mtk_svs *svs)
> +{
> +	struct svs_bank *svsb = svs->bank;
> +	enum reg_index rg_i;
> +
> +	pr_notice("%s: %s: VOP74:0x%08x, VOP30:0x%08x, DCVALUES:0x%08x\n",
> +		  svsb->name, __func__, svs_readl(svs, VOP74),
> +		  svs_readl(svs, VOP30), svs_readl(svs, DCVALUES));
> +
> +	for (rg_i = TEMPMONCTL0; rg_i < reg_num; rg_i++)
> +		svsb->reg_data[SVS_PHASE_INIT02][rg_i] = svs_readl(svs, rg_i);
> +
> +	svsb->ops->get_vops(svs);
> +	memcpy(svsb->init02_volts, svsb->volts, 4 * svsb->opp_count);
> +	svsb->phase = SVS_PHASE_INIT02;
> +
> +	svs_writel(svs, 0x0, SVSEN);
> +	svs_writel(svs, 0x1, INTSTS);
> +
> +	complete(&svsb->init_completion);
> +}
> +
> +static inline void svs_mon_mode_isr_handler(struct mtk_svs *svs)
> +{
> +	struct svs_bank *svsb = svs->bank;
> +	enum reg_index rg_i;
> +
> +	for (rg_i = TEMPMONCTL0; rg_i < reg_num; rg_i++)
> +		svsb->reg_data[SVS_PHASE_MON][rg_i] = svs_readl(svs, rg_i);
> +
> +	svsb->svs_temp = svs_readl(svs, TEMP) & 0xff;
> +
> +	svsb->ops->get_vops(svs);
> +	svsb->phase = SVS_PHASE_MON;
> +
> +	svs_writel(svs, 0x00ff0000, INTSTS);
> +}
> +
> +static inline void svs_error_isr_handler(struct mtk_svs *svs)
> +{
> +	const struct svs_platform *svsp = svs->platform;
> +	struct svs_bank *svsb = svs->bank;
> +	enum reg_index rg_i;
> +
> +	pr_err("%s(): %s(%s)", __func__, svsp->name, svsb->name);
> +	pr_err("CORESEL(0x%x) = 0x%08x\n",
> +	       svsp->regs[CORESEL], svs_readl(svs, CORESEL)),
> +	pr_err("SVSEN(0x%x) = 0x%08x, INTSTS(0x%x) = 0x%08x\n",
> +	       svsp->regs[SVSEN], svs_readl(svs, SVSEN),
> +	       svsp->regs[INTSTS], svs_readl(svs, INTSTS));
> +	pr_err("SMSTATE0(0x%x) = 0x%08x, SMSTATE1(0x%x) = 0x%08x\n",
> +	       svsp->regs[SMSTATE0], svs_readl(svs, SMSTATE0),
> +	       svsp->regs[SMSTATE1], svs_readl(svs, SMSTATE1));
> +
> +	for (rg_i = TEMPMONCTL0; rg_i < reg_num; rg_i++)
> +		svsb->reg_data[SVS_PHASE_MON][rg_i] = svs_readl(svs, rg_i);
> +
> +	svsb->init01_support = false;
> +	svsb->init02_support = false;
> +	svsb->mon_mode_support = false;
> +
> +	if (svsb->phase == SVS_PHASE_MON)
> +		svsb->phase = SVS_PHASE_INIT02;
> +
> +	svs_writel(svs, 0x0, SVSEN);
> +	svs_writel(svs, 0x00ffffff, INTSTS);
> +}
> +
> +static inline void svs_isr_handler(struct mtk_svs *svs)
> +{
> +	u32 intsts, svsen;
> +
> +	svs_switch_bank(svs);
> +
> +	intsts = svs_readl(svs, INTSTS);
> +	svsen = svs_readl(svs, SVSEN);
> +
> +	if (intsts == 0x1 && ((svsen & 0x7) == 0x1))
> +		svs_init01_isr_handler(svs);
> +	else if ((intsts == 0x1) && ((svsen & 0x7) == 0x5))
> +		svs_init02_isr_handler(svs);
> +	else if ((intsts & 0x00ff0000) != 0x0)
> +		svs_mon_mode_isr_handler(svs);
> +	else
> +		svs_error_isr_handler(svs);
> +}
> +
> +static irqreturn_t svs_isr(int irq, void *data)
> +{
> +	struct mtk_svs *svs = (struct mtk_svs *)data;
> +	const struct svs_platform *svsp = svs->platform;
> +	struct svs_bank *svsb = NULL;
> +	unsigned long flags;
> +	u32 idx;
> +
> +	flags = claim_mtk_svs_lock();
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		svs->bank = svsb;
> +
> +		if (svsb->suspended)
> +			continue;
> +		else if (svsb->intst & svs_readl(svs, INTST))
> +			continue;
> +
> +		svs_isr_handler(svs);
> +		break;
> +	}
> +	release_mtk_svs_lock(flags);
> +
> +	if (svsb->phase != SVS_PHASE_INIT01)
> +		svs_set_volts(svsb, false);
> +
> +	return IRQ_HANDLED;
> +}
> +
> +static void svs_mon_mode(struct mtk_svs *svs)
> +{
> +	const struct svs_platform *svsp = svs->platform;
> +	struct svs_bank *svsb;
> +	unsigned long flags;
> +	u32 idx;
> +
> +	flags = claim_mtk_svs_lock();
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		svs->bank = svsb;
> +
> +		if (!svsb->mon_mode_support)
> +			continue;
> +
> +		svs_set_phase(svs, SVS_PHASE_MON);
> +	}
> +	release_mtk_svs_lock(flags);
> +}
> +
> +static int svs_init02(struct mtk_svs *svs)
> +{
> +	const struct svs_platform *svsp = svs->platform;
> +	struct svs_bank *svsb;
> +	unsigned long flags, time_left;
> +	u32 idx;
> +
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		svs->bank = svsb;
> +
> +		if (!svsb->init02_support)
> +			continue;
> +
> +		reinit_completion(&svsb->init_completion);
> +		flags = claim_mtk_svs_lock();
> +		svs_set_phase(svs, SVS_PHASE_INIT02);
> +		release_mtk_svs_lock(flags);
> +		time_left =
> +			wait_for_completion_timeout(&svsb->init_completion,
> +						    msecs_to_jiffies(2000));
> +		if (time_left == 0) {
> +			pr_err("%s: init02 completion timeout\n", svsb->name);
> +			return -EBUSY;
> +		}
> +	}
> +
> +	return 0;
> +}
> +
> +static int svs_init01(struct mtk_svs *svs)
> +{
> +	const struct svs_platform *svsp = svs->platform;
> +	struct svs_bank *svsb;
> +	struct pm_qos_request qos_request = { {0} };
> +	unsigned long flags, time_left;
> +	bool search_done;
> +	int ret = -EINVAL;
> +	u32 opp_freqs, opp_vboot, buck_volt, idx, i;
> +
> +	/* Let CPUs leave idle-off state for initializing svs_init01. */
> +	pm_qos_add_request(&qos_request, PM_QOS_CPU_DMA_LATENCY, 0);
> +
> +	/* Sometimes two svs_bank use the same buck.
> +	 * Therefore, we set each svs_bank to vboot voltage first.
> +	 */
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		search_done = false;
> +
> +		if (!svsb->init01_support)
> +			continue;
> +
> +		ret = regulator_set_mode(svsb->buck, REGULATOR_MODE_FAST);
> +		if (ret)
> +			pr_notice("%s: fail to set fast mode: %d\n",
> +				  svsb->name, ret);
> +
> +		if (svsb->mtcmos_request) {
> +			ret = regulator_enable(svsb->buck);
> +			if (ret) {
> +				pr_err("%s: fail to enable %s power: %d\n",
> +				       svsb->name, svsb->buck_name, ret);
> +				goto init01_finish;
> +			}
> +
> +			ret = dev_pm_domain_attach(svsb->dev, false);
> +			if (ret) {
> +				pr_err("%s: attach pm domain fail: %d\n",
> +				       svsb->name, ret);
> +				goto init01_finish;
> +			}
> +
> +			pm_runtime_enable(svsb->dev);
> +			ret = pm_runtime_get_sync(svsb->dev);
> +			if (ret < 0) {
> +				pr_err("%s: turn mtcmos on fail: %d\n",
> +				       svsb->name, ret);
> +				goto init01_finish;
> +			}
> +		}
> +
> +		/* Find the fastest freq that can be run at vboot and
> +		 * fix to that freq until svs_init01 is done.
> +		 */
> +		opp_vboot = svs_volt_to_opp_volt(svsb->vboot,
> +						 svsb->volt_step,
> +						 svsb->volt_base);
> +
> +		for (i = 0; i < svsb->opp_count; i++) {
> +			opp_freqs = svsb->opp_freqs[i];
> +			if (!search_done && svsb->opp_volts[i] <= opp_vboot) {
> +				ret = dev_pm_opp_adjust_voltage(svsb->dev,
> +								opp_freqs,
> +								opp_vboot);
> +				if (ret) {
> +					pr_err("%s: set voltage failed: %d\n",
> +					       svsb->name, ret);
> +					goto init01_finish;
> +				}
> +
> +				search_done = true;
> +			} else {
> +				dev_pm_opp_disable(svsb->dev,
> +						   svsb->opp_freqs[i]);
> +			}
> +		}
> +	}
> +
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		svs->bank = svsb;
> +
> +		if (!svsb->init01_support)
> +			continue;
> +
> +		opp_vboot = svs_volt_to_opp_volt(svsb->vboot,
> +						 svsb->volt_step,
> +						 svsb->volt_base);
> +
> +		buck_volt = regulator_get_voltage(svsb->buck);
> +		if (buck_volt != opp_vboot) {
> +			pr_err("%s: buck voltage: %u, expected vboot: %u\n",
> +			       svsb->name, buck_volt, opp_vboot);
> +			ret = -EPERM;
> +			goto init01_finish;
> +		}
> +
> +		init_completion(&svsb->init_completion);
> +		flags = claim_mtk_svs_lock();
> +		svs_set_phase(svs, SVS_PHASE_INIT01);
> +		release_mtk_svs_lock(flags);
> +		time_left =
> +			wait_for_completion_timeout(&svsb->init_completion,
> +						    msecs_to_jiffies(2000));
> +		if (time_left == 0) {
> +			pr_err("%s: init01 completion timeout\n", svsb->name);
> +			ret = -EBUSY;
> +			goto init01_finish;
> +		}
> +	}
> +
> +init01_finish:
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +
> +		if (!svsb->init01_support)
> +			continue;
> +
> +		for (i = 0; i < svsb->opp_count; i++)
> +			dev_pm_opp_enable(svsb->dev, svsb->opp_freqs[i]);
> +
> +		if (regulator_set_mode(svsb->buck, REGULATOR_MODE_NORMAL))
> +			pr_notice("%s: fail to set normal mode: %d\n",
> +				  svsb->name, ret);
> +
> +		if (svsb->mtcmos_request) {
> +			if (pm_runtime_put_sync(svsb->dev))
> +				pr_err("%s: turn mtcmos off fail: %d\n",
> +				       svsb->name, ret);
> +			pm_runtime_disable(svsb->dev);
> +			dev_pm_domain_detach(svsb->dev, 0);
> +			if (regulator_disable(svsb->buck))
> +				pr_err("%s: fail to disable %s power: %d\n",
> +				       svsb->name, svsb->buck_name, ret);
> +		}
> +	}
> +
> +	pm_qos_remove_request(&qos_request);
> +
> +	return ret;
> +}
> +
> +static int svs_start(struct mtk_svs *svs)
> +{
> +	int ret;
> +
> +	ret = svs_init01(svs);
> +	if (ret)
> +		return ret;
> +
> +	ret = svs_init02(svs);
> +	if (ret)
> +		return ret;
> +
> +	svs_mon_mode(svs);
> +
> +	return ret;
> +}
> +
> +static int svs_mt8183_efuse_parsing(struct mtk_svs *svs)
> +{
> +	const struct svs_platform *svsp = svs->platform;
> +	struct thermal_parameter tp;
> +	struct svs_bank *svsb;
> +	bool mon_mode_support = true;
> +	int format[6], x_roomt[6], tb_roomt;
> +	u32 idx, i, ft_pgm, mts, temp0, temp1, temp2;
> +
> +	if (svsp->fake_efuse) {
> +		pr_notice("fake efuse\n");
> +		svs->efuse[0] = 0x00310080;
> +		svs->efuse[1] = 0xabfbf757;
> +		svs->efuse[2] = 0x47c747c7;
> +		svs->efuse[3] = 0xabfbf757;
> +		svs->efuse[4] = 0xe7fca0ec;
> +		svs->efuse[5] = 0x47bf4b88;
> +		svs->efuse[6] = 0xabfb8fa5;
> +		svs->efuse[7] = 0xabfb217b;
> +		svs->efuse[8] = 0x4bf34be1;
> +		svs->efuse[9] = 0xabfb670d;
> +		svs->efuse[16] = 0xabfbc653;
> +		svs->efuse[17] = 0x47f347e1;
> +		svs->efuse[18] = 0xabfbd848;
> +
> +		svs->thermal_efuse[0] = 0x02873f69;
> +		svs->thermal_efuse[1] = 0xa11d9142;
> +		svs->thermal_efuse[2] = 0xa2526900;
> +	}
> +
> +	/* svs efuse parsing */
> +	ft_pgm = (svs->efuse[0] >> 4) & 0xf;
> +
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		if (ft_pgm <= 1)
> +			svsb->init01_volt_flag = SVS_INIT01_VOLT_IGNORE;
> +
> +		switch (svsb->sw_id) {
> +		case SVS_CPU_LITTLE:
> +			svsb->bdes = svs->efuse[16] & 0xff;
> +			svsb->mdes = (svs->efuse[16] >> 8) & 0xff;
> +			svsb->dcbdet = (svs->efuse[16] >> 16) & 0xff;
> +			svsb->dcmdet = (svs->efuse[16] >> 24) & 0xff;
> +			svsb->mtdes  = (svs->efuse[17] >> 16) & 0xff;
> +
> +			if (ft_pgm <= 3)
> +				svsb->volt_offset += 10;
> +			else
> +				svsb->volt_offset += 2;
> +			break;
> +		case SVS_CPU_BIG:
> +			svsb->bdes = svs->efuse[18] & 0xff;
> +			svsb->mdes = (svs->efuse[18] >> 8) & 0xff;
> +			svsb->dcbdet = (svs->efuse[18] >> 16) & 0xff;
> +			svsb->dcmdet = (svs->efuse[18] >> 24) & 0xff;
> +			svsb->mtdes  = svs->efuse[17] & 0xff;
> +
> +			if (ft_pgm <= 3)
> +				svsb->volt_offset += 15;
> +			else
> +				svsb->volt_offset += 12;
> +			break;
> +		case SVS_CCI:
> +			svsb->bdes = svs->efuse[4] & 0xff;
> +			svsb->mdes = (svs->efuse[4] >> 8) & 0xff;
> +			svsb->dcbdet = (svs->efuse[4] >> 16) & 0xff;
> +			svsb->dcmdet = (svs->efuse[4] >> 24) & 0xff;
> +			svsb->mtdes  = (svs->efuse[5] >> 16) & 0xff;
> +
> +			if (ft_pgm <= 3)
> +				svsb->volt_offset += 10;
> +			else
> +				svsb->volt_offset += 2;
> +			break;
> +		case SVS_GPU:
> +			svsb->bdes = svs->efuse[6] & 0xff;
> +			svsb->mdes = (svs->efuse[6] >> 8) & 0xff;
> +			svsb->dcbdet = (svs->efuse[6] >> 16) & 0xff;
> +			svsb->dcmdet = (svs->efuse[6] >> 24) & 0xff;
> +			svsb->mtdes  = svs->efuse[5] & 0xff;
> +
> +			if (ft_pgm >= 2) {
> +				svsb->freq_base = 800000000; /* 800MHz */
> +				svsb->dvt_fixed = 2;
> +			}
> +			break;
> +		default:
> +			break;
> +		}
> +	}
> +
> +	for (i = 0; i < svsp->efuse_num; i++) {
> +		if (svs->efuse[i])
> +			pr_notice("M_HW_RES%d: 0x%08x\n", i, svs->efuse[i]);
> +	}
> +
> +	/* thermal efuse parsing */
> +	if (!svs->thermal_efuse)
> +		return 0;
> +
> +	tp.adc_ge_t = (svs->thermal_efuse[1] >> 22) & 0x3ff;
> +	tp.adc_oe_t = (svs->thermal_efuse[1] >> 12) & 0x3ff;
> +
> +	tp.o_vtsmcu1 = (svs->thermal_efuse[0] >> 17) & 0x1ff;
> +	tp.o_vtsmcu2 = (svs->thermal_efuse[0] >> 8) & 0x1ff;
> +	tp.o_vtsmcu3 = svs->thermal_efuse[1] & 0x1ff;
> +	tp.o_vtsmcu4 = (svs->thermal_efuse[2] >> 23) & 0x1ff;
> +	tp.o_vtsmcu5 = (svs->thermal_efuse[2] >> 5) & 0x1ff;
> +	tp.o_vtsabb = (svs->thermal_efuse[2] >> 14) & 0x1ff;
> +
> +	tp.degc_cali = (svs->thermal_efuse[0] >> 1) & 0x3f;
> +	tp.adc_cali_en_t = svs->thermal_efuse[0] & BIT(0);
> +	tp.o_slope_sign = (svs->thermal_efuse[0] >> 7) & BIT(0);
> +
> +	tp.ts_id = (svs->thermal_efuse[1] >> 9) & BIT(0);
> +	tp.o_slope = (svs->thermal_efuse[0] >> 26) & 0x3f;
> +
> +	if (tp.adc_cali_en_t == 1) {
> +		if (tp.ts_id == 0)
> +			tp.o_slope = 0;
> +
> +		if ((tp.adc_ge_t < 265 || tp.adc_ge_t > 758) ||
> +		    (tp.adc_oe_t < 265 || tp.adc_oe_t > 758) ||
> +		    (tp.o_vtsmcu1 < -8 || tp.o_vtsmcu1 > 484) ||
> +		    (tp.o_vtsmcu2 < -8 || tp.o_vtsmcu2 > 484) ||
> +		    (tp.o_vtsmcu3 < -8 || tp.o_vtsmcu3 > 484) ||
> +		    (tp.o_vtsmcu4 < -8 || tp.o_vtsmcu4 > 484) ||
> +		    (tp.o_vtsmcu5 < -8 || tp.o_vtsmcu5 > 484) ||
> +		    (tp.o_vtsabb < -8 || tp.o_vtsabb > 484) ||
> +		    (tp.degc_cali < 1 || tp.degc_cali > 63)) {
> +			pr_err("bad thermal efuse data. disable mon mode\n");
> +			mon_mode_support = false;
> +		}
> +	} else {
> +		pr_err("no thermal efuse data. disable mon mode\n");
> +		mon_mode_support = false;
> +	}
> +
> +	if (!mon_mode_support) {
> +		for (i = 0; i < svsp->thermal_efuse_num; i++)
> +			pr_err("thermal_efuse[%u] = 0x%08x\n",
> +			       i, svs->thermal_efuse[i]);
> +
> +		for (idx = 0; idx < svsp->bank_num; idx++) {
> +			svsb = &svsp->banks[idx];
> +			svsb->mon_mode_support = false;
> +		}
> +
> +		return 0;
> +	}
> +
> +	tp.ge = ((tp.adc_ge_t - 512) * 10000) / 4096;
> +	tp.oe = (tp.adc_oe_t - 512);
> +	tp.gain = (10000 + tp.ge);
> +
> +	format[0] = (tp.o_vtsmcu1 + 3350 - tp.oe);
> +	format[1] = (tp.o_vtsmcu2 + 3350 - tp.oe);
> +	format[2] = (tp.o_vtsmcu3 + 3350 - tp.oe);
> +	format[3] = (tp.o_vtsmcu4 + 3350 - tp.oe);
> +	format[4] = (tp.o_vtsmcu5 + 3350 - tp.oe);
> +	format[5] = (tp.o_vtsabb + 3350 - tp.oe);
> +
> +	for (i = 0; i < 6; i++)
> +		x_roomt[i] = (((format[i] * 10000) / 4096) * 10000) / tp.gain;
> +
> +	temp0 = (10000 * 100000 / tp.gain) * 15 / 18;
> +
> +	if (tp.o_slope_sign == 0)
> +		mts = (temp0 * 10) / (1534 + tp.o_slope * 10);
> +	else
> +		mts = (temp0 * 10) / (1534 - tp.o_slope * 10);
> +
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		svsb->mts = mts;
> +
> +		switch (svsb->sw_id) {
> +		case SVS_CPU_LITTLE:
> +			tb_roomt = x_roomt[3];
> +			break;
> +		case SVS_CPU_BIG:
> +			tb_roomt = x_roomt[4];
> +			break;
> +		case SVS_CCI:
> +			tb_roomt = x_roomt[3];
> +			break;
> +		case SVS_GPU:
> +			tb_roomt = x_roomt[1];
> +			break;
> +		default:
> +			pr_err("unknown svsb_id = %u? disable svs\n",
> +			       svsb->sw_id);
> +			return -EINVAL;
> +		}
> +
> +		temp0 = (tp.degc_cali * 10 / 2);
> +		temp1 = ((10000 * 100000 / 4096 / tp.gain) *
> +			 tp.oe + tb_roomt * 10) * 15 / 18;
> +
> +		if (tp.o_slope_sign == 0)
> +			temp2 = temp1 * 100 / (1534 + tp.o_slope * 10);
> +		else
> +			temp2 = temp1 * 100 / (1534 - tp.o_slope * 10);
> +
> +		svsb->bts = (temp0 + temp2 - 250) * 4 / 10;
> +	}
> +
> +	return 0;
> +}
> +
> +static int svs_is_support(struct mtk_svs *svs)

nit: this appears to be a check if the platform supports SVS.  If so,
then it should probably be 'bool' and be called svs_is_supported().

> +{
> +	const struct svs_platform *svsp = svs->platform;
> +	struct svs_bank *svsb;
> +	struct nvmem_cell *cell;
> +	size_t len;
> +	int ret;
> +	u32 idx, i;
> +
> +	if (svsp->fake_efuse) {
> +		len = svsp->efuse_num * 4;
> +		svs->efuse = kzalloc(len, GFP_KERNEL);
> +		if (!svs->efuse)
> +			return -ENOMEM;
> +
> +		len = svsp->thermal_efuse_num * 4;
> +		svs->thermal_efuse = kzalloc(len, GFP_KERNEL);
> +		if (!svs->thermal_efuse)
> +			return -ENOMEM;
> +
> +		goto svsp_efuse_parsing;
> +	}
> +
> +	/* get svs efuse by nvmem */
> +	cell = nvmem_cell_get(svs->dev, "svs-calibration-data");
> +	if (IS_ERR(cell)) {
> +		pr_err("no \"svs-calibration-data\" from dts? disable svs\n");
> +		return PTR_ERR(cell);
> +	}
> +
> +	svs->efuse = (u32 *)nvmem_cell_read(cell, &len);
> +	nvmem_cell_put(cell);
> +
> +	ret = (svs->efuse[svsp->efuse_check] == 0) ? -EPERM : 0;
> +	if (ret) {
> +		pr_err("no svs efuse. disable svs.\n");
> +		for (i = 0; i < svsp->efuse_num; i++)
> +			pr_err("M_HW_RES%d: 0x%08x\n", i, svs->efuse[i]);
> +		return ret;
> +	}
> +
> +	/* get thermal efuse by nvmem */
> +	cell = nvmem_cell_get(svs->dev, "calibration-data");
> +	if (IS_ERR(cell)) {
> +		pr_err("no \"calibration-data\" from dts? disable mon mode\n");
> +		svs->thermal_efuse = NULL;
> +		for (idx = 0; idx < svsp->bank_num; idx++) {
> +			svsb = &svsp->banks[idx];
> +			svsb->mon_mode_support = false;
> +		}
> +		goto svsp_efuse_parsing;
> +	}
> +
> +	svs->thermal_efuse = (u32 *)nvmem_cell_read(cell, &len);
> +	nvmem_cell_put(cell);
> +
> +svsp_efuse_parsing:
> +	ret = svsp->efuse_parsing(svs);
> +
> +	return ret;
> +}
> +
> +static int svs_resource_setup(struct mtk_svs *svs)
> +{
> +	const struct svs_platform *svsp = svs->platform;
> +	struct svs_bank *svsb;
> +	struct platform_device *pdev;
> +	struct device_node *np = NULL;
> +	struct dev_pm_opp *opp;
> +	unsigned long freq;
> +	size_t opp_size;
> +	int count, ret;
> +	u32 idx, i;
> +
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +
> +		if (!svsb->init01_support)
> +			continue;
> +
> +		switch (svsb->sw_id) {
> +		case SVS_CPU_LITTLE:
> +			svsb->name = "SVS_CPU_LITTLE";
> +			break;
> +		case SVS_CPU_BIG:
> +			svsb->name = "SVS_CPU_BIG";
> +			break;
> +		case SVS_CCI:
> +			svsb->name = "SVS_CCI";
> +			break;
> +		case SVS_GPU:
> +			svsb->name = "SVS_GPU";
> +			break;
> +		default:
> +			WARN_ON(1);
> +			return -EINVAL;
> +		}
> +
> +		/* Add svs_bank device for opp-table/mtcmos/buck control */
> +		pdev = platform_device_alloc(svsb->name, 0);
> +		if (!pdev) {
> +			pr_err("%s: fail to alloc pdev for svs_bank\n",
> +			       svsb->name);
> +			return -ENOMEM;
> +		}
> +
> +		for_each_child_of_node(svs->dev->of_node, np) {
> +			if (of_device_is_compatible(np, svsb->of_compatible)) {
> +				pdev->dev.of_node = np;
> +				break;
> +			}
> +		}
> +
> +		ret = platform_device_add(pdev);
> +		if (ret) {
> +			pr_err("%s: fail to add svs_bank device: %d\n",
> +			       svsb->name, ret);
> +			return ret;
> +		}
> +
> +		svsb->dev = &pdev->dev;
> +		dev_set_drvdata(svsb->dev, svs);
> +		ret = dev_pm_opp_of_add_table(svsb->dev);
> +		if (ret) {
> +			pr_err("%s: fail to add opp table: %d\n",
> +			       svsb->name, ret);
> +			return ret;
> +		}
> +
> +		mutex_init(&svsb->lock);
> +
> +		svsb->buck = devm_regulator_get_optional(svsb->dev,
> +							 svsb->buck_name);
> +		if (IS_ERR(svsb->buck)) {
> +			pr_err("%s: cannot get regulator \"%s-supply\"\n",
> +			       svsb->name, svsb->buck_name);
> +			return PTR_ERR(svsb->buck);
> +		}
> +
> +		count = dev_pm_opp_get_opp_count(svsb->dev);
> +		if (svsb->opp_count != count) {
> +			pr_err("%s: opp_count not \"%u\" but get \"%d\"?\n",
> +			       svsb->name, svsb->opp_count, count);
> +			return count;
> +		}
> +
> +		opp_size = 4 * svsb->opp_count;
> +		svsb->opp_volts = kmalloc(opp_size, GFP_KERNEL);
> +		if (!svsb->opp_volts)
> +			return -ENOMEM;
> +
> +		svsb->init02_volts = kmalloc(opp_size, GFP_KERNEL);
> +		if (!svsb->init02_volts)
> +			return -ENOMEM;
> +
> +		svsb->volts = kmalloc(opp_size, GFP_KERNEL);
> +		if (!svsb->volts)
> +			return -ENOMEM;
> +
> +		svsb->opp_freqs = kmalloc(opp_size, GFP_KERNEL);
> +		if (!svsb->opp_freqs)
> +			return -ENOMEM;
> +
> +		svsb->freqs_pct = kmalloc(opp_size, GFP_KERNEL);
> +		if (!svsb->freqs_pct)
> +			return -ENOMEM;
> +
> +		for (i = 0, freq = (u32)-1; i < svsb->opp_count; i++, freq--) {
> +			opp = dev_pm_opp_find_freq_floor(svsb->dev, &freq);
> +			if (IS_ERR(opp)) {
> +				pr_err("%s: error opp entry!!, err = %ld\n",
> +				       svsb->name, PTR_ERR(opp));
> +				return PTR_ERR(opp);
> +			}
> +
> +			svsb->opp_freqs[i] = freq;
> +			svsb->opp_volts[i] = dev_pm_opp_get_voltage(opp);
> +			svsb->freqs_pct[i] = percent(svsb->opp_freqs[i],
> +						     svsb->freq_base) & 0xff;
> +		}
> +	}
> +
> +	return 0;
> +}

There are lots of resources (platform_device, all the kmalloc regions)
that are never free'd here.  You might consider using devm for this.

Related, all the small malloc's are calculated based on the opp_count
for each bank, but they are all hard-coded to 16.   Seems it would be
better to have a default/max size for this in the bank structure itself
instead of making these small allocations.

> +static int svs_suspend(struct device *dev)
> +{
> +	struct mtk_svs *svs = dev_get_drvdata(dev);
> +	const struct svs_platform *svsp = svs->platform;
> +	struct svs_bank *svsb;
> +	unsigned long flags;
> +	u32 idx;
> +
> +	/* Wait if there is processing svs_isr(). Suspend all banks. */
> +	flags = claim_mtk_svs_lock();
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		svs->bank = svsb;
> +		svs_switch_bank(svs);
> +		svs_writel(svs, 0x0, SVSEN);
> +		svs_writel(svs, 0x00ffffff, INTSTS);

I'm assuming this part will disable future interrupts?

I'm not seeing where they get re-enabled on the resume path.


> +		svsb->suspended = true;
> +	}
> +	release_mtk_svs_lock(flags);
> +
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		if (svsb->phase == SVS_PHASE_MON) {
> +			svsb->phase = SVS_PHASE_INIT02;
> +			svs_set_volts(svsb, true);
> +		}
> +	}
> +
> +	clk_disable_unprepare(svs->main_clk);
> +
> +	return 0;
> +}
> +
> +static int svs_resume(struct device *dev)
> +{
> +	struct mtk_svs *svs = dev_get_drvdata(dev);
> +	const struct svs_platform *svsp = svs->platform;
> +	struct svs_bank *svsb;
> +	int ret;
> +	u32 idx;
> +
> +	ret = clk_prepare_enable(svs->main_clk);
> +	if (ret)
> +		pr_err("%s(): cannot enable main_clk\n", __func__);
> +
> +	for (idx = 0; idx < svsp->bank_num; idx++) {
> +		svsb = &svsp->banks[idx];
> +		svsb->suspended = false;
> +	}
> +
> +	ret = svs_init02(svs);
> +	if (ret)
> +		return ret;
> +
> +	svs_mon_mode(svs);
> +
> +	return 0;
> +}

Kevin



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