linux/drivers/clk/clk-versaclock7.c

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// SPDX-License-Identifier: GPL-2.0
/*
* Common clock framework driver for the Versaclock7 family of timing devices.
*
* Copyright (c) 2022 Renesas Electronics Corporation
*/
#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
#include <linux/bitfield.h>
#include <linux/clk.h>
#include <linux/clk-provider.h>
#include <linux/i2c.h>
#include <linux/math64.h>
#include <linux/module.h>
#include <linux/of.h>
#include <linux/property.h>
#include <linux/regmap.h>
#include <linux/swab.h>
/*
* 16-bit register address: the lower 8 bits of the register address come
* from the offset addr byte and the upper 8 bits come from the page register.
*/
#define VC7_PAGE_ADDR 0xFD
#define VC7_PAGE_WINDOW 256
#define VC7_MAX_REG 0x364
/* Maximum number of banks supported by VC7 */
#define VC7_NUM_BANKS 7
/* Maximum number of FODs supported by VC7 */
#define VC7_NUM_FOD 3
/* Maximum number of IODs supported by VC7 */
#define VC7_NUM_IOD 4
/* Maximum number of outputs supported by VC7 */
#define VC7_NUM_OUT 12
/* VCO valid range is 9.5 GHz to 10.7 GHz */
#define VC7_APLL_VCO_MIN 9500000000UL
#define VC7_APLL_VCO_MAX 10700000000UL
/* APLL denominator is fixed at 2^27 */
#define VC7_APLL_DENOMINATOR_BITS 27
/* FOD 1st stage denominator is fixed 2^34 */
#define VC7_FOD_DENOMINATOR_BITS 34
/* IOD can operate between 1kHz and 650MHz */
#define VC7_IOD_RATE_MIN 1000UL
#define VC7_IOD_RATE_MAX 650000000UL
#define VC7_IOD_MIN_DIVISOR 14
#define VC7_IOD_MAX_DIVISOR 0x1ffffff /* 25-bit */
#define VC7_FOD_RATE_MIN 1000UL
#define VC7_FOD_RATE_MAX 650000000UL
#define VC7_FOD_1ST_STAGE_RATE_MIN 33000000UL /* 33 MHz */
#define VC7_FOD_1ST_STAGE_RATE_MAX 650000000UL /* 650 MHz */
#define VC7_FOD_1ST_INT_MAX 324
#define VC7_FOD_2ND_INT_MIN 2
#define VC7_FOD_2ND_INT_MAX 0x1ffff /* 17-bit */
/* VC7 Registers */
#define VC7_REG_XO_CNFG 0x2C
#define VC7_REG_XO_CNFG_COUNT 4
#define VC7_REG_XO_IB_H_DIV_SHIFT 24
#define VC7_REG_XO_IB_H_DIV_MASK GENMASK(28, VC7_REG_XO_IB_H_DIV_SHIFT)
#define VC7_REG_APLL_FB_DIV_FRAC 0x120
#define VC7_REG_APLL_FB_DIV_FRAC_COUNT 4
#define VC7_REG_APLL_FB_DIV_FRAC_MASK GENMASK(26, 0)
#define VC7_REG_APLL_FB_DIV_INT 0x124
#define VC7_REG_APLL_FB_DIV_INT_COUNT 2
#define VC7_REG_APLL_FB_DIV_INT_MASK GENMASK(9, 0)
#define VC7_REG_APLL_CNFG 0x127
#define VC7_REG_APLL_EN_DOUBLER BIT(0)
#define VC7_REG_OUT_BANK_CNFG(idx) (0x280 + (0x4 * (idx)))
#define VC7_REG_OUTPUT_BANK_SRC_MASK GENMASK(2, 0)
#define VC7_REG_FOD_INT_CNFG(idx) (0x1E0 + (0x10 * (idx)))
#define VC7_REG_FOD_INT_CNFG_COUNT 8
#define VC7_REG_FOD_1ST_INT_MASK GENMASK(8, 0)
#define VC7_REG_FOD_2ND_INT_SHIFT 9
#define VC7_REG_FOD_2ND_INT_MASK GENMASK(25, VC7_REG_FOD_2ND_INT_SHIFT)
#define VC7_REG_FOD_FRAC_SHIFT 26
#define VC7_REG_FOD_FRAC_MASK GENMASK_ULL(59, VC7_REG_FOD_FRAC_SHIFT)
#define VC7_REG_IOD_INT_CNFG(idx) (0x1C0 + (0x8 * (idx)))
#define VC7_REG_IOD_INT_CNFG_COUNT 4
#define VC7_REG_IOD_INT_MASK GENMASK(24, 0)
#define VC7_REG_ODRV_EN(idx) (0x240 + (0x4 * (idx)))
#define VC7_REG_OUT_DIS BIT(0)
struct vc7_driver_data;
static const struct regmap_config vc7_regmap_config;
/* Supported Renesas VC7 models */
enum vc7_model {
VC7_RC21008A,
};
struct vc7_chip_info {
const enum vc7_model model;
const unsigned int banks[VC7_NUM_BANKS];
const unsigned int num_banks;
const unsigned int outputs[VC7_NUM_OUT];
const unsigned int num_outputs;
};
/*
* Changing the APLL frequency is currently not supported.
* The APLL will consist of an opaque block between the XO and FOD/IODs and
* its frequency will be computed based on the current state of the device.
*/
struct vc7_apll_data {
struct clk *clk;
struct vc7_driver_data *vc7;
u8 xo_ib_h_div;
u8 en_doubler;
u16 apll_fb_div_int;
u32 apll_fb_div_frac;
};
struct vc7_fod_data {
struct clk_hw hw;
struct vc7_driver_data *vc7;
unsigned int num;
u32 fod_1st_int;
u32 fod_2nd_int;
u64 fod_frac;
};
struct vc7_iod_data {
struct clk_hw hw;
struct vc7_driver_data *vc7;
unsigned int num;
u32 iod_int;
};
struct vc7_out_data {
struct clk_hw hw;
struct vc7_driver_data *vc7;
unsigned int num;
unsigned int out_dis;
};
struct vc7_driver_data {
struct i2c_client *client;
struct regmap *regmap;
const struct vc7_chip_info *chip_info;
struct clk *pin_xin;
struct vc7_apll_data clk_apll;
struct vc7_fod_data clk_fod[VC7_NUM_FOD];
struct vc7_iod_data clk_iod[VC7_NUM_IOD];
struct vc7_out_data clk_out[VC7_NUM_OUT];
};
struct vc7_bank_src_map {
enum vc7_bank_src_type {
VC7_FOD,
VC7_IOD,
} type;
union _divider {
struct vc7_iod_data *iod;
struct vc7_fod_data *fod;
} src;
};
static struct clk_hw *vc7_of_clk_get(struct of_phandle_args *clkspec,
void *data)
{
struct vc7_driver_data *vc7 = data;
unsigned int idx = clkspec->args[0];
if (idx >= vc7->chip_info->num_outputs)
return ERR_PTR(-EINVAL);
return &vc7->clk_out[idx].hw;
}
static const unsigned int RC21008A_index_to_output_mapping[] = {
1, 2, 3, 6, 7, 8, 10, 11
};
static int vc7_map_index_to_output(const enum vc7_model model, const unsigned int i)
{
switch (model) {
case VC7_RC21008A:
return RC21008A_index_to_output_mapping[i];
default:
return i;
}
}
/* bank to output mapping, same across all variants */
static const unsigned int output_bank_mapping[] = {
0, /* Output 0 */
1, /* Output 1 */
2, /* Output 2 */
2, /* Output 3 */
3, /* Output 4 */
3, /* Output 5 */
3, /* Output 6 */
3, /* Output 7 */
4, /* Output 8 */
4, /* Output 9 */
5, /* Output 10 */
6 /* Output 11 */
};
/**
* vc7_64_mul_64_to_128() - Multiply two u64 and return an unsigned 128-bit integer
* as an upper and lower part.
*
* @left: The left argument.
* @right: The right argument.
* @hi: The upper 64-bits of the 128-bit product.
* @lo: The lower 64-bits of the 128-bit product.
*
* From mul_64_64 in crypto/ecc.c:350 in the linux kernel, accessed in v5.17.2.
*/
static void vc7_64_mul_64_to_128(u64 left, u64 right, u64 *hi, u64 *lo)
{
u64 a0 = left & 0xffffffffull;
u64 a1 = left >> 32;
u64 b0 = right & 0xffffffffull;
u64 b1 = right >> 32;
u64 m0 = a0 * b0;
u64 m1 = a0 * b1;
u64 m2 = a1 * b0;
u64 m3 = a1 * b1;
m2 += (m0 >> 32);
m2 += m1;
/* Overflow */
if (m2 < m1)
m3 += 0x100000000ull;
*lo = (m0 & 0xffffffffull) | (m2 << 32);
*hi = m3 + (m2 >> 32);
}
/**
* vc7_128_div_64_to_64() - Divides a 128-bit uint by a 64-bit divisor, return a 64-bit quotient.
*
* @numhi: The uppper 64-bits of the dividend.
* @numlo: The lower 64-bits of the dividend.
* @den: The denominator (divisor).
* @r: The remainder, pass NULL if the remainder is not needed.
*
* Originally from libdivide, modified to use kernel u64/u32 types.
*
* See https://github.com/ridiculousfish/libdivide/blob/master/libdivide.h#L471.
*
* Return: The 64-bit quotient of the division.
*
* In case of overflow of division by zero, max(u64) is returned.
*/
static u64 vc7_128_div_64_to_64(u64 numhi, u64 numlo, u64 den, u64 *r)
{
/*
* We work in base 2**32.
* A uint32 holds a single digit. A uint64 holds two digits.
* Our numerator is conceptually [num3, num2, num1, num0].
* Our denominator is [den1, den0].
*/
const u64 b = ((u64)1 << 32);
/* The high and low digits of our computed quotient. */
u32 q1, q0;
/* The normalization shift factor */
int shift;
/*
* The high and low digits of our denominator (after normalizing).
* Also the low 2 digits of our numerator (after normalizing).
*/
u32 den1, den0, num1, num0;
/* A partial remainder; */
u64 rem;
/*
* The estimated quotient, and its corresponding remainder (unrelated
* to true remainder).
*/
u64 qhat, rhat;
/* Variables used to correct the estimated quotient. */
u64 c1, c2;
/* Check for overflow and divide by 0. */
if (numhi >= den) {
if (r)
*r = ~0ull;
return ~0ull;
}
/*
* Determine the normalization factor. We multiply den by this, so that
* its leading digit is at least half b. In binary this means just
* shifting left by the number of leading zeros, so that there's a 1 in
* the MSB.
*
* We also shift numer by the same amount. This cannot overflow because
* numhi < den. The expression (-shift & 63) is the same as (64 -
* shift), except it avoids the UB of shifting by 64. The funny bitwise
* 'and' ensures that numlo does not get shifted into numhi if shift is
* 0. clang 11 has an x86 codegen bug here: see LLVM bug 50118. The
* sequence below avoids it.
*/
shift = __builtin_clzll(den);
den <<= shift;
numhi <<= shift;
numhi |= (numlo >> (-shift & 63)) & (-(s64)shift >> 63);
numlo <<= shift;
/*
* Extract the low digits of the numerator and both digits of the
* denominator.
*/
num1 = (u32)(numlo >> 32);
num0 = (u32)(numlo & 0xFFFFFFFFu);
den1 = (u32)(den >> 32);
den0 = (u32)(den & 0xFFFFFFFFu);
/*
* We wish to compute q1 = [n3 n2 n1] / [d1 d0].
* Estimate q1 as [n3 n2] / [d1], and then correct it.
* Note while qhat may be 2 digits, q1 is always 1 digit.
*/
qhat = div64_u64_rem(numhi, den1, &rhat);
c1 = qhat * den0;
c2 = rhat * b + num1;
if (c1 > c2)
qhat -= (c1 - c2 > den) ? 2 : 1;
q1 = (u32)qhat;
/* Compute the true (partial) remainder. */
rem = numhi * b + num1 - q1 * den;
/*
* We wish to compute q0 = [rem1 rem0 n0] / [d1 d0].
* Estimate q0 as [rem1 rem0] / [d1] and correct it.
*/
qhat = div64_u64_rem(rem, den1, &rhat);
c1 = qhat * den0;
c2 = rhat * b + num0;
if (c1 > c2)
qhat -= (c1 - c2 > den) ? 2 : 1;
q0 = (u32)qhat;
/* Return remainder if requested. */
if (r)
*r = (rem * b + num0 - q0 * den) >> shift;
return ((u64)q1 << 32) | q0;
}
static int vc7_get_bank_clk(struct vc7_driver_data *vc7,
unsigned int bank_idx,
unsigned int output_bank_src,
struct vc7_bank_src_map *map)
{
/* Mapping from Table 38 in datasheet */
if (bank_idx == 0 || bank_idx == 1) {
switch (output_bank_src) {
case 0:
map->type = VC7_IOD,
map->src.iod = &vc7->clk_iod[0];
return 0;
case 1:
map->type = VC7_IOD,
map->src.iod = &vc7->clk_iod[1];
return 0;
case 4:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[0];
return 0;
case 5:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[1];
return 0;
default:
break;
}
} else if (bank_idx == 2) {
switch (output_bank_src) {
case 1:
map->type = VC7_IOD,
map->src.iod = &vc7->clk_iod[1];
return 0;
case 4:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[0];
return 0;
case 5:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[1];
return 0;
default:
break;
}
} else if (bank_idx == 3) {
switch (output_bank_src) {
case 4:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[0];
return 0;
case 5:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[1];
return 0;
case 6:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[2];
return 0;
default:
break;
}
} else if (bank_idx == 4) {
switch (output_bank_src) {
case 0:
/* CLKIN1 not supported in this driver */
break;
case 2:
map->type = VC7_IOD,
map->src.iod = &vc7->clk_iod[2];
return 0;
case 5:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[1];
return 0;
case 6:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[2];
return 0;
case 7:
/* CLKIN0 not supported in this driver */
break;
default:
break;
}
} else if (bank_idx == 5) {
switch (output_bank_src) {
case 0:
/* CLKIN1 not supported in this driver */
break;
case 1:
/* XIN_REFIN not supported in this driver */
break;
case 2:
map->type = VC7_IOD,
map->src.iod = &vc7->clk_iod[2];
return 0;
case 3:
map->type = VC7_IOD,
map->src.iod = &vc7->clk_iod[3];
return 0;
case 5:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[1];
return 0;
case 6:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[2];
return 0;
case 7:
/* CLKIN0 not supported in this driver */
break;
default:
break;
}
} else if (bank_idx == 6) {
switch (output_bank_src) {
case 0:
/* CLKIN1 not supported in this driver */
break;
case 2:
map->type = VC7_IOD,
map->src.iod = &vc7->clk_iod[2];
return 0;
case 3:
map->type = VC7_IOD,
map->src.iod = &vc7->clk_iod[3];
return 0;
case 5:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[1];
return 0;
case 6:
map->type = VC7_FOD,
map->src.fod = &vc7->clk_fod[2];
return 0;
case 7:
/* CLKIN0 not supported in this driver */
break;
default:
break;
}
}
pr_warn("bank_src%d = %d is not supported\n", bank_idx, output_bank_src);
return -1;
}
static int vc7_read_apll(struct vc7_driver_data *vc7)
{
int err;
u32 val32;
u16 val16;
err = regmap_bulk_read(vc7->regmap,
VC7_REG_XO_CNFG,
(u32 *)&val32,
VC7_REG_XO_CNFG_COUNT);
if (err) {
dev_err(&vc7->client->dev, "failed to read XO_CNFG\n");
return err;
}
vc7->clk_apll.xo_ib_h_div = (val32 & VC7_REG_XO_IB_H_DIV_MASK)
>> VC7_REG_XO_IB_H_DIV_SHIFT;
err = regmap_read(vc7->regmap,
VC7_REG_APLL_CNFG,
&val32);
if (err) {
dev_err(&vc7->client->dev, "failed to read APLL_CNFG\n");
return err;
}
vc7->clk_apll.en_doubler = val32 & VC7_REG_APLL_EN_DOUBLER;
err = regmap_bulk_read(vc7->regmap,
VC7_REG_APLL_FB_DIV_FRAC,
(u32 *)&val32,
VC7_REG_APLL_FB_DIV_FRAC_COUNT);
if (err) {
dev_err(&vc7->client->dev, "failed to read APLL_FB_DIV_FRAC\n");
return err;
}
vc7->clk_apll.apll_fb_div_frac = val32 & VC7_REG_APLL_FB_DIV_FRAC_MASK;
err = regmap_bulk_read(vc7->regmap,
VC7_REG_APLL_FB_DIV_INT,
(u16 *)&val16,
VC7_REG_APLL_FB_DIV_INT_COUNT);
if (err) {
dev_err(&vc7->client->dev, "failed to read APLL_FB_DIV_INT\n");
return err;
}
vc7->clk_apll.apll_fb_div_int = val16 & VC7_REG_APLL_FB_DIV_INT_MASK;
return 0;
}
static int vc7_read_fod(struct vc7_driver_data *vc7, unsigned int idx)
{
int err;
u64 val;
err = regmap_bulk_read(vc7->regmap,
VC7_REG_FOD_INT_CNFG(idx),
(u64 *)&val,
VC7_REG_FOD_INT_CNFG_COUNT);
if (err) {
dev_err(&vc7->client->dev, "failed to read FOD%d\n", idx);
return err;
}
vc7->clk_fod[idx].fod_1st_int = (val & VC7_REG_FOD_1ST_INT_MASK);
vc7->clk_fod[idx].fod_2nd_int =
(val & VC7_REG_FOD_2ND_INT_MASK) >> VC7_REG_FOD_2ND_INT_SHIFT;
vc7->clk_fod[idx].fod_frac = (val & VC7_REG_FOD_FRAC_MASK)
>> VC7_REG_FOD_FRAC_SHIFT;
return 0;
}
static int vc7_write_fod(struct vc7_driver_data *vc7, unsigned int idx)
{
int err;
u64 val;
/*
* FOD dividers are part of an atomic group where fod_1st_int,
* fod_2nd_int, and fod_frac must be written together. The new divider
* is applied when the MSB of fod_frac is written.
*/
err = regmap_bulk_read(vc7->regmap,
VC7_REG_FOD_INT_CNFG(idx),
(u64 *)&val,
VC7_REG_FOD_INT_CNFG_COUNT);
if (err) {
dev_err(&vc7->client->dev, "failed to read FOD%d\n", idx);
return err;
}
val = u64_replace_bits(val,
vc7->clk_fod[idx].fod_1st_int,
VC7_REG_FOD_1ST_INT_MASK);
val = u64_replace_bits(val,
vc7->clk_fod[idx].fod_2nd_int,
VC7_REG_FOD_2ND_INT_MASK);
val = u64_replace_bits(val,
vc7->clk_fod[idx].fod_frac,
VC7_REG_FOD_FRAC_MASK);
err = regmap_bulk_write(vc7->regmap,
VC7_REG_FOD_INT_CNFG(idx),
(u64 *)&val,
sizeof(u64));
if (err) {
dev_err(&vc7->client->dev, "failed to write FOD%d\n", idx);
return err;
}
return 0;
}
static int vc7_read_iod(struct vc7_driver_data *vc7, unsigned int idx)
{
int err;
u32 val;
err = regmap_bulk_read(vc7->regmap,
VC7_REG_IOD_INT_CNFG(idx),
(u32 *)&val,
VC7_REG_IOD_INT_CNFG_COUNT);
if (err) {
dev_err(&vc7->client->dev, "failed to read IOD%d\n", idx);
return err;
}
vc7->clk_iod[idx].iod_int = (val & VC7_REG_IOD_INT_MASK);
return 0;
}
static int vc7_write_iod(struct vc7_driver_data *vc7, unsigned int idx)
{
int err;
u32 val;
/*
* IOD divider field is atomic and all bits must be written.
* The new divider is applied when the MSB of iod_int is written.
*/
err = regmap_bulk_read(vc7->regmap,
VC7_REG_IOD_INT_CNFG(idx),
(u32 *)&val,
VC7_REG_IOD_INT_CNFG_COUNT);
if (err) {
dev_err(&vc7->client->dev, "failed to read IOD%d\n", idx);
return err;
}
val = u32_replace_bits(val,
vc7->clk_iod[idx].iod_int,
VC7_REG_IOD_INT_MASK);
err = regmap_bulk_write(vc7->regmap,
VC7_REG_IOD_INT_CNFG(idx),
(u32 *)&val,
sizeof(u32));
if (err) {
dev_err(&vc7->client->dev, "failed to write IOD%d\n", idx);
return err;
}
return 0;
}
static int vc7_read_output(struct vc7_driver_data *vc7, unsigned int idx)
{
int err;
unsigned int val, out_num;
out_num = vc7_map_index_to_output(vc7->chip_info->model, idx);
err = regmap_read(vc7->regmap,
VC7_REG_ODRV_EN(out_num),
&val);
if (err) {
dev_err(&vc7->client->dev, "failed to read ODRV_EN[%d]\n", idx);
return err;
}
vc7->clk_out[idx].out_dis = val & VC7_REG_OUT_DIS;
return 0;
}
static int vc7_write_output(struct vc7_driver_data *vc7, unsigned int idx)
{
int err;
unsigned int out_num;
out_num = vc7_map_index_to_output(vc7->chip_info->model, idx);
err = regmap_write_bits(vc7->regmap,
VC7_REG_ODRV_EN(out_num),
VC7_REG_OUT_DIS,
vc7->clk_out[idx].out_dis);
if (err) {
dev_err(&vc7->client->dev, "failed to write ODRV_EN[%d]\n", idx);
return err;
}
return 0;
}
static unsigned long vc7_get_apll_rate(struct vc7_driver_data *vc7)
{
int err;
unsigned long xtal_rate;
u64 refin_div, apll_rate;
xtal_rate = clk_get_rate(vc7->pin_xin);
err = vc7_read_apll(vc7);
if (err) {
dev_err(&vc7->client->dev, "unable to read apll\n");
return err;
}
/* 0 is bypassed, 1 is reserved */
if (vc7->clk_apll.xo_ib_h_div < 2)
refin_div = xtal_rate;
else
refin_div = div64_u64(xtal_rate, vc7->clk_apll.xo_ib_h_div);
if (vc7->clk_apll.en_doubler)
refin_div *= 2;
/* divider = int + (frac / 2^27) */
apll_rate = (refin_div * vc7->clk_apll.apll_fb_div_int) +
((refin_div * vc7->clk_apll.apll_fb_div_frac) >> VC7_APLL_DENOMINATOR_BITS);
pr_debug("%s - xo_ib_h_div: %u, apll_fb_div_int: %u, apll_fb_div_frac: %u\n",
__func__, vc7->clk_apll.xo_ib_h_div, vc7->clk_apll.apll_fb_div_int,
vc7->clk_apll.apll_fb_div_frac);
pr_debug("%s - refin_div: %llu, apll rate: %llu\n",
__func__, refin_div, apll_rate);
return apll_rate;
}
static void vc7_calc_iod_divider(unsigned long rate, unsigned long parent_rate,
u32 *divider)
{
*divider = DIV_ROUND_UP(parent_rate, rate);
if (*divider < VC7_IOD_MIN_DIVISOR)
*divider = VC7_IOD_MIN_DIVISOR;
if (*divider > VC7_IOD_MAX_DIVISOR)
*divider = VC7_IOD_MAX_DIVISOR;
}
static void vc7_calc_fod_1st_stage(unsigned long rate, unsigned long parent_rate,
u32 *div_int, u64 *div_frac)
{
u64 rem;
*div_int = (u32)div64_u64_rem(parent_rate, rate, &rem);
*div_frac = div64_u64(rem << VC7_FOD_DENOMINATOR_BITS, rate);
}
static unsigned long vc7_calc_fod_1st_stage_rate(unsigned long parent_rate,
u32 fod_1st_int, u64 fod_frac)
{
u64 numer, denom, hi, lo, divisor;
numer = fod_frac;
denom = BIT_ULL(VC7_FOD_DENOMINATOR_BITS);
if (fod_frac) {
vc7_64_mul_64_to_128(parent_rate, denom, &hi, &lo);
divisor = ((u64)fod_1st_int * denom) + numer;
return vc7_128_div_64_to_64(hi, lo, divisor, NULL);
}
return div64_u64(parent_rate, fod_1st_int);
}
static unsigned long vc7_calc_fod_2nd_stage_rate(unsigned long parent_rate,
u32 fod_1st_int, u32 fod_2nd_int, u64 fod_frac)
{
unsigned long fod_1st_stage_rate;
fod_1st_stage_rate = vc7_calc_fod_1st_stage_rate(parent_rate, fod_1st_int, fod_frac);
if (fod_2nd_int < 2)
return fod_1st_stage_rate;
/*
* There is a div-by-2 preceding the 2nd stage integer divider
* (not shown on block diagram) so the actual 2nd stage integer
* divisor is 2 * N.
*/
return div64_u64(fod_1st_stage_rate >> 1, fod_2nd_int);
}
static void vc7_calc_fod_divider(unsigned long rate, unsigned long parent_rate,
u32 *fod_1st_int, u32 *fod_2nd_int, u64 *fod_frac)
{
unsigned int allow_frac, i, best_frac_i;
unsigned long first_stage_rate;
vc7_calc_fod_1st_stage(rate, parent_rate, fod_1st_int, fod_frac);
first_stage_rate = vc7_calc_fod_1st_stage_rate(parent_rate, *fod_1st_int, *fod_frac);
*fod_2nd_int = 0;
/* Do we need the second stage integer divider? */
if (first_stage_rate < VC7_FOD_1ST_STAGE_RATE_MIN) {
allow_frac = 0;
best_frac_i = VC7_FOD_2ND_INT_MIN;
for (i = VC7_FOD_2ND_INT_MIN; i <= VC7_FOD_2ND_INT_MAX; i++) {
/*
* 1) There is a div-by-2 preceding the 2nd stage integer divider
* (not shown on block diagram) so the actual 2nd stage integer
* divisor is 2 * N.
* 2) Attempt to find an integer solution first. This means stepping
* through each 2nd stage integer and recalculating the 1st stage
* until the 1st stage frequency is out of bounds. If no integer
* solution is found, use the best fractional solution.
*/
vc7_calc_fod_1st_stage(parent_rate, rate * 2 * i, fod_1st_int, fod_frac);
first_stage_rate = vc7_calc_fod_1st_stage_rate(parent_rate,
*fod_1st_int,
*fod_frac);
/* Remember the first viable fractional solution */
if (best_frac_i == VC7_FOD_2ND_INT_MIN &&
first_stage_rate > VC7_FOD_1ST_STAGE_RATE_MIN) {
best_frac_i = i;
}
/* Is the divider viable? Prefer integer solutions over fractional. */
if (*fod_1st_int < VC7_FOD_1ST_INT_MAX &&
first_stage_rate >= VC7_FOD_1ST_STAGE_RATE_MIN &&
(allow_frac || *fod_frac == 0)) {
*fod_2nd_int = i;
break;
}
/* Ran out of divisors or the 1st stage frequency is out of range */
if (i >= VC7_FOD_2ND_INT_MAX ||
first_stage_rate > VC7_FOD_1ST_STAGE_RATE_MAX) {
allow_frac = 1;
i = best_frac_i;
/* Restore the best frac and rerun the loop for the last time */
if (best_frac_i != VC7_FOD_2ND_INT_MIN)
i--;
continue;
}
}
}
}
static unsigned long vc7_fod_recalc_rate(struct clk_hw *hw, unsigned long parent_rate)
{
struct vc7_fod_data *fod = container_of(hw, struct vc7_fod_data, hw);
struct vc7_driver_data *vc7 = fod->vc7;
int err;
unsigned long fod_rate;
err = vc7_read_fod(vc7, fod->num);
if (err) {
dev_err(&vc7->client->dev, "error reading registers for %s\n",
clk_hw_get_name(hw));
return err;
}
pr_debug("%s - %s: parent_rate: %lu\n", __func__, clk_hw_get_name(hw), parent_rate);
fod_rate = vc7_calc_fod_2nd_stage_rate(parent_rate, fod->fod_1st_int,
fod->fod_2nd_int, fod->fod_frac);
pr_debug("%s - %s: fod_1st_int: %u, fod_2nd_int: %u, fod_frac: %llu\n",
__func__, clk_hw_get_name(hw),
fod->fod_1st_int, fod->fod_2nd_int, fod->fod_frac);
pr_debug("%s - %s rate: %lu\n", __func__, clk_hw_get_name(hw), fod_rate);
return fod_rate;
}
static long vc7_fod_round_rate(struct clk_hw *hw, unsigned long rate, unsigned long *parent_rate)
{
struct vc7_fod_data *fod = container_of(hw, struct vc7_fod_data, hw);
unsigned long fod_rate;
pr_debug("%s - %s: requested rate: %lu, parent_rate: %lu\n",
__func__, clk_hw_get_name(hw), rate, *parent_rate);
vc7_calc_fod_divider(rate, *parent_rate,
&fod->fod_1st_int, &fod->fod_2nd_int, &fod->fod_frac);
fod_rate = vc7_calc_fod_2nd_stage_rate(*parent_rate, fod->fod_1st_int,
fod->fod_2nd_int, fod->fod_frac);
pr_debug("%s - %s: fod_1st_int: %u, fod_2nd_int: %u, fod_frac: %llu\n",
__func__, clk_hw_get_name(hw),
fod->fod_1st_int, fod->fod_2nd_int, fod->fod_frac);
pr_debug("%s - %s rate: %lu\n", __func__, clk_hw_get_name(hw), fod_rate);
return fod_rate;
}
static int vc7_fod_set_rate(struct clk_hw *hw, unsigned long rate, unsigned long parent_rate)
{
struct vc7_fod_data *fod = container_of(hw, struct vc7_fod_data, hw);
struct vc7_driver_data *vc7 = fod->vc7;
unsigned long fod_rate;
pr_debug("%s - %s: rate: %lu, parent_rate: %lu\n",
__func__, clk_hw_get_name(hw), rate, parent_rate);
if (rate < VC7_FOD_RATE_MIN || rate > VC7_FOD_RATE_MAX) {
dev_err(&vc7->client->dev,
"requested frequency %lu Hz for %s is out of range\n",
rate, clk_hw_get_name(hw));
return -EINVAL;
}
vc7_write_fod(vc7, fod->num);
fod_rate = vc7_calc_fod_2nd_stage_rate(parent_rate, fod->fod_1st_int,
fod->fod_2nd_int, fod->fod_frac);
pr_debug("%s - %s: fod_1st_int: %u, fod_2nd_int: %u, fod_frac: %llu\n",
__func__, clk_hw_get_name(hw),
fod->fod_1st_int, fod->fod_2nd_int, fod->fod_frac);
pr_debug("%s - %s rate: %lu\n", __func__, clk_hw_get_name(hw), fod_rate);
return 0;
}
static const struct clk_ops vc7_fod_ops = {
.recalc_rate = vc7_fod_recalc_rate,
.round_rate = vc7_fod_round_rate,
.set_rate = vc7_fod_set_rate,
};
static unsigned long vc7_iod_recalc_rate(struct clk_hw *hw, unsigned long parent_rate)
{
struct vc7_iod_data *iod = container_of(hw, struct vc7_iod_data, hw);
struct vc7_driver_data *vc7 = iod->vc7;
int err;
unsigned long iod_rate;
err = vc7_read_iod(vc7, iod->num);
if (err) {
dev_err(&vc7->client->dev, "error reading registers for %s\n",
clk_hw_get_name(hw));
return err;
}
iod_rate = div64_u64(parent_rate, iod->iod_int);
pr_debug("%s - %s: iod_int: %u\n", __func__, clk_hw_get_name(hw), iod->iod_int);
pr_debug("%s - %s rate: %lu\n", __func__, clk_hw_get_name(hw), iod_rate);
return iod_rate;
}
static long vc7_iod_round_rate(struct clk_hw *hw, unsigned long rate, unsigned long *parent_rate)
{
struct vc7_iod_data *iod = container_of(hw, struct vc7_iod_data, hw);
unsigned long iod_rate;
pr_debug("%s - %s: requested rate: %lu, parent_rate: %lu\n",
__func__, clk_hw_get_name(hw), rate, *parent_rate);
vc7_calc_iod_divider(rate, *parent_rate, &iod->iod_int);
iod_rate = div64_u64(*parent_rate, iod->iod_int);
pr_debug("%s - %s: iod_int: %u\n", __func__, clk_hw_get_name(hw), iod->iod_int);
pr_debug("%s - %s rate: %ld\n", __func__, clk_hw_get_name(hw), iod_rate);
return iod_rate;
}
static int vc7_iod_set_rate(struct clk_hw *hw, unsigned long rate, unsigned long parent_rate)
{
struct vc7_iod_data *iod = container_of(hw, struct vc7_iod_data, hw);
struct vc7_driver_data *vc7 = iod->vc7;
unsigned long iod_rate;
pr_debug("%s - %s: rate: %lu, parent_rate: %lu\n",
__func__, clk_hw_get_name(hw), rate, parent_rate);
if (rate < VC7_IOD_RATE_MIN || rate > VC7_IOD_RATE_MAX) {
dev_err(&vc7->client->dev,
"requested frequency %lu Hz for %s is out of range\n",
rate, clk_hw_get_name(hw));
return -EINVAL;
}
vc7_write_iod(vc7, iod->num);
iod_rate = div64_u64(parent_rate, iod->iod_int);
pr_debug("%s - %s: iod_int: %u\n", __func__, clk_hw_get_name(hw), iod->iod_int);
pr_debug("%s - %s rate: %ld\n", __func__, clk_hw_get_name(hw), iod_rate);
return 0;
}
static const struct clk_ops vc7_iod_ops = {
.recalc_rate = vc7_iod_recalc_rate,
.round_rate = vc7_iod_round_rate,
.set_rate = vc7_iod_set_rate,
};
static int vc7_clk_out_prepare(struct clk_hw *hw)
{
struct vc7_out_data *out = container_of(hw, struct vc7_out_data, hw);
struct vc7_driver_data *vc7 = out->vc7;
int err;
out->out_dis = 0;
err = vc7_write_output(vc7, out->num);
if (err) {
dev_err(&vc7->client->dev, "error writing registers for %s\n",
clk_hw_get_name(hw));
return err;
}
pr_debug("%s - %s: clk prepared\n", __func__, clk_hw_get_name(hw));
return 0;
}
static void vc7_clk_out_unprepare(struct clk_hw *hw)
{
struct vc7_out_data *out = container_of(hw, struct vc7_out_data, hw);
struct vc7_driver_data *vc7 = out->vc7;
int err;
out->out_dis = 1;
err = vc7_write_output(vc7, out->num);
if (err) {
dev_err(&vc7->client->dev, "error writing registers for %s\n",
clk_hw_get_name(hw));
return;
}
pr_debug("%s - %s: clk unprepared\n", __func__, clk_hw_get_name(hw));
}
static int vc7_clk_out_is_enabled(struct clk_hw *hw)
{
struct vc7_out_data *out = container_of(hw, struct vc7_out_data, hw);
struct vc7_driver_data *vc7 = out->vc7;
int err, is_enabled;
err = vc7_read_output(vc7, out->num);
if (err) {
dev_err(&vc7->client->dev, "error reading registers for %s\n",
clk_hw_get_name(hw));
return err;
}
is_enabled = !out->out_dis;
pr_debug("%s - %s: is_enabled=%d\n", __func__, clk_hw_get_name(hw), is_enabled);
return is_enabled;
}
static const struct clk_ops vc7_clk_out_ops = {
.prepare = vc7_clk_out_prepare,
.unprepare = vc7_clk_out_unprepare,
.is_enabled = vc7_clk_out_is_enabled,
};
static int vc7_probe(struct i2c_client *client)
{
struct vc7_driver_data *vc7;
struct clk_init_data clk_init;
struct vc7_bank_src_map bank_src_map;
const char *node_name, *apll_name;
const char *parent_names[1];
unsigned int i, val, bank_idx, out_num;
unsigned long apll_rate;
int ret;
vc7 = devm_kzalloc(&client->dev, sizeof(*vc7), GFP_KERNEL);
if (!vc7)
return -ENOMEM;
i2c_set_clientdata(client, vc7);
vc7->client = client;
vc7->chip_info = i2c_get_match_data(client);
vc7->pin_xin = devm_clk_get(&client->dev, "xin");
if (PTR_ERR(vc7->pin_xin) == -EPROBE_DEFER) {
return dev_err_probe(&client->dev, -EPROBE_DEFER,
"xin not specified\n");
}
vc7->regmap = devm_regmap_init_i2c(client, &vc7_regmap_config);
if (IS_ERR(vc7->regmap)) {
return dev_err_probe(&client->dev, PTR_ERR(vc7->regmap),
"failed to allocate register map\n");
}
if (of_property_read_string(client->dev.of_node, "clock-output-names",
&node_name))
node_name = client->dev.of_node->name;
/* Register APLL */
apll_rate = vc7_get_apll_rate(vc7);
apll_name = kasprintf(GFP_KERNEL, "%s_apll", node_name);
vc7->clk_apll.clk = clk_register_fixed_rate(&client->dev, apll_name,
__clk_get_name(vc7->pin_xin),
0, apll_rate);
kfree(apll_name); /* ccf made a copy of the name */
if (IS_ERR(vc7->clk_apll.clk)) {
return dev_err_probe(&client->dev, PTR_ERR(vc7->clk_apll.clk),
"failed to register apll\n");
}
/* Register FODs */
for (i = 0; i < VC7_NUM_FOD; i++) {
memset(&clk_init, 0, sizeof(clk_init));
clk_init.name = kasprintf(GFP_KERNEL, "%s_fod%d", node_name, i);
clk_init.ops = &vc7_fod_ops;
clk_init.parent_names = parent_names;
parent_names[0] = __clk_get_name(vc7->clk_apll.clk);
clk_init.num_parents = 1;
vc7->clk_fod[i].num = i;
vc7->clk_fod[i].vc7 = vc7;
vc7->clk_fod[i].hw.init = &clk_init;
ret = devm_clk_hw_register(&client->dev, &vc7->clk_fod[i].hw);
if (ret)
goto err_clk_register;
kfree(clk_init.name); /* ccf made a copy of the name */
}
/* Register IODs */
for (i = 0; i < VC7_NUM_IOD; i++) {
memset(&clk_init, 0, sizeof(clk_init));
clk_init.name = kasprintf(GFP_KERNEL, "%s_iod%d", node_name, i);
clk_init.ops = &vc7_iod_ops;
clk_init.parent_names = parent_names;
parent_names[0] = __clk_get_name(vc7->clk_apll.clk);
clk_init.num_parents = 1;
vc7->clk_iod[i].num = i;
vc7->clk_iod[i].vc7 = vc7;
vc7->clk_iod[i].hw.init = &clk_init;
ret = devm_clk_hw_register(&client->dev, &vc7->clk_iod[i].hw);
if (ret)
goto err_clk_register;
kfree(clk_init.name); /* ccf made a copy of the name */
}
/* Register outputs */
for (i = 0; i < vc7->chip_info->num_outputs; i++) {
out_num = vc7_map_index_to_output(vc7->chip_info->model, i);
/*
* This driver does not support remapping FOD/IOD to banks.
* The device state is read and the driver is setup to match
* the device's existing mapping.
*/
bank_idx = output_bank_mapping[out_num];
regmap_read(vc7->regmap, VC7_REG_OUT_BANK_CNFG(bank_idx), &val);
val &= VC7_REG_OUTPUT_BANK_SRC_MASK;
memset(&bank_src_map, 0, sizeof(bank_src_map));
ret = vc7_get_bank_clk(vc7, bank_idx, val, &bank_src_map);
if (ret) {
dev_err_probe(&client->dev, ret,
"unable to register output %d\n", i);
return ret;
}
switch (bank_src_map.type) {
case VC7_FOD:
parent_names[0] = clk_hw_get_name(&bank_src_map.src.fod->hw);
break;
case VC7_IOD:
parent_names[0] = clk_hw_get_name(&bank_src_map.src.iod->hw);
break;
}
memset(&clk_init, 0, sizeof(clk_init));
clk_init.name = kasprintf(GFP_KERNEL, "%s_out%d", node_name, i);
clk_init.ops = &vc7_clk_out_ops;
clk_init.flags = CLK_SET_RATE_PARENT;
clk_init.parent_names = parent_names;
clk_init.num_parents = 1;
vc7->clk_out[i].num = i;
vc7->clk_out[i].vc7 = vc7;
vc7->clk_out[i].hw.init = &clk_init;
ret = devm_clk_hw_register(&client->dev, &vc7->clk_out[i].hw);
if (ret)
goto err_clk_register;
kfree(clk_init.name); /* ccf made a copy of the name */
}
ret = of_clk_add_hw_provider(client->dev.of_node, vc7_of_clk_get, vc7);
if (ret) {
dev_err_probe(&client->dev, ret, "unable to add clk provider\n");
goto err_clk;
}
return ret;
err_clk_register:
dev_err_probe(&client->dev, ret,
"unable to register %s\n", clk_init.name);
kfree(clk_init.name); /* ccf made a copy of the name */
err_clk:
clk_unregister_fixed_rate(vc7->clk_apll.clk);
return ret;
}
Here's the main clk pull request for this merge window. We have some late breaking reports that a patch series to rework clk rate range support broke boot on some devices, so I've left that branch out of this PR. Hopefully we can get to that next week, or punt on it and let it bake another cycle. That means we don't really have any changes to the core framework this time around besides a few typo fixes. Instead this is all clk driver updates and fixes. The usual suspects are here (again), with Qualcomm dominating the diffstat. We look to have gained support for quite a few new Qualcomm SoCs and Dmitry worked on updating many of the existing Qualcomm drivers to use clk_parent_data. After that we have MediaTek drivers getting some much needed updates, in particular to support GPU DVFS. There are also quite a few Samsung clk driver patches, but that's mostly because there was a maintainer change and so last release we missed some of those patches. Overall things look normal, but I'm slowly reviewing core framework code nowadays and that shows given the rate range patches had to be yanked last minute. Let's hope this situation changes soon. New Drivers: - Support for Renesas VersaClock7 clock generator family - Add Spreadtrum UMS512 SoC clk support - New clock drivers for MediaTek Helio X10 MT6795 - Display clks for Qualcomm SM6115, SM8450 - GPU clks for Qualcomm SC8280XP - Qualcomm MSM8909 and SM6375 global and SMD RPM clk drivers Deleted Drivers: - Remove DaVinci DM644x and DM646x clk driver support Updates: - Convert Baikal-T1 CCU driver to platform driver - Split reset support out of primary Baikal-T1 CCU driver - Add some missing clks required for RPiVid Video Decoder on RaspberryPi - Mark PLLC critical on bcm2835 - More devm helpers for fixed rate registration - Various PXA168 clk driver fixes - Add resets for MediaTek MT8195 PCIe and USB - Miscellaneous of_node_put() fixes - Nuke dt-bindings/clk path (again) by moving headers to dt-bindings/clock - Convert gpio-clk-gate binding to YAML - Various fixes to AMD/Xilinx Zynqmp clk driver - Graduate AMD/Xilinx "clocking wizard" driver from staging - Add missing DPI1_HDMI clock in MT8195 VDOSYS1 - Clock driver changes to support GPU DVFS on MT8183, MT8192, MT8195 - Fix GPU clock topology on MT8195 - Propogate rate changes from GPU clock gate up the tree - Clock mux notifiers for GPU-related PLLs - Conversion of more "simple" drivers to mtk_clk_simple_probe() - Hook up mtk_clk_simple_remove() for "simple" MT8192 clock drivers - Fixes to previous |struct clk| to |struct clk_hw| conversion on MediaTek - Shrink MT8192 clock driver by deduplicating clock parent lists - Change order between 'sim_enet_root_clk' and 'enet_qos_root_clk' clocks for i.MX8MP - Drop unnecessary newline in i.MX8MM dt-bindings - Add more MU1 and SAI clocks dt-bindings Ids - Introduce slice busy bit check for i.MX93 composite clock - Introduce white list bit check for i.MX93 composite clock - Add new i.MX93 clock gate - Add MU1 and MU2 clocks to i.MX93 clock provider - Add SAI IPG clocks to i.MX93 clock provider - add generic clocks for U(S)ART available on SAMA5D2 SoCs - reset controller support for Polarfire clocks - .round_rate and .set rate support for clk-mpfs - code cleanup for clk-mpfs - PLL support for PolarFire SoC's Clock Conditioning Circuitry - Add watchdog, I2C, pin control/GPIO, and Ethernet clocks on R-Car V4H - Add SDHI, Timer (CMT/TMU), and SPI (MSIOF) clocks on R-Car S4-8 - Add I2C clocks and resets on RZ/V2M - Document clock support for the RZ/Five SoC - mux-variant clock using the table variant to select parents - clock controller for the rv1126 soc - conversion of rk3128 to yaml and relicensing of the yaml bindings to gpl2+MIT (following dt-binding guildelines) - Exynos7885: add FSYS, TREX and MFC clock controllers - Exynos850: add IS and AUD (audio) clock controllers with bindings - ExynosAutov9: add FSYS clock controllers with bindings - ExynosAutov9: correct clock IDs in bindings of Peric 0 and 1 clock controllers, due to duplicated entries. This is an acceptable ABI break: recently developed/added platform so without legacies, acked by known users/developers - ExynosAutov9: add few missing Peric 0/1 gates - ExynosAutov9: correct register offsets of few Peric 0/1 clocks - Minor code improvements (use of_device_get_match_data() helper, code style) - Add Krzysztof Kozlowski as co-maintainer of Samsung SoC clocks, as he already maintainers that architecture/platform - Keep Qualcomm GDSCs enabled when PWRSTS_RET flag is there, solving retention issues during suspend of USB on Qualcomm sc7180/sc7280 and SC8280XP - Qualcomm SM6115 and QCM2260 are moved to reuse PLL configuration - Qualcomm SDM660 SDCC1 moved to floor clk ops - Support for the APCS PLLs for Qualcomm IPQ8064, IPQ8074 and IPQ6018 was added/fixed - The Qualcomm MSM8996 CPU clocks are updated with support for ACD - Support for Qualcomm SDM670 GCC and RPMh clks was added - Transition to parent_data, parent_hws and use of ARRAY_SIZE() for num_parents was done for many Qualcomm SoCs - Support for per-reset defined delay on Qualcomm was introduced -----BEGIN PGP SIGNATURE----- iQJFBAABCAAvFiEE9L57QeeUxqYDyoaDrQKIl8bklSUFAmM/trwRHHNib3lkQGtl cm5lbC5vcmcACgkQrQKIl8bklSUEoA/+LiftbrF8Xtu7lGdxRjqLzRftUmHaUQWO d0cadtzMsgxzFJsxp99IiJBVJoaYCBOGlnZDx8p/JGv+mmdhl5+yHgKQbR8nEmTk 5A+bdA1okOdm8SPBPMcLvuMjsgmx+DHkuxvnC2hT8ZGfQDoa+6PnObpP30LJkHT0 oVY8g8ScEuHI5eJcNz3UgxAetKeJd+WRQPxKCrjsOeyhWuNAJ7wdTVQjjzH49X4C RS3fjeHvhr2VZm23IgildY++a6hPO72gtBjEpDRoFwnmWAVqUtxiwptoJJNkC5kB toD/ndQHOLh/XOJFKgksS20L4JHtSp5F3Ma8sIuOjAXmDCyqMdTQhydnl5Pyrow+ ct8BMUGkx0Sw8pXBJYINtHpwTtIxvLu/sBNqBb/lRCWd8byrPlUnKvF/COcoxp27 miZTwJI28fHU5a2K/46iWZCI5YUvVcnBSz8WbEWWvOltIT8S0JvZozA3KuRm5vys /k2HaQwO2I0QWQzPjfg6SRlTTWH6p+Hc47fSg7LSM6Scsb7ZraajTM2QOvgn7Mgp m/136q7jr9mvuLqqy1fBY3F2hDZYNSJX+UfmIFcpCyxvht0GVFN9YCc+Ibgyl2vQ P3b9LXV2OqhtDJg6ds7v8aPgAGUwUFO8GTPBG1cuom7z5u/kdIpjKaFAyr8wWSuJ wqPIFevggsA= =9jI+ -----END PGP SIGNATURE----- Merge tag 'clk-for-linus' of git://git.kernel.org/pub/scm/linux/kernel/git/clk/linux Pull clk updates from Stephen Boyd: "We have some late breaking reports that a patch series to rework clk rate range support broke boot on some devices, so I've left that branch out of this. Hopefully we can get to that next week, or punt on it and let it bake another cycle. That means we don't really have any changes to the core framework this time around besides a few typo fixes. Instead this is all clk driver updates and fixes. The usual suspects are here (again), with Qualcomm dominating the diffstat. We look to have gained support for quite a few new Qualcomm SoCs and Dmitry worked on updating many of the existing Qualcomm drivers to use clk_parent_data. After that we have MediaTek drivers getting some much needed updates, in particular to support GPU DVFS. There are also quite a few Samsung clk driver patches, but that's mostly because there was a maintainer change and so last release we missed some of those patches. Overall things look normal, but I'm slowly reviewing core framework code nowadays and that shows given the rate range patches had to be yanked last minute. Let's hope this situation changes soon. New Drivers: - Support for Renesas VersaClock7 clock generator family - Add Spreadtrum UMS512 SoC clk support - New clock drivers for MediaTek Helio X10 MT6795 - Display clks for Qualcomm SM6115, SM8450 - GPU clks for Qualcomm SC8280XP - Qualcomm MSM8909 and SM6375 global and SMD RPM clk drivers Deleted Drivers: - Remove DaVinci DM644x and DM646x clk driver support Updates: - Convert Baikal-T1 CCU driver to platform driver - Split reset support out of primary Baikal-T1 CCU driver - Add some missing clks required for RPiVid Video Decoder on RaspberryPi - Mark PLLC critical on bcm2835 - More devm helpers for fixed rate registration - Various PXA168 clk driver fixes - Add resets for MediaTek MT8195 PCIe and USB - Miscellaneous of_node_put() fixes - Nuke dt-bindings/clk path (again) by moving headers to dt-bindings/clock - Convert gpio-clk-gate binding to YAML - Various fixes to AMD/Xilinx Zynqmp clk driver - Graduate AMD/Xilinx "clocking wizard" driver from staging - Add missing DPI1_HDMI clock in MT8195 VDOSYS1 - Clock driver changes to support GPU DVFS on MT8183, MT8192, MT8195 - Fix GPU clock topology on MT8195 - Propogate rate changes from GPU clock gate up the tree - Clock mux notifiers for GPU-related PLLs - Conversion of more "simple" drivers to mtk_clk_simple_probe() - Hook up mtk_clk_simple_remove() for "simple" MT8192 clock drivers - Fixes to previous |struct clk| to |struct clk_hw| conversion on MediaTek - Shrink MT8192 clock driver by deduplicating clock parent lists - Change order between 'sim_enet_root_clk' and 'enet_qos_root_clk' clocks for i.MX8MP - Drop unnecessary newline in i.MX8MM dt-bindings - Add more MU1 and SAI clocks dt-bindings Ids - Introduce slice busy bit check for i.MX93 composite clock - Introduce white list bit check for i.MX93 composite clock - Add new i.MX93 clock gate - Add MU1 and MU2 clocks to i.MX93 clock provider - Add SAI IPG clocks to i.MX93 clock provider - add generic clocks for U(S)ART available on SAMA5D2 SoCs - reset controller support for Polarfire clocks - .round_rate and .set rate support for clk-mpfs - code cleanup for clk-mpfs - PLL support for PolarFire SoC's Clock Conditioning Circuitry - Add watchdog, I2C, pin control/GPIO, and Ethernet clocks on R-Car V4H - Add SDHI, Timer (CMT/TMU), and SPI (MSIOF) clocks on R-Car S4-8 - Add I2C clocks and resets on RZ/V2M - Document clock support for the RZ/Five SoC - mux-variant clock using the table variant to select parents - clock controller for the rv1126 soc - conversion of rk3128 to yaml and relicensing of the yaml bindings to gpl2+MIT (following dt-binding guildelines) - Exynos7885: add FSYS, TREX and MFC clock controllers - Exynos850: add IS and AUD (audio) clock controllers with bindings - ExynosAutov9: add FSYS clock controllers with bindings - ExynosAutov9: correct clock IDs in bindings of Peric 0 and 1 clock controllers, due to duplicated entries. This is an acceptable ABI break: recently developed/added platform so without legacies, acked by known users/developers - ExynosAutov9: add few missing Peric 0/1 gates - ExynosAutov9: correct register offsets of few Peric 0/1 clocks - Minor code improvements (use of_device_get_match_data() helper, code style) - Add Krzysztof Kozlowski as co-maintainer of Samsung SoC clocks, as he already maintainers that architecture/platform - Keep Qualcomm GDSCs enabled when PWRSTS_RET flag is there, solving retention issues during suspend of USB on Qualcomm sc7180/sc7280 and SC8280XP - Qualcomm SM6115 and QCM2260 are moved to reuse PLL configuration - Qualcomm SDM660 SDCC1 moved to floor clk ops - Support for the APCS PLLs for Qualcomm IPQ8064, IPQ8074 and IPQ6018 was added/fixed - The Qualcomm MSM8996 CPU clocks are updated with support for ACD - Support for Qualcomm SDM670 GCC and RPMh clks was added - Transition to parent_data, parent_hws and use of ARRAY_SIZE() for num_parents was done for many Qualcomm SoCs - Support for per-reset defined delay on Qualcomm was introduced" * tag 'clk-for-linus' of git://git.kernel.org/pub/scm/linux/kernel/git/clk/linux: (283 commits) clk: qcom: gcc-sm6375: Ensure unsigned long type clk: qcom: gcc-sm6375: Remove unused variables clk: qcom: kpss-xcc: convert to parent data API clk: introduce (devm_)hw_register_mux_parent_data_table API clk: allow building lan966x as a module clk: clk-xgene: simplify if-if to if-else clk: ast2600: BCLK comes from EPLL clk: clocking-wizard: Depend on HAS_IOMEM clk: clocking-wizard: Use dev_err_probe() helper clk: nxp: fix typo in comment clk: pxa: add a check for the return value of kzalloc() clk: vc5: Add support for IDT/Renesas VersaClock 5P49V6975 dt-bindings: clock: vc5: Add 5P49V6975 clk: mvebu: armada-37xx-tbg: Remove the unneeded result variable clk: ti: dra7-atl: Fix reference leak in of_dra7_atl_clk_probe clk: Renesas versaclock7 ccf device driver dt-bindings: Renesas versaclock7 device tree bindings clk: ti: Balance of_node_get() calls for of_find_node_by_name() clk: imx: scu: fix memleak on platform_device_add() fails clk: vc5: Use regmap_{set,clear}_bits() where appropriate ...
2022-10-08 20:06:48 +03:00
static void vc7_remove(struct i2c_client *client)
{
struct vc7_driver_data *vc7 = i2c_get_clientdata(client);
of_clk_del_provider(client->dev.of_node);
clk_unregister_fixed_rate(vc7->clk_apll.clk);
}
static bool vc7_volatile_reg(struct device *dev, unsigned int reg)
{
if (reg == VC7_PAGE_ADDR)
return false;
return true;
}
static const struct vc7_chip_info vc7_rc21008a_info = {
.model = VC7_RC21008A,
.num_banks = 6,
.num_outputs = 8,
};
static struct regmap_range_cfg vc7_range_cfg[] = {
{
.range_min = 0,
.range_max = VC7_MAX_REG,
.selector_reg = VC7_PAGE_ADDR,
.selector_mask = 0xFF,
.selector_shift = 0,
.window_start = 0,
.window_len = VC7_PAGE_WINDOW,
}};
static const struct regmap_config vc7_regmap_config = {
.reg_bits = 8,
.val_bits = 8,
.max_register = VC7_MAX_REG,
.ranges = vc7_range_cfg,
.num_ranges = ARRAY_SIZE(vc7_range_cfg),
.volatile_reg = vc7_volatile_reg,
.cache_type = REGCACHE_MAPLE,
.can_multi_write = true,
.reg_format_endian = REGMAP_ENDIAN_LITTLE,
.val_format_endian = REGMAP_ENDIAN_LITTLE,
};
static const struct i2c_device_id vc7_i2c_id[] = {
{ "rc21008a", .driver_data = (kernel_ulong_t)&vc7_rc21008a_info },
{}
};
MODULE_DEVICE_TABLE(i2c, vc7_i2c_id);
static const struct of_device_id vc7_of_match[] = {
{ .compatible = "renesas,rc21008a", .data = &vc7_rc21008a_info },
{}
};
MODULE_DEVICE_TABLE(of, vc7_of_match);
static struct i2c_driver vc7_i2c_driver = {
.driver = {
.name = "vc7",
.of_match_table = vc7_of_match,
},
.probe = vc7_probe,
.remove = vc7_remove,
.id_table = vc7_i2c_id,
};
module_i2c_driver(vc7_i2c_driver);
MODULE_LICENSE("GPL");
MODULE_AUTHOR("Alex Helms <alexander.helms.jy@renesas.com");
MODULE_DESCRIPTION("Renesas Versaclock7 common clock framework driver");