Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Alex Helms | 5863 | 99.76% | 1 | 20.00% |
Marek Vašut | 12 | 0.20% | 2 | 40.00% |
Linus Torvalds | 1 | 0.02% | 1 | 20.00% |
Uwe Kleine-König | 1 | 0.02% | 1 | 20.00% |
Total | 5877 | 5 |
// 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/of_platform.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 = device_get_match_data(&client->dev); 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; } 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_RBTREE, .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");
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