Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Stefan Popa | 2870 | 99.58% | 3 | 50.00% |
Nuno Sá | 6 | 0.21% | 1 | 16.67% |
Jonathan Cameron | 5 | 0.17% | 1 | 16.67% |
Uwe Kleine-König | 1 | 0.03% | 1 | 16.67% |
Total | 2882 | 6 |
// SPDX-License-Identifier: GPL-2.0 /* * Analog Devices ADF4371 SPI Wideband Synthesizer driver * * Copyright 2019 Analog Devices Inc. */ #include <linux/bitfield.h> #include <linux/clk.h> #include <linux/device.h> #include <linux/err.h> #include <linux/gcd.h> #include <linux/kernel.h> #include <linux/module.h> #include <linux/regmap.h> #include <linux/sysfs.h> #include <linux/spi/spi.h> #include <linux/iio/iio.h> /* Registers address macro */ #define ADF4371_REG(x) (x) /* ADF4371_REG0 */ #define ADF4371_ADDR_ASC_MSK BIT(2) #define ADF4371_ADDR_ASC(x) FIELD_PREP(ADF4371_ADDR_ASC_MSK, x) #define ADF4371_ADDR_ASC_R_MSK BIT(5) #define ADF4371_ADDR_ASC_R(x) FIELD_PREP(ADF4371_ADDR_ASC_R_MSK, x) #define ADF4371_RESET_CMD 0x81 /* ADF4371_REG17 */ #define ADF4371_FRAC2WORD_L_MSK GENMASK(7, 1) #define ADF4371_FRAC2WORD_L(x) FIELD_PREP(ADF4371_FRAC2WORD_L_MSK, x) #define ADF4371_FRAC1WORD_MSK BIT(0) #define ADF4371_FRAC1WORD(x) FIELD_PREP(ADF4371_FRAC1WORD_MSK, x) /* ADF4371_REG18 */ #define ADF4371_FRAC2WORD_H_MSK GENMASK(6, 0) #define ADF4371_FRAC2WORD_H(x) FIELD_PREP(ADF4371_FRAC2WORD_H_MSK, x) /* ADF4371_REG1A */ #define ADF4371_MOD2WORD_MSK GENMASK(5, 0) #define ADF4371_MOD2WORD(x) FIELD_PREP(ADF4371_MOD2WORD_MSK, x) /* ADF4371_REG24 */ #define ADF4371_RF_DIV_SEL_MSK GENMASK(6, 4) #define ADF4371_RF_DIV_SEL(x) FIELD_PREP(ADF4371_RF_DIV_SEL_MSK, x) /* ADF4371_REG25 */ #define ADF4371_MUTE_LD_MSK BIT(7) #define ADF4371_MUTE_LD(x) FIELD_PREP(ADF4371_MUTE_LD_MSK, x) /* ADF4371_REG32 */ #define ADF4371_TIMEOUT_MSK GENMASK(1, 0) #define ADF4371_TIMEOUT(x) FIELD_PREP(ADF4371_TIMEOUT_MSK, x) /* ADF4371_REG34 */ #define ADF4371_VCO_ALC_TOUT_MSK GENMASK(4, 0) #define ADF4371_VCO_ALC_TOUT(x) FIELD_PREP(ADF4371_VCO_ALC_TOUT_MSK, x) /* Specifications */ #define ADF4371_MIN_VCO_FREQ 4000000000ULL /* 4000 MHz */ #define ADF4371_MAX_VCO_FREQ 8000000000ULL /* 8000 MHz */ #define ADF4371_MAX_OUT_RF8_FREQ ADF4371_MAX_VCO_FREQ /* Hz */ #define ADF4371_MIN_OUT_RF8_FREQ (ADF4371_MIN_VCO_FREQ / 64) /* Hz */ #define ADF4371_MAX_OUT_RF16_FREQ (ADF4371_MAX_VCO_FREQ * 2) /* Hz */ #define ADF4371_MIN_OUT_RF16_FREQ (ADF4371_MIN_VCO_FREQ * 2) /* Hz */ #define ADF4371_MAX_OUT_RF32_FREQ (ADF4371_MAX_VCO_FREQ * 4) /* Hz */ #define ADF4371_MIN_OUT_RF32_FREQ (ADF4371_MIN_VCO_FREQ * 4) /* Hz */ #define ADF4371_MAX_FREQ_PFD 250000000UL /* Hz */ #define ADF4371_MAX_FREQ_REFIN 600000000UL /* Hz */ /* MOD1 is a 24-bit primary modulus with fixed value of 2^25 */ #define ADF4371_MODULUS1 33554432ULL /* MOD2 is the programmable, 14-bit auxiliary fractional modulus */ #define ADF4371_MAX_MODULUS2 BIT(14) #define ADF4371_CHECK_RANGE(freq, range) \ ((freq > ADF4371_MAX_ ## range) || (freq < ADF4371_MIN_ ## range)) enum { ADF4371_FREQ, ADF4371_POWER_DOWN, ADF4371_CHANNEL_NAME }; enum { ADF4371_CH_RF8, ADF4371_CH_RFAUX8, ADF4371_CH_RF16, ADF4371_CH_RF32 }; enum adf4371_variant { ADF4371, ADF4372 }; struct adf4371_pwrdown { unsigned int reg; unsigned int bit; }; static const char * const adf4371_ch_names[] = { "RF8x", "RFAUX8x", "RF16x", "RF32x" }; static const struct adf4371_pwrdown adf4371_pwrdown_ch[4] = { [ADF4371_CH_RF8] = { ADF4371_REG(0x25), 2 }, [ADF4371_CH_RFAUX8] = { ADF4371_REG(0x72), 3 }, [ADF4371_CH_RF16] = { ADF4371_REG(0x25), 3 }, [ADF4371_CH_RF32] = { ADF4371_REG(0x25), 4 }, }; static const struct reg_sequence adf4371_reg_defaults[] = { { ADF4371_REG(0x0), 0x18 }, { ADF4371_REG(0x12), 0x40 }, { ADF4371_REG(0x1E), 0x48 }, { ADF4371_REG(0x20), 0x14 }, { ADF4371_REG(0x22), 0x00 }, { ADF4371_REG(0x23), 0x00 }, { ADF4371_REG(0x24), 0x80 }, { ADF4371_REG(0x25), 0x07 }, { ADF4371_REG(0x27), 0xC5 }, { ADF4371_REG(0x28), 0x83 }, { ADF4371_REG(0x2C), 0x44 }, { ADF4371_REG(0x2D), 0x11 }, { ADF4371_REG(0x2E), 0x12 }, { ADF4371_REG(0x2F), 0x94 }, { ADF4371_REG(0x32), 0x04 }, { ADF4371_REG(0x35), 0xFA }, { ADF4371_REG(0x36), 0x30 }, { ADF4371_REG(0x39), 0x07 }, { ADF4371_REG(0x3A), 0x55 }, { ADF4371_REG(0x3E), 0x0C }, { ADF4371_REG(0x3F), 0x80 }, { ADF4371_REG(0x40), 0x50 }, { ADF4371_REG(0x41), 0x28 }, { ADF4371_REG(0x47), 0xC0 }, { ADF4371_REG(0x52), 0xF4 }, { ADF4371_REG(0x70), 0x03 }, { ADF4371_REG(0x71), 0x60 }, { ADF4371_REG(0x72), 0x32 }, }; static const struct regmap_config adf4371_regmap_config = { .reg_bits = 16, .val_bits = 8, .read_flag_mask = BIT(7), }; struct adf4371_chip_info { unsigned int num_channels; const struct iio_chan_spec *channels; }; struct adf4371_state { struct spi_device *spi; struct regmap *regmap; struct clk *clkin; /* * Lock for accessing device registers. Some operations require * multiple consecutive R/W operations, during which the device * shouldn't be interrupted. The buffers are also shared across * all operations so need to be protected on stand alone reads and * writes. */ struct mutex lock; const struct adf4371_chip_info *chip_info; unsigned long clkin_freq; unsigned long fpfd; unsigned int integer; unsigned int fract1; unsigned int fract2; unsigned int mod2; unsigned int rf_div_sel; unsigned int ref_div_factor; u8 buf[10] __aligned(IIO_DMA_MINALIGN); }; static unsigned long long adf4371_pll_fract_n_get_rate(struct adf4371_state *st, u32 channel) { unsigned long long val, tmp; unsigned int ref_div_sel; val = (((u64)st->integer * ADF4371_MODULUS1) + st->fract1) * st->fpfd; tmp = (u64)st->fract2 * st->fpfd; do_div(tmp, st->mod2); val += tmp + ADF4371_MODULUS1 / 2; if (channel == ADF4371_CH_RF8 || channel == ADF4371_CH_RFAUX8) ref_div_sel = st->rf_div_sel; else ref_div_sel = 0; do_div(val, ADF4371_MODULUS1 * (1 << ref_div_sel)); if (channel == ADF4371_CH_RF16) val <<= 1; else if (channel == ADF4371_CH_RF32) val <<= 2; return val; } static void adf4371_pll_fract_n_compute(unsigned long long vco, unsigned long long pfd, unsigned int *integer, unsigned int *fract1, unsigned int *fract2, unsigned int *mod2) { unsigned long long tmp; u32 gcd_div; tmp = do_div(vco, pfd); tmp = tmp * ADF4371_MODULUS1; *fract2 = do_div(tmp, pfd); *integer = vco; *fract1 = tmp; *mod2 = pfd; while (*mod2 > ADF4371_MAX_MODULUS2) { *mod2 >>= 1; *fract2 >>= 1; } gcd_div = gcd(*fract2, *mod2); *mod2 /= gcd_div; *fract2 /= gcd_div; } static int adf4371_set_freq(struct adf4371_state *st, unsigned long long freq, unsigned int channel) { u32 cp_bleed; u8 int_mode = 0; int ret; switch (channel) { case ADF4371_CH_RF8: case ADF4371_CH_RFAUX8: if (ADF4371_CHECK_RANGE(freq, OUT_RF8_FREQ)) return -EINVAL; st->rf_div_sel = 0; while (freq < ADF4371_MIN_VCO_FREQ) { freq <<= 1; st->rf_div_sel++; } break; case ADF4371_CH_RF16: /* ADF4371 RF16 8000...16000 MHz */ if (ADF4371_CHECK_RANGE(freq, OUT_RF16_FREQ)) return -EINVAL; freq >>= 1; break; case ADF4371_CH_RF32: /* ADF4371 RF32 16000...32000 MHz */ if (ADF4371_CHECK_RANGE(freq, OUT_RF32_FREQ)) return -EINVAL; freq >>= 2; break; default: return -EINVAL; } adf4371_pll_fract_n_compute(freq, st->fpfd, &st->integer, &st->fract1, &st->fract2, &st->mod2); st->buf[0] = st->integer >> 8; st->buf[1] = 0x40; /* REG12 default */ st->buf[2] = 0x00; st->buf[3] = st->fract1 & 0xFF; st->buf[4] = st->fract1 >> 8; st->buf[5] = st->fract1 >> 16; st->buf[6] = ADF4371_FRAC2WORD_L(st->fract2 & 0x7F) | ADF4371_FRAC1WORD(st->fract1 >> 24); st->buf[7] = ADF4371_FRAC2WORD_H(st->fract2 >> 7); st->buf[8] = st->mod2 & 0xFF; st->buf[9] = ADF4371_MOD2WORD(st->mod2 >> 8); ret = regmap_bulk_write(st->regmap, ADF4371_REG(0x11), st->buf, 10); if (ret < 0) return ret; /* * The R counter allows the input reference frequency to be * divided down to produce the reference clock to the PFD */ ret = regmap_write(st->regmap, ADF4371_REG(0x1F), st->ref_div_factor); if (ret < 0) return ret; ret = regmap_update_bits(st->regmap, ADF4371_REG(0x24), ADF4371_RF_DIV_SEL_MSK, ADF4371_RF_DIV_SEL(st->rf_div_sel)); if (ret < 0) return ret; cp_bleed = DIV_ROUND_UP(400 * 1750, st->integer * 375); cp_bleed = clamp(cp_bleed, 1U, 255U); ret = regmap_write(st->regmap, ADF4371_REG(0x26), cp_bleed); if (ret < 0) return ret; /* * Set to 1 when in INT mode (when FRAC1 = FRAC2 = 0), * and set to 0 when in FRAC mode. */ if (st->fract1 == 0 && st->fract2 == 0) int_mode = 0x01; ret = regmap_write(st->regmap, ADF4371_REG(0x2B), int_mode); if (ret < 0) return ret; return regmap_write(st->regmap, ADF4371_REG(0x10), st->integer & 0xFF); } static ssize_t adf4371_read(struct iio_dev *indio_dev, uintptr_t private, const struct iio_chan_spec *chan, char *buf) { struct adf4371_state *st = iio_priv(indio_dev); unsigned long long val = 0; unsigned int readval, reg, bit; int ret; switch ((u32)private) { case ADF4371_FREQ: val = adf4371_pll_fract_n_get_rate(st, chan->channel); ret = regmap_read(st->regmap, ADF4371_REG(0x7C), &readval); if (ret < 0) break; if (readval == 0x00) { dev_dbg(&st->spi->dev, "PLL un-locked\n"); ret = -EBUSY; } break; case ADF4371_POWER_DOWN: reg = adf4371_pwrdown_ch[chan->channel].reg; bit = adf4371_pwrdown_ch[chan->channel].bit; ret = regmap_read(st->regmap, reg, &readval); if (ret < 0) break; val = !(readval & BIT(bit)); break; case ADF4371_CHANNEL_NAME: return sprintf(buf, "%s\n", adf4371_ch_names[chan->channel]); default: ret = -EINVAL; val = 0; break; } return ret < 0 ? ret : sprintf(buf, "%llu\n", val); } static ssize_t adf4371_write(struct iio_dev *indio_dev, uintptr_t private, const struct iio_chan_spec *chan, const char *buf, size_t len) { struct adf4371_state *st = iio_priv(indio_dev); unsigned long long freq; bool power_down; unsigned int bit, readval, reg; int ret; mutex_lock(&st->lock); switch ((u32)private) { case ADF4371_FREQ: ret = kstrtoull(buf, 10, &freq); if (ret) break; ret = adf4371_set_freq(st, freq, chan->channel); break; case ADF4371_POWER_DOWN: ret = kstrtobool(buf, &power_down); if (ret) break; reg = adf4371_pwrdown_ch[chan->channel].reg; bit = adf4371_pwrdown_ch[chan->channel].bit; ret = regmap_read(st->regmap, reg, &readval); if (ret < 0) break; readval &= ~BIT(bit); readval |= (!power_down << bit); ret = regmap_write(st->regmap, reg, readval); break; default: ret = -EINVAL; break; } mutex_unlock(&st->lock); return ret ? ret : len; } #define _ADF4371_EXT_INFO(_name, _ident) { \ .name = _name, \ .read = adf4371_read, \ .write = adf4371_write, \ .private = _ident, \ .shared = IIO_SEPARATE, \ } static const struct iio_chan_spec_ext_info adf4371_ext_info[] = { /* * Ideally we use IIO_CHAN_INFO_FREQUENCY, but there are * values > 2^32 in order to support the entire frequency range * in Hz. Using scale is a bit ugly. */ _ADF4371_EXT_INFO("frequency", ADF4371_FREQ), _ADF4371_EXT_INFO("powerdown", ADF4371_POWER_DOWN), _ADF4371_EXT_INFO("name", ADF4371_CHANNEL_NAME), { }, }; #define ADF4371_CHANNEL(index) { \ .type = IIO_ALTVOLTAGE, \ .output = 1, \ .channel = index, \ .ext_info = adf4371_ext_info, \ .indexed = 1, \ } static const struct iio_chan_spec adf4371_chan[] = { ADF4371_CHANNEL(ADF4371_CH_RF8), ADF4371_CHANNEL(ADF4371_CH_RFAUX8), ADF4371_CHANNEL(ADF4371_CH_RF16), ADF4371_CHANNEL(ADF4371_CH_RF32), }; static const struct adf4371_chip_info adf4371_chip_info[] = { [ADF4371] = { .channels = adf4371_chan, .num_channels = 4, }, [ADF4372] = { .channels = adf4371_chan, .num_channels = 3, } }; static int adf4371_reg_access(struct iio_dev *indio_dev, unsigned int reg, unsigned int writeval, unsigned int *readval) { struct adf4371_state *st = iio_priv(indio_dev); if (readval) return regmap_read(st->regmap, reg, readval); else return regmap_write(st->regmap, reg, writeval); } static const struct iio_info adf4371_info = { .debugfs_reg_access = &adf4371_reg_access, }; static int adf4371_setup(struct adf4371_state *st) { unsigned int synth_timeout = 2, timeout = 1, vco_alc_timeout = 1; unsigned int vco_band_div, tmp; int ret; /* Perform a software reset */ ret = regmap_write(st->regmap, ADF4371_REG(0x0), ADF4371_RESET_CMD); if (ret < 0) return ret; ret = regmap_multi_reg_write(st->regmap, adf4371_reg_defaults, ARRAY_SIZE(adf4371_reg_defaults)); if (ret < 0) return ret; /* Mute to Lock Detect */ if (device_property_read_bool(&st->spi->dev, "adi,mute-till-lock-en")) { ret = regmap_update_bits(st->regmap, ADF4371_REG(0x25), ADF4371_MUTE_LD_MSK, ADF4371_MUTE_LD(1)); if (ret < 0) return ret; } /* Set address in ascending order, so the bulk_write() will work */ ret = regmap_update_bits(st->regmap, ADF4371_REG(0x0), ADF4371_ADDR_ASC_MSK | ADF4371_ADDR_ASC_R_MSK, ADF4371_ADDR_ASC(1) | ADF4371_ADDR_ASC_R(1)); if (ret < 0) return ret; /* * Calculate and maximize PFD frequency * fPFD = REFIN × ((1 + D)/(R × (1 + T))) * Where D is the REFIN doubler bit, T is the reference divide by 2, * R is the reference division factor * TODO: it is assumed D and T equal 0. */ do { st->ref_div_factor++; st->fpfd = st->clkin_freq / st->ref_div_factor; } while (st->fpfd > ADF4371_MAX_FREQ_PFD); /* Calculate Timeouts */ vco_band_div = DIV_ROUND_UP(st->fpfd, 2400000U); tmp = DIV_ROUND_CLOSEST(st->fpfd, 1000000U); do { timeout++; if (timeout > 1023) { timeout = 2; synth_timeout++; } } while (synth_timeout * 1024 + timeout <= 20 * tmp); do { vco_alc_timeout++; } while (vco_alc_timeout * 1024 - timeout <= 50 * tmp); st->buf[0] = vco_band_div; st->buf[1] = timeout & 0xFF; st->buf[2] = ADF4371_TIMEOUT(timeout >> 8) | 0x04; st->buf[3] = synth_timeout; st->buf[4] = ADF4371_VCO_ALC_TOUT(vco_alc_timeout); return regmap_bulk_write(st->regmap, ADF4371_REG(0x30), st->buf, 5); } static int adf4371_probe(struct spi_device *spi) { const struct spi_device_id *id = spi_get_device_id(spi); struct iio_dev *indio_dev; struct adf4371_state *st; struct regmap *regmap; int ret; indio_dev = devm_iio_device_alloc(&spi->dev, sizeof(*st)); if (!indio_dev) return -ENOMEM; regmap = devm_regmap_init_spi(spi, &adf4371_regmap_config); if (IS_ERR(regmap)) { dev_err(&spi->dev, "Error initializing spi regmap: %ld\n", PTR_ERR(regmap)); return PTR_ERR(regmap); } st = iio_priv(indio_dev); spi_set_drvdata(spi, indio_dev); st->spi = spi; st->regmap = regmap; mutex_init(&st->lock); st->chip_info = &adf4371_chip_info[id->driver_data]; indio_dev->name = id->name; indio_dev->info = &adf4371_info; indio_dev->modes = INDIO_DIRECT_MODE; indio_dev->channels = st->chip_info->channels; indio_dev->num_channels = st->chip_info->num_channels; st->clkin = devm_clk_get_enabled(&spi->dev, "clkin"); if (IS_ERR(st->clkin)) return PTR_ERR(st->clkin); st->clkin_freq = clk_get_rate(st->clkin); ret = adf4371_setup(st); if (ret < 0) { dev_err(&spi->dev, "ADF4371 setup failed\n"); return ret; } return devm_iio_device_register(&spi->dev, indio_dev); } static const struct spi_device_id adf4371_id_table[] = { { "adf4371", ADF4371 }, { "adf4372", ADF4372 }, {} }; MODULE_DEVICE_TABLE(spi, adf4371_id_table); static const struct of_device_id adf4371_of_match[] = { { .compatible = "adi,adf4371" }, { .compatible = "adi,adf4372" }, { }, }; MODULE_DEVICE_TABLE(of, adf4371_of_match); static struct spi_driver adf4371_driver = { .driver = { .name = "adf4371", .of_match_table = adf4371_of_match, }, .probe = adf4371_probe, .id_table = adf4371_id_table, }; module_spi_driver(adf4371_driver); MODULE_AUTHOR("Stefan Popa <stefan.popa@analog.com>"); MODULE_DESCRIPTION("Analog Devices ADF4371 SPI PLL"); MODULE_LICENSE("GPL");
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