On Tue, 8 Dec 2020 13:30:06 +0000 "Pop, Cristian" <Cristian.Pop@xxxxxxxxxx> wrote: > > -----Original Message----- > > From: Jonathan Cameron <jic23@xxxxxxxxxx> > > Sent: Saturday, December 5, 2020 8:01 PM > > To: Pop, Cristian <Cristian.Pop@xxxxxxxxxx> > > Cc: linux-iio@xxxxxxxxxxxxxxx; linux-kernel@xxxxxxxxxxxxxxx; > > devicetree@xxxxxxxxxxxxxxx; robh+dt@xxxxxxxxxx > > Subject: Re: [PATCH v2 2/2] iio: dac: ad5766: add driver support for AD5766 > > > > [External] > > > > On Fri, 4 Dec 2020 20:20:43 +0200 > > Cristian Pop <cristian.pop@xxxxxxxxxx> wrote: > > > > > The AD5766/AD5767 are 16-channel, 16-bit/12-bit, voltage output dense > > > DACs Digital-to-Analog converters. > > > > > > This change adds support for these DACs. > > > > > > Link: > > > https://www.analog.com/media/en/technical-documentation/data- > > sheets/ad > > > 5766-5767.pdf > > > > > > Signed-off-by: Cristian Pop <cristian.pop@xxxxxxxxxx> > > > > Missing build files + docs for the new ABI. > > Note it doesn't build so a few things to fix on that front! > > > > Docs in appropriate file under Documentation/ABI/testing/sysfs-bus-iio-* > > > > I'm a bit curious about the range being entirely controllable from userspace > > as well. Seems like something that might be dangerous in some systems. > > Perhaps we need some sort of dt binding restriction mechanism? > If you think it is better to restrict the user to a range that is set in device tree, > please let me know. In some cases it is possible to have an extended range maybe, > or a combination of multiple ranges. It's an interesting question of whether anyone actually would use these parts in a circumstance where they wanted to only access the full range via a mode switch. I agree it is theoretically possible, but it's pretty odd and would smack of curious design decisions to me! I'm a little cynical in that I suspect the only people who ever change these ranges are those using devkits to do a PoC. Production hardware would normally be designed to work best with a fixed range. If a range that doesn't correspond to one of the supported ones, actually makes sense, then having a dt binding that sets max and min values separately and allowed the driver to check against both would work. Thanks, Jonathan > > > > > > > --- > > > Changes in v2: > > > -Remove forward declarations, arrange code > > > -New ABI docs > > > -Move "max_val" scope in case > > > -Remove blank line > > > -Use bitfield operations, where posible > > > -Change declaration type to int of: > > > int > > scale_avail[AD5766_VOLTAGE_RANGE_MAX][2]; > > > int > > offset_avail[AD5766_VOLTAGE_RANGE_MAX][2]; > > > -Move initialization down to just above where it is used: > > > "type = spi_get_device_id(spi)->driver_data;" > > > > > > drivers/iio/dac/ad5766.c | 758 > > > +++++++++++++++++++++++++++++++++++++++ > > > 1 file changed, 758 insertions(+) > > > create mode 100644 drivers/iio/dac/ad5766.c > > > > > > diff --git a/drivers/iio/dac/ad5766.c b/drivers/iio/dac/ad5766.c new > > > file mode 100644 index 000000000000..e6d24a41bd4e > > > --- /dev/null > > > +++ b/drivers/iio/dac/ad5766.c > > > @@ -0,0 +1,758 @@ > > > +// SPDX-License-Identifier: GPL-2.0-only > > > +/* > > > + * Analog Devices AD5766, AD5767 > > > + * Digital to Analog Converters driver > > > + * > > > + * Copyright 2019-2020 Analog Devices Inc. > > > + */ > > > + > > > +#include <linux/delay.h> > > > +#include <linux/device.h> > > > +#include <linux/gpio/consumer.h> > > > +#include <linux/module.h> > > > +#include <linux/spi/spi.h> > > > +#include <linux/iio/iio.h> > > > +#include <linux/bitfield.h> > > > + > > > +#define AD5766_UPPER_WORD_SPI_MASK GENMASK(31, 16) > > > +#define AD5766_LOWER_WORD_SPI_MASK GENMASK(15, 0) > > > +#define AD5766_DITHER_SOURCE_MASK(x) GENMASK(((2 * x) + > > 1), (2 * x)) > > > +#define AD5766_DITHER_SCALE_MASK(x) > > AD5766_DITHER_SOURCE_MASK(x) > > > + > > > +#define AD5766_CMD_NOP_MUX_OUT 0x00 > > > +#define AD5766_CMD_SDO_CNTRL 0x01 > > > +#define AD5766_CMD_WR_IN_REG(x) (0x10 | ((x) > > & 0xF)) > > > +#define AD5766_CMD_WR_DAC_REG(x) (0x20 | ((x) & 0xF)) > > > +#define AD5766_CMD_SW_LDAC 0x30 > > > +#define AD5766_CMD_SPAN_REG 0x40 > > > +#define AD5766_CMD_WR_PWR_DITHER 0x51 > > > +#define AD5766_CMD_WR_DAC_REG_ALL 0x60 > > > +#define AD5766_CMD_SW_FULL_RESET 0x70 > > > +#define AD5766_CMD_READBACK_REG(x) (0x80 | ((x) & 0xF)) > > > +#define AD5766_CMD_DITHER_SIG_1 0x90 > > > +#define AD5766_CMD_DITHER_SIG_2 0xA0 > > > +#define AD5766_CMD_INV_DITHER 0xB0 > > > +#define AD5766_CMD_DITHER_SCALE_1 0xC0 > > > +#define AD5766_CMD_DITHER_SCALE_2 0xD0 > > > + > > > +#define AD5766_FULL_RESET_CODE 0x1234 > > > + > > > +enum ad5766_type { > > > + ID_AD5766, > > > + ID_AD5767, > > > +}; > > > + > > > +enum ad5766_voltage_range { > > > + AD5766_VOLTAGE_RANGE_M20V_0V, > > > + AD5766_VOLTAGE_RANGE_M16V_to_0V, > > > + AD5766_VOLTAGE_RANGE_M10V_to_0V, > > > + AD5766_VOLTAGE_RANGE_M12V_to_14V, > > > + AD5766_VOLTAGE_RANGE_M16V_to_10V, > > > + AD5766_VOLTAGE_RANGE_M10V_to_6V, > > > + AD5766_VOLTAGE_RANGE_M5V_to_5V, > > > + AD5766_VOLTAGE_RANGE_M10V_to_10V, > > > + AD5766_VOLTAGE_RANGE_MAX, > > > +}; > > > + > > > +/** > > > + * struct ad5766_chip_info - chip specific information > > > + * @num_channels: number of channels > > > + * @channel: channel specification > > > + */ > > > +struct ad5766_chip_info { > > > + unsigned int num_channels; > > > + const struct iio_chan_spec *channels; > > > +}; > > > + > > > +enum { > > > + AD5766_DITHER_PWR, > > > + AD5766_DITHER_INVERT > > > +}; > > > + > > > +/* > > > + * External dither signal can be composed with the DAC output, if > > activated. > > > + * The dither signals are applied to the N0 and N1 input pins. > > > + * Dither source for each of the channel can be selected by writing > > > +to > > > + * "dither_source",a 32 bit variable and two bits are used for each > > > +of the 16 > > > + * channels: 0: NO_DITHER, 1: N0, 2: N1. > > > + * This variable holds available dither source strings. > > > + */ > > > +static const char * const ad5766_dither_sources[] = { > > > + "NO_DITHER", > > > + "N0", > > > + "N1", > > > +}; > > > + > > > +/* > > > + * Dither signal can also be scaled. > > > + * Available dither scale strings coresponding to "dither_scale" > > > +field in > > > + * "struct ad5766_state". > > > + * "dither_scale" is a 32 bit variable and two bits are used for each > > > +of the 16 > > > + * channels: 0: NO_SCALING, 1: 75%_SCALING, 2: 50%_SCALING, 3: > > 25%_SCALING. > > > > Needs explicit ABI docs for a proper discussion. My gut feeling is it should > > be two controls. On/off + a scaling control that takes integer values. > There is a dither on/off, we can also add an on/off control for scale and source > If requested. > > > > > + */ > > > +static const char * const ad5766_dither_scales[] = { > > > + "NO_SCALING", > > > + "75%_SCALING", > > > + "50%_SCALING", > > > + "25%_SCALING", > > > +}; > > > + > > > +/** > > > + * struct ad5766_state - driver instance specific data > > > + * @spi: SPI device > > > + * @lock: Mutex lock > > > > Say what exactly the scope of the lock is. No interest at all to tell us what is > > clear from the type of the structure element. > > > > > + * @chip_info: Chip model specific constants > > > + * @gpio_reset: Reset GPIO, used to reset the device > > > + * @crt_range: Current selected output range > > > + * @cached_offset: Cached range coresponding to the selected offset > > > + * @dither_power_ctrl: Power-down bit for each channel dither > > block (for > > > + * example, D15 = DAC 15,D8 = DAC 8, and D0 = DAC 0) > > > + * 0 - Normal operation, 1 - Power down > > > + * @dither_invert: Inverts the dither signal applied to the selected DAC > > > + * outputs > > > + * @dither_source: Selects between 3 possible sources: > > > + * 0: No dither, 1: N0, 2: N1 > > > + * Two bits are used for each channel > > > + * @dither_scale: Selects between 4 possible scales: > > > + * 0: No scale, 1: 75%, 2: 50%, 3: 25% > > > + * Two bits are used for each channel > > > + * @scale_avail: Scale available table > > > + * @offset_avail: Offest available table > > > + * @data: SPI transfer buffers > > > + */ > > > +struct ad5766_state { > > > + struct spi_device *spi; > > > + struct mutex lock; > > > + const struct ad5766_chip_info *chip_info; > > > + struct gpio_desc *gpio_reset; > > > + enum ad5766_voltage_range crt_range; > > > + enum ad5766_voltage_range cached_offset; > > > + u16 dither_power_ctrl; > > > + u16 dither_invert; > > > + u32 dither_source; > > > + u32 dither_scale; > > > + int scale_avail[AD5766_VOLTAGE_RANGE_MAX][2]; > > > + int offset_avail[AD5766_VOLTAGE_RANGE_MAX][2]; > > > + union { > > > + u32 d32; > > > + u16 w16[2]; > > > + u8 b8[4]; > > > + } data[3] ____cacheline_aligned; > > > +}; > > > + > > ... > > > + > > > +static int _ad5766_spi_read(struct ad5766_state *st, u8 dac, int > > > +*val) { > > > + int ret; > > > + struct spi_transfer xfers[] = { > > > + { > > > + .tx_buf = &st->data[0].d32, > > > + .bits_per_word = 8, > > > + .len = 3, > > > + .cs_change = 1, > > > + }, { > > > + .tx_buf = &st->data[1].d32, > > > + .rx_buf = &st->data[2].d32, > > > + .bits_per_word = 8, > > > + .len = 3, > > > + }, > > > + }; > > > + > > > + st->data[0].d32 = AD5766_CMD_READBACK_REG(dac); > > > + st->data[1].d32 = AD5766_CMD_NOP_MUX_OUT; > > > + > > > + ret = spi_sync_transfer(st->spi, xfers, ARRAY_SIZE(xfers)); > > > + if (ret) > > > + return ret; > > > + > > > + *val = st->data[2].w16[1]; > > > + > > > + return ret; > > > +} > > > + > > > +static int _ad5766_spi_write(struct ad5766_state *st, u8 command, u16 > > > +data) { > > > + st->data[0].b8[0] = command; > > > + st->data[0].b8[1] = (data & 0xFF00) >> 8; > > > + st->data[0].b8[2] = (data & 0x00FF) >> 0; > > > > That's an unaligned put so ideally use put_unaligned_xx16 and friends to > > make that clear. > > > > > + > > > + return spi_write(st->spi, &st->data[0].b8[0], 3); } > > > + > > > +static int ad5766_read(struct iio_dev *indio_dev, u8 dac, int *val) { > > > + struct ad5766_state *st = iio_priv(indio_dev); > > > + int ret; > > > + > > > + mutex_lock(&st->lock); > > > + ret = _ad5766_spi_read(st, dac, val); > > > + mutex_unlock(&st->lock); > > > + > > > + return ret; > > > +} > > > + > > > +static int ad5766_write(struct iio_dev *indio_dev, u8 dac, u16 data) > > > +{ > > > + struct ad5766_state *st = iio_priv(indio_dev); > > > + int ret; > > > + > > > + mutex_lock(&st->lock); > > > + ret = _ad5766_spi_write(st, AD5766_CMD_WR_DAC_REG(dac), > > data); > > > > Normal convention for this sort of function would be __ rather than _ Looks > > more deliberate. > > > > > + mutex_unlock(&st->lock); > > > + > > > + return ret; > > > +} > > > + > > > > ... > > > > > + > > > +#define _AD5766_CHAN_EXT_INFO(_name, _what, _shared) { \ > > > + .name = _name, \ > > > + .read = ad5766_read_ext, \ > > > + .write = ad5766_write_ext, \ > > > + .private = _what, \ > > > + .shared = _shared, \ > > > +} > > > + > > > +static const struct iio_chan_spec_ext_info ad5766_ext_info[] = { > > > + > > > + _AD5766_CHAN_EXT_INFO("dither_pwr", AD5766_DITHER_PWR, > > IIO_SEPARATE), > > > + _AD5766_CHAN_EXT_INFO("dither_invert", > > AD5766_DITHER_INVERT, > > > + IIO_SEPARATE), > > > + IIO_ENUM("dither_source", IIO_SEPARATE, > > &ad5766_dither_source_enum), > > > + IIO_ENUM_AVAILABLE_SHARED("dither_source", > > > + IIO_SEPARATE, > > > + &ad5766_dither_source_enum), > > > + IIO_ENUM("dither_scale", IIO_SEPARATE, > > &ad5766_dither_scale_enum), > > > + IIO_ENUM_AVAILABLE_SHARED("dither_scale", > > > > That macro doesn't exist in mainline. > > > > > + IIO_SEPARATE, > > > + &ad5766_dither_scale_enum), > > > + {} > > > +}; > > > > All the above need ABI docs so we can talk about them without having to > > read data sheets. > > > > ...