treewide: Replace GPLv2 boilerplate/reference with SPDX - rule 156

[mirror_ubuntu-jammy-kernel.git] / sound / pci / ice1712 / juli.c

// SPDX-License-Identifier: GPL-2.0-or-later
/*
 *   ALSA driver for ICEnsemble VT1724 (Envy24HT)
 *
 *   Lowlevel functions for ESI Juli@ cards
 *
 *      Copyright (c) 2004 Jaroslav Kysela <perex@perex.cz>
 *                    2008 Pavel Hofman <dustin@seznam.cz>
 */

#include <linux/delay.h>
#include <linux/interrupt.h>
#include <linux/init.h>
#include <linux/slab.h>
#include <linux/string.h>
#include <sound/core.h>
#include <sound/tlv.h>

#include "ice1712.h"
#include "envy24ht.h"
#include "juli.h"

struct juli_spec {
        struct ak4114 *ak4114;
        unsigned int analog:1;
};

/*
 * chip addresses on I2C bus
 */
#define AK4114_ADDR             0x20            /* S/PDIF receiver */
#define AK4358_ADDR             0x22            /* DAC */

/*
 * Juli does not use the standard ICE1724 clock scheme. Juli's ice1724 chip is
 * supplied by external clock provided by Xilinx array and MK73-1 PLL frequency
 * multiplier. Actual frequency is set by ice1724 GPIOs hooked to the Xilinx.
 *
 * The clock circuitry is supplied by the two ice1724 crystals. This
 * arrangement allows to generate independent clock signal for AK4114's input
 * rate detection circuit. As a result, Juli, unlike most other
 * ice1724+ak4114-based cards, detects spdif input rate correctly.
 * This fact is applied in the driver, allowing to modify PCM stream rate
 * parameter according to the actual input rate.
 *
 * Juli uses the remaining three stereo-channels of its DAC to optionally
 * monitor analog input, digital input, and digital output. The corresponding
 * I2S signals are routed by Xilinx, controlled by GPIOs.
 *
 * The master mute is implemented using output muting transistors (GPIO) in
 * combination with smuting the DAC.
 *
 * The card itself has no HW master volume control, implemented using the
 * vmaster control.
 *
 * TODO:
 * researching and fixing the input monitors
 */

/*
 * GPIO pins
 */
#define GPIO_FREQ_MASK          (3<<0)
#define GPIO_FREQ_32KHZ         (0<<0)
#define GPIO_FREQ_44KHZ         (1<<0)
#define GPIO_FREQ_48KHZ         (2<<0)
#define GPIO_MULTI_MASK         (3<<2)
#define GPIO_MULTI_4X           (0<<2)
#define GPIO_MULTI_2X           (1<<2)
#define GPIO_MULTI_1X           (2<<2)          /* also external */
#define GPIO_MULTI_HALF         (3<<2)
#define GPIO_INTERNAL_CLOCK     (1<<4)          /* 0 = external, 1 = internal */
#define GPIO_CLOCK_MASK         (1<<4)
#define GPIO_ANALOG_PRESENT     (1<<5)          /* RO only: 0 = present */
#define GPIO_RXMCLK_SEL         (1<<7)          /* must be 0 */
#define GPIO_AK5385A_CKS0       (1<<8)
#define GPIO_AK5385A_DFS1       (1<<9)
#define GPIO_AK5385A_DFS0       (1<<10)
#define GPIO_DIGOUT_MONITOR     (1<<11)         /* 1 = active */
#define GPIO_DIGIN_MONITOR      (1<<12)         /* 1 = active */
#define GPIO_ANAIN_MONITOR      (1<<13)         /* 1 = active */
#define GPIO_AK5385A_CKS1       (1<<14)         /* must be 0 */
#define GPIO_MUTE_CONTROL       (1<<15)         /* output mute, 1 = muted */

#define GPIO_RATE_MASK          (GPIO_FREQ_MASK | GPIO_MULTI_MASK | \
                GPIO_CLOCK_MASK)
#define GPIO_AK5385A_MASK       (GPIO_AK5385A_CKS0 | GPIO_AK5385A_DFS0 | \
                GPIO_AK5385A_DFS1 | GPIO_AK5385A_CKS1)

#define JULI_PCM_RATE   (SNDRV_PCM_RATE_16000 | SNDRV_PCM_RATE_22050 | \
                SNDRV_PCM_RATE_32000 | SNDRV_PCM_RATE_44100 | \
                SNDRV_PCM_RATE_48000 | SNDRV_PCM_RATE_64000 | \
                SNDRV_PCM_RATE_88200 | SNDRV_PCM_RATE_96000 | \
                SNDRV_PCM_RATE_176400 | SNDRV_PCM_RATE_192000)

#define GPIO_RATE_16000         (GPIO_FREQ_32KHZ | GPIO_MULTI_HALF | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_22050         (GPIO_FREQ_44KHZ | GPIO_MULTI_HALF | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_24000         (GPIO_FREQ_48KHZ | GPIO_MULTI_HALF | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_32000         (GPIO_FREQ_32KHZ | GPIO_MULTI_1X | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_44100         (GPIO_FREQ_44KHZ | GPIO_MULTI_1X | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_48000         (GPIO_FREQ_48KHZ | GPIO_MULTI_1X | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_64000         (GPIO_FREQ_32KHZ | GPIO_MULTI_2X | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_88200         (GPIO_FREQ_44KHZ | GPIO_MULTI_2X | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_96000         (GPIO_FREQ_48KHZ | GPIO_MULTI_2X | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_176400        (GPIO_FREQ_44KHZ | GPIO_MULTI_4X | \
                GPIO_INTERNAL_CLOCK)
#define GPIO_RATE_192000        (GPIO_FREQ_48KHZ | GPIO_MULTI_4X | \
                GPIO_INTERNAL_CLOCK)

/*
 * Initial setup of the conversion array GPIO <-> rate
 */
static const unsigned int juli_rates[] = {
        16000, 22050, 24000, 32000,
        44100, 48000, 64000, 88200,
        96000, 176400, 192000,
};

static const unsigned int gpio_vals[] = {
        GPIO_RATE_16000, GPIO_RATE_22050, GPIO_RATE_24000, GPIO_RATE_32000,
        GPIO_RATE_44100, GPIO_RATE_48000, GPIO_RATE_64000, GPIO_RATE_88200,
        GPIO_RATE_96000, GPIO_RATE_176400, GPIO_RATE_192000,
};

static const struct snd_pcm_hw_constraint_list juli_rates_info = {
        .count = ARRAY_SIZE(juli_rates),
        .list = juli_rates,
        .mask = 0,
};

static int get_gpio_val(int rate)
{
        int i;
        for (i = 0; i < ARRAY_SIZE(juli_rates); i++)
                if (juli_rates[i] == rate)
                        return gpio_vals[i];
        return 0;
}

static void juli_ak4114_write(void *private_data, unsigned char reg,
                                unsigned char val)
{
        snd_vt1724_write_i2c((struct snd_ice1712 *)private_data, AK4114_ADDR,
                                reg, val);
}

static unsigned char juli_ak4114_read(void *private_data, unsigned char reg)
{
        return snd_vt1724_read_i2c((struct snd_ice1712 *)private_data,
                                        AK4114_ADDR, reg);
}

/*
 * If SPDIF capture and slaved to SPDIF-IN, setting runtime rate
 * to the external rate
 */
static void juli_spdif_in_open(struct snd_ice1712 *ice,
                                struct snd_pcm_substream *substream)
{
        struct juli_spec *spec = ice->spec;
        struct snd_pcm_runtime *runtime = substream->runtime;
        int rate;

        if (substream->stream == SNDRV_PCM_STREAM_PLAYBACK ||
                        !ice->is_spdif_master(ice))
                return;
        rate = snd_ak4114_external_rate(spec->ak4114);
        if (rate >= runtime->hw.rate_min && rate <= runtime->hw.rate_max) {
                runtime->hw.rate_min = rate;
                runtime->hw.rate_max = rate;
        }
}

/*
 * AK4358 section
 */

static void juli_akm_lock(struct snd_akm4xxx *ak, int chip)
{
}

static void juli_akm_unlock(struct snd_akm4xxx *ak, int chip)
{
}

static void juli_akm_write(struct snd_akm4xxx *ak, int chip,
                           unsigned char addr, unsigned char data)
{
        struct snd_ice1712 *ice = ak->private_data[0];
         
        if (snd_BUG_ON(chip))
                return;
        snd_vt1724_write_i2c(ice, AK4358_ADDR, addr, data);
}

/*
 * change the rate of envy24HT, AK4358, AK5385
 */
static void juli_akm_set_rate_val(struct snd_akm4xxx *ak, unsigned int rate)
{
        unsigned char old, tmp, ak4358_dfs;
        unsigned int ak5385_pins, old_gpio, new_gpio;
        struct snd_ice1712 *ice = ak->private_data[0];
        struct juli_spec *spec = ice->spec;

        if (rate == 0)  /* no hint - S/PDIF input is master or the new spdif
                           input rate undetected, simply return */
                return;

        /* adjust DFS on codecs */
        if (rate > 96000)  {
                ak4358_dfs = 2;
                ak5385_pins = GPIO_AK5385A_DFS1 | GPIO_AK5385A_CKS0;
        } else if (rate > 48000) {
                ak4358_dfs = 1;
                ak5385_pins = GPIO_AK5385A_DFS0;
        } else {
                ak4358_dfs = 0;
                ak5385_pins = 0;
        }
        /* AK5385 first, since it requires cold reset affecting both codecs */
        old_gpio = ice->gpio.get_data(ice);
        new_gpio =  (old_gpio & ~GPIO_AK5385A_MASK) | ak5385_pins;
        /* dev_dbg(ice->card->dev, "JULI - ak5385 set_rate_val: new gpio 0x%x\n",
                new_gpio); */
        ice->gpio.set_data(ice, new_gpio);

        /* cold reset */
        old = inb(ICEMT1724(ice, AC97_CMD));
        outb(old | VT1724_AC97_COLD, ICEMT1724(ice, AC97_CMD));
        udelay(1);
        outb(old & ~VT1724_AC97_COLD, ICEMT1724(ice, AC97_CMD));

        /* AK4358 */
        /* set new value, reset DFS */
        tmp = snd_akm4xxx_get(ak, 0, 2);
        snd_akm4xxx_reset(ak, 1);
        tmp = snd_akm4xxx_get(ak, 0, 2);
        tmp &= ~(0x03 << 4);
        tmp |= ak4358_dfs << 4;
        snd_akm4xxx_set(ak, 0, 2, tmp);
        snd_akm4xxx_reset(ak, 0);

        /* reinit ak4114 */
        snd_ak4114_reinit(spec->ak4114);
}

#define AK_DAC(xname, xch)      { .name = xname, .num_channels = xch }
#define PCM_VOLUME              "PCM Playback Volume"
#define MONITOR_AN_IN_VOLUME    "Monitor Analog In Volume"
#define MONITOR_DIG_IN_VOLUME   "Monitor Digital In Volume"
#define MONITOR_DIG_OUT_VOLUME  "Monitor Digital Out Volume"

static const struct snd_akm4xxx_dac_channel juli_dac[] = {
        AK_DAC(PCM_VOLUME, 2),
        AK_DAC(MONITOR_AN_IN_VOLUME, 2),
        AK_DAC(MONITOR_DIG_OUT_VOLUME, 2),
        AK_DAC(MONITOR_DIG_IN_VOLUME, 2),
};


static const struct snd_akm4xxx akm_juli_dac = {
        .type = SND_AK4358,
        .num_dacs = 8,  /* DAC1 - analog out
                           DAC2 - analog in monitor
                           DAC3 - digital out monitor
                           DAC4 - digital in monitor
                         */
        .ops = {
                .lock = juli_akm_lock,
                .unlock = juli_akm_unlock,
                .write = juli_akm_write,
                .set_rate_val = juli_akm_set_rate_val
        },
        .dac_info = juli_dac,
};

#define juli_mute_info          snd_ctl_boolean_mono_info

static int juli_mute_get(struct snd_kcontrol *kcontrol,
                struct snd_ctl_elem_value *ucontrol)
{
        struct snd_ice1712 *ice = snd_kcontrol_chip(kcontrol);
        unsigned int val;
        val = ice->gpio.get_data(ice) & (unsigned int) kcontrol->private_value;
        if (kcontrol->private_value == GPIO_MUTE_CONTROL)
                /* val 0 = signal on */
                ucontrol->value.integer.value[0] = (val) ? 0 : 1;
        else
                /* val 1 = signal on */
                ucontrol->value.integer.value[0] = (val) ? 1 : 0;
        return 0;
}

static int juli_mute_put(struct snd_kcontrol *kcontrol,
                struct snd_ctl_elem_value *ucontrol)
{
        struct snd_ice1712 *ice = snd_kcontrol_chip(kcontrol);
        unsigned int old_gpio, new_gpio;
        old_gpio = ice->gpio.get_data(ice);
        if (ucontrol->value.integer.value[0]) {
                /* unmute */
                if (kcontrol->private_value == GPIO_MUTE_CONTROL) {
                        /* 0 = signal on */
                        new_gpio = old_gpio & ~GPIO_MUTE_CONTROL;
                        /* un-smuting DAC */
                        snd_akm4xxx_write(ice->akm, 0, 0x01, 0x01);
                } else
                        /* 1 = signal on */
                        new_gpio =  old_gpio |
                                (unsigned int) kcontrol->private_value;
        } else {
                /* mute */
                if (kcontrol->private_value == GPIO_MUTE_CONTROL) {
                        /* 1 = signal off */
                        new_gpio = old_gpio | GPIO_MUTE_CONTROL;
                        /* smuting DAC */
                        snd_akm4xxx_write(ice->akm, 0, 0x01, 0x03);
                } else
                        /* 0 = signal off */
                        new_gpio =  old_gpio &
                                ~((unsigned int) kcontrol->private_value);
        }
        /* dev_dbg(ice->card->dev,
                "JULI - mute/unmute: control_value: 0x%x, old_gpio: 0x%x, "
                "new_gpio 0x%x\n",
                (unsigned int)ucontrol->value.integer.value[0], old_gpio,
                new_gpio); */
        if (old_gpio != new_gpio) {
                ice->gpio.set_data(ice, new_gpio);
                return 1;
        }
        /* no change */
        return 0;
}

static struct snd_kcontrol_new juli_mute_controls[] = {
        {
                .iface = SNDRV_CTL_ELEM_IFACE_MIXER,
                .name = "Master Playback Switch",
                .info = juli_mute_info,
                .get = juli_mute_get,
                .put = juli_mute_put,
                .private_value = GPIO_MUTE_CONTROL,
        },
        /* Although the following functionality respects the succint NDA'd
         * documentation from the card manufacturer, and the same way of
         * operation is coded in OSS Juli driver, only Digital Out monitor
         * seems to work. Surprisingly, Analog input monitor outputs Digital
         * output data. The two are independent, as enabling both doubles
         * volume of the monitor sound.
         *
         * Checking traces on the board suggests the functionality described
         * by the manufacturer is correct - I2S from ADC and AK4114
         * go to ICE as well as to Xilinx, I2S inputs of DAC2,3,4 (the monitor
         * inputs) are fed from Xilinx.
         *
         * I even checked traces on board and coded a support in driver for
         * an alternative possibility - the unused I2S ICE output channels
         * switched to HW-IN/SPDIF-IN and providing the monitoring signal to
         * the DAC - to no avail. The I2S outputs seem to be unconnected.
         *
         * The windows driver supports the monitoring correctly.
         */
        {
                .iface = SNDRV_CTL_ELEM_IFACE_MIXER,
                .name = "Monitor Analog In Switch",
                .info = juli_mute_info,
                .get = juli_mute_get,
                .put = juli_mute_put,
                .private_value = GPIO_ANAIN_MONITOR,
        },
        {
                .iface = SNDRV_CTL_ELEM_IFACE_MIXER,
                .name = "Monitor Digital Out Switch",
                .info = juli_mute_info,
                .get = juli_mute_get,
                .put = juli_mute_put,
                .private_value = GPIO_DIGOUT_MONITOR,
        },
        {
                .iface = SNDRV_CTL_ELEM_IFACE_MIXER,
                .name = "Monitor Digital In Switch",
                .info = juli_mute_info,
                .get = juli_mute_get,
                .put = juli_mute_put,
                .private_value = GPIO_DIGIN_MONITOR,
        },
};

static char *slave_vols[] = {
        PCM_VOLUME,
        MONITOR_AN_IN_VOLUME,
        MONITOR_DIG_IN_VOLUME,
        MONITOR_DIG_OUT_VOLUME,
        NULL
};

static
DECLARE_TLV_DB_SCALE(juli_master_db_scale, -6350, 50, 1);

static struct snd_kcontrol *ctl_find(struct snd_card *card,
                                     const char *name)
{
        struct snd_ctl_elem_id sid = {0};

        strlcpy(sid.name, name, sizeof(sid.name));
        sid.iface = SNDRV_CTL_ELEM_IFACE_MIXER;
        return snd_ctl_find_id(card, &sid);
}

static void add_slaves(struct snd_card *card,
                       struct snd_kcontrol *master,
                       char * const *list)
{
        for (; *list; list++) {
                struct snd_kcontrol *slave = ctl_find(card, *list);
                /* dev_dbg(card->dev, "add_slaves - %s\n", *list); */
                if (slave) {
                        /* dev_dbg(card->dev, "slave %s found\n", *list); */
                        snd_ctl_add_slave(master, slave);
                }
        }
}

static int juli_add_controls(struct snd_ice1712 *ice)
{
        struct juli_spec *spec = ice->spec;
        int err;
        unsigned int i;
        struct snd_kcontrol *vmaster;

        err = snd_ice1712_akm4xxx_build_controls(ice);
        if (err < 0)
                return err;

        for (i = 0; i < ARRAY_SIZE(juli_mute_controls); i++) {
                err = snd_ctl_add(ice->card,
                                snd_ctl_new1(&juli_mute_controls[i], ice));
                if (err < 0)
                        return err;
        }
        /* Create virtual master control */
        vmaster = snd_ctl_make_virtual_master("Master Playback Volume",
                                              juli_master_db_scale);
        if (!vmaster)
                return -ENOMEM;
        add_slaves(ice->card, vmaster, slave_vols);
        err = snd_ctl_add(ice->card, vmaster);
        if (err < 0)
                return err;

        /* only capture SPDIF over AK4114 */
        return snd_ak4114_build(spec->ak4114, NULL,
                        ice->pcm->streams[SNDRV_PCM_STREAM_CAPTURE].substream);
}

/*
 * suspend/resume
 * */

#ifdef CONFIG_PM_SLEEP
static int juli_resume(struct snd_ice1712 *ice)
{
        struct snd_akm4xxx *ak = ice->akm;
        struct juli_spec *spec = ice->spec;
        /* akm4358 un-reset, un-mute */
        snd_akm4xxx_reset(ak, 0);
        /* reinit ak4114 */
        snd_ak4114_resume(spec->ak4114);
        return 0;
}

static int juli_suspend(struct snd_ice1712 *ice)
{
        struct snd_akm4xxx *ak = ice->akm;
        struct juli_spec *spec = ice->spec;
        /* akm4358 reset and soft-mute */
        snd_akm4xxx_reset(ak, 1);
        snd_ak4114_suspend(spec->ak4114);
        return 0;
}
#endif

/*
 * initialize the chip
 */

static inline int juli_is_spdif_master(struct snd_ice1712 *ice)
{
        return (ice->gpio.get_data(ice) & GPIO_INTERNAL_CLOCK) ? 0 : 1;
}

static unsigned int juli_get_rate(struct snd_ice1712 *ice)
{
        int i;
        unsigned char result;

        result =  ice->gpio.get_data(ice) & GPIO_RATE_MASK;
        for (i = 0; i < ARRAY_SIZE(gpio_vals); i++)
                if (gpio_vals[i] == result)
                        return juli_rates[i];
        return 0;
}

/* setting new rate */
static void juli_set_rate(struct snd_ice1712 *ice, unsigned int rate)
{
        unsigned int old, new;
        unsigned char val;

        old = ice->gpio.get_data(ice);
        new =  (old & ~GPIO_RATE_MASK) | get_gpio_val(rate);
        /* dev_dbg(ice->card->dev, "JULI - set_rate: old %x, new %x\n",
                        old & GPIO_RATE_MASK,
                        new & GPIO_RATE_MASK); */

        ice->gpio.set_data(ice, new);
        /* switching to external clock - supplied by external circuits */
        val = inb(ICEMT1724(ice, RATE));
        outb(val | VT1724_SPDIF_MASTER, ICEMT1724(ice, RATE));
}

static inline unsigned char juli_set_mclk(struct snd_ice1712 *ice,
                                          unsigned int rate)
{
        /* no change in master clock */
        return 0;
}

/* setting clock to external - SPDIF */
static int juli_set_spdif_clock(struct snd_ice1712 *ice, int type)
{
        unsigned int old;
        old = ice->gpio.get_data(ice);
        /* external clock (= 0), multiply 1x, 48kHz */
        ice->gpio.set_data(ice, (old & ~GPIO_RATE_MASK) | GPIO_MULTI_1X |
                        GPIO_FREQ_48KHZ);
        return 0;
}

/* Called when ak4114 detects change in the input SPDIF stream */
static void juli_ak4114_change(struct ak4114 *ak4114, unsigned char c0,
                               unsigned char c1)
{
        struct snd_ice1712 *ice = ak4114->change_callback_private;
        int rate;
        if (ice->is_spdif_master(ice) && c1) {
                /* only for SPDIF master mode, rate was changed */
                rate = snd_ak4114_external_rate(ak4114);
                /* dev_dbg(ice->card->dev, "ak4114 - input rate changed to %d\n",
                                rate); */
                juli_akm_set_rate_val(ice->akm, rate);
        }
}

static int juli_init(struct snd_ice1712 *ice)
{
        static const unsigned char ak4114_init_vals[] = {
                /* AK4117_REG_PWRDN */  AK4114_RST | AK4114_PWN |
                                        AK4114_OCKS0 | AK4114_OCKS1,
                /* AK4114_REQ_FORMAT */ AK4114_DIF_I24I2S,
                /* AK4114_REG_IO0 */    AK4114_TX1E,
                /* AK4114_REG_IO1 */    AK4114_EFH_1024 | AK4114_DIT |
                                        AK4114_IPS(1),
                /* AK4114_REG_INT0_MASK */ 0,
                /* AK4114_REG_INT1_MASK */ 0
        };
        static const unsigned char ak4114_init_txcsb[] = {
                0x41, 0x02, 0x2c, 0x00, 0x00
        };
        int err;
        struct juli_spec *spec;
        struct snd_akm4xxx *ak;

        spec = kzalloc(sizeof(*spec), GFP_KERNEL);
        if (!spec)
                return -ENOMEM;
        ice->spec = spec;

        err = snd_ak4114_create(ice->card,
                                juli_ak4114_read,
                                juli_ak4114_write,
                                ak4114_init_vals, ak4114_init_txcsb,
                                ice, &spec->ak4114);
        if (err < 0)
                return err;
        /* callback for codecs rate setting */
        spec->ak4114->change_callback = juli_ak4114_change;
        spec->ak4114->change_callback_private = ice;
        /* AK4114 in Juli can detect external rate correctly */
        spec->ak4114->check_flags = 0;

#if 0
/*
 * it seems that the analog doughter board detection does not work reliably, so
 * force the analog flag; it should be very rare (if ever) to come at Juli@
 * used without the analog daughter board
 */
        spec->analog = (ice->gpio.get_data(ice) & GPIO_ANALOG_PRESENT) ? 0 : 1;
#else
        spec->analog = 1;
#endif

        if (spec->analog) {
                dev_info(ice->card->dev, "juli@: analog I/O detected\n");
                ice->num_total_dacs = 2;
                ice->num_total_adcs = 2;

                ice->akm = kzalloc(sizeof(struct snd_akm4xxx), GFP_KERNEL);
                ak = ice->akm;
                if (!ak)
                        return -ENOMEM;
                ice->akm_codecs = 1;
                err = snd_ice1712_akm4xxx_init(ak, &akm_juli_dac, NULL, ice);
                if (err < 0)
                        return err;
        }

        /* juli is clocked by Xilinx array */
        ice->hw_rates = &juli_rates_info;
        ice->is_spdif_master = juli_is_spdif_master;
        ice->get_rate = juli_get_rate;
        ice->set_rate = juli_set_rate;
        ice->set_mclk = juli_set_mclk;
        ice->set_spdif_clock = juli_set_spdif_clock;

        ice->spdif.ops.open = juli_spdif_in_open;

#ifdef CONFIG_PM_SLEEP
        ice->pm_resume = juli_resume;
        ice->pm_suspend = juli_suspend;
        ice->pm_suspend_enabled = 1;
#endif

        return 0;
}


/*
 * Juli@ boards don't provide the EEPROM data except for the vendor IDs.
 * hence the driver needs to sets up it properly.
 */

static unsigned char juli_eeprom[] = {
        [ICE_EEP2_SYSCONF]     = 0x2b,  /* clock 512, mpu401, 1xADC, 1xDACs,
                                           SPDIF in */
        [ICE_EEP2_ACLINK]      = 0x80,  /* I2S */
        [ICE_EEP2_I2S]         = 0xf8,  /* vol, 96k, 24bit, 192k */
        [ICE_EEP2_SPDIF]       = 0xc3,  /* out-en, out-int, spdif-in */
        [ICE_EEP2_GPIO_DIR]    = 0x9f,  /* 5, 6:inputs; 7, 4-0 outputs*/
        [ICE_EEP2_GPIO_DIR1]   = 0xff,
        [ICE_EEP2_GPIO_DIR2]   = 0x7f,
        [ICE_EEP2_GPIO_MASK]   = 0x60,  /* 5, 6: locked; 7, 4-0 writable */
        [ICE_EEP2_GPIO_MASK1]  = 0x00,  /* 0-7 writable */
        [ICE_EEP2_GPIO_MASK2]  = 0x7f,
        [ICE_EEP2_GPIO_STATE]  = GPIO_FREQ_48KHZ | GPIO_MULTI_1X |
               GPIO_INTERNAL_CLOCK,     /* internal clock, multiple 1x, 48kHz*/
        [ICE_EEP2_GPIO_STATE1] = 0x00,  /* unmuted */
        [ICE_EEP2_GPIO_STATE2] = 0x00,
};

/* entry point */
struct snd_ice1712_card_info snd_vt1724_juli_cards[] = {
        {
                .subvendor = VT1724_SUBDEVICE_JULI,
                .name = "ESI Juli@",
                .model = "juli",
                .chip_init = juli_init,
                .build_controls = juli_add_controls,
                .eeprom_size = sizeof(juli_eeprom),
                .eeprom_data = juli_eeprom,
        },
        { } /* terminator */
};