drivers/gpu/drm/bridge/ti-sn65dsi86.c at v6.0-rc2

tjh.dev / kernel
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Linux kernel mirror (for testing) git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
kernel os linux
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kernel / drivers / gpu / drm / bridge / ti-sn65dsi86.c
at v6.0-rc2 1935 lines 55 kB view raw
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   1// SPDX-License-Identifier: GPL-2.0
   2/*
   3 * Copyright (c) 2018, The Linux Foundation. All rights reserved.
   4 * datasheet: https://www.ti.com/lit/ds/symlink/sn65dsi86.pdf
   5 */
   6
   7#include <linux/atomic.h>
   8#include <linux/auxiliary_bus.h>
   9#include <linux/bitfield.h>
  10#include <linux/bits.h>
  11#include <linux/clk.h>
  12#include <linux/debugfs.h>
  13#include <linux/gpio/consumer.h>
  14#include <linux/gpio/driver.h>
  15#include <linux/i2c.h>
  16#include <linux/iopoll.h>
  17#include <linux/module.h>
  18#include <linux/of_graph.h>
  19#include <linux/pm_runtime.h>
  20#include <linux/pwm.h>
  21#include <linux/regmap.h>
  22#include <linux/regulator/consumer.h>
  23
  24#include <asm/unaligned.h>
  25
  26#include <drm/display/drm_dp_aux_bus.h>
  27#include <drm/display/drm_dp_helper.h>
  28#include <drm/drm_atomic.h>
  29#include <drm/drm_atomic_helper.h>
  30#include <drm/drm_bridge.h>
  31#include <drm/drm_bridge_connector.h>
  32#include <drm/drm_mipi_dsi.h>
  33#include <drm/drm_of.h>
  34#include <drm/drm_panel.h>
  35#include <drm/drm_print.h>
  36#include <drm/drm_probe_helper.h>
  37
  38#define SN_DEVICE_REV_REG			0x08
  39#define SN_DPPLL_SRC_REG			0x0A
  40#define  DPPLL_CLK_SRC_DSICLK			BIT(0)
  41#define  REFCLK_FREQ_MASK			GENMASK(3, 1)
  42#define  REFCLK_FREQ(x)				((x) << 1)
  43#define  DPPLL_SRC_DP_PLL_LOCK			BIT(7)
  44#define SN_PLL_ENABLE_REG			0x0D
  45#define SN_DSI_LANES_REG			0x10
  46#define  CHA_DSI_LANES_MASK			GENMASK(4, 3)
  47#define  CHA_DSI_LANES(x)			((x) << 3)
  48#define SN_DSIA_CLK_FREQ_REG			0x12
  49#define SN_CHA_ACTIVE_LINE_LENGTH_LOW_REG	0x20
  50#define SN_CHA_VERTICAL_DISPLAY_SIZE_LOW_REG	0x24
  51#define SN_CHA_HSYNC_PULSE_WIDTH_LOW_REG	0x2C
  52#define SN_CHA_HSYNC_PULSE_WIDTH_HIGH_REG	0x2D
  53#define  CHA_HSYNC_POLARITY			BIT(7)
  54#define SN_CHA_VSYNC_PULSE_WIDTH_LOW_REG	0x30
  55#define SN_CHA_VSYNC_PULSE_WIDTH_HIGH_REG	0x31
  56#define  CHA_VSYNC_POLARITY			BIT(7)
  57#define SN_CHA_HORIZONTAL_BACK_PORCH_REG	0x34
  58#define SN_CHA_VERTICAL_BACK_PORCH_REG		0x36
  59#define SN_CHA_HORIZONTAL_FRONT_PORCH_REG	0x38
  60#define SN_CHA_VERTICAL_FRONT_PORCH_REG		0x3A
  61#define SN_LN_ASSIGN_REG			0x59
  62#define  LN_ASSIGN_WIDTH			2
  63#define SN_ENH_FRAME_REG			0x5A
  64#define  VSTREAM_ENABLE				BIT(3)
  65#define  LN_POLRS_OFFSET			4
  66#define  LN_POLRS_MASK				0xf0
  67#define SN_DATA_FORMAT_REG			0x5B
  68#define  BPP_18_RGB				BIT(0)
  69#define SN_HPD_DISABLE_REG			0x5C
  70#define  HPD_DISABLE				BIT(0)
  71#define SN_GPIO_IO_REG				0x5E
  72#define  SN_GPIO_INPUT_SHIFT			4
  73#define  SN_GPIO_OUTPUT_SHIFT			0
  74#define SN_GPIO_CTRL_REG			0x5F
  75#define  SN_GPIO_MUX_INPUT			0
  76#define  SN_GPIO_MUX_OUTPUT			1
  77#define  SN_GPIO_MUX_SPECIAL			2
  78#define  SN_GPIO_MUX_MASK			0x3
  79#define SN_AUX_WDATA_REG(x)			(0x64 + (x))
  80#define SN_AUX_ADDR_19_16_REG			0x74
  81#define SN_AUX_ADDR_15_8_REG			0x75
  82#define SN_AUX_ADDR_7_0_REG			0x76
  83#define SN_AUX_ADDR_MASK			GENMASK(19, 0)
  84#define SN_AUX_LENGTH_REG			0x77
  85#define SN_AUX_CMD_REG				0x78
  86#define  AUX_CMD_SEND				BIT(0)
  87#define  AUX_CMD_REQ(x)				((x) << 4)
  88#define SN_AUX_RDATA_REG(x)			(0x79 + (x))
  89#define SN_SSC_CONFIG_REG			0x93
  90#define  DP_NUM_LANES_MASK			GENMASK(5, 4)
  91#define  DP_NUM_LANES(x)			((x) << 4)
  92#define SN_DATARATE_CONFIG_REG			0x94
  93#define  DP_DATARATE_MASK			GENMASK(7, 5)
  94#define  DP_DATARATE(x)				((x) << 5)
  95#define SN_ML_TX_MODE_REG			0x96
  96#define  ML_TX_MAIN_LINK_OFF			0
  97#define  ML_TX_NORMAL_MODE			BIT(0)
  98#define SN_PWM_PRE_DIV_REG			0xA0
  99#define SN_BACKLIGHT_SCALE_REG			0xA1
 100#define  BACKLIGHT_SCALE_MAX			0xFFFF
 101#define SN_BACKLIGHT_REG			0xA3
 102#define SN_PWM_EN_INV_REG			0xA5
 103#define  SN_PWM_INV_MASK			BIT(0)
 104#define  SN_PWM_EN_MASK				BIT(1)
 105#define SN_AUX_CMD_STATUS_REG			0xF4
 106#define  AUX_IRQ_STATUS_AUX_RPLY_TOUT		BIT(3)
 107#define  AUX_IRQ_STATUS_AUX_SHORT		BIT(5)
 108#define  AUX_IRQ_STATUS_NAT_I2C_FAIL		BIT(6)
 109
 110#define MIN_DSI_CLK_FREQ_MHZ	40
 111
 112/* fudge factor required to account for 8b/10b encoding */
 113#define DP_CLK_FUDGE_NUM	10
 114#define DP_CLK_FUDGE_DEN	8
 115
 116/* Matches DP_AUX_MAX_PAYLOAD_BYTES (for now) */
 117#define SN_AUX_MAX_PAYLOAD_BYTES	16
 118
 119#define SN_REGULATOR_SUPPLY_NUM		4
 120
 121#define SN_MAX_DP_LANES			4
 122#define SN_NUM_GPIOS			4
 123#define SN_GPIO_PHYSICAL_OFFSET		1
 124
 125#define SN_LINK_TRAINING_TRIES		10
 126
 127#define SN_PWM_GPIO_IDX			3 /* 4th GPIO */
 128
 129/**
 130 * struct ti_sn65dsi86 - Platform data for ti-sn65dsi86 driver.
 131 * @bridge_aux:   AUX-bus sub device for MIPI-to-eDP bridge functionality.
 132 * @gpio_aux:     AUX-bus sub device for GPIO controller functionality.
 133 * @aux_aux:      AUX-bus sub device for eDP AUX channel functionality.
 134 * @pwm_aux:      AUX-bus sub device for PWM controller functionality.
 135 *
 136 * @dev:          Pointer to the top level (i2c) device.
 137 * @regmap:       Regmap for accessing i2c.
 138 * @aux:          Our aux channel.
 139 * @bridge:       Our bridge.
 140 * @connector:    Our connector.
 141 * @host_node:    Remote DSI node.
 142 * @dsi:          Our MIPI DSI source.
 143 * @refclk:       Our reference clock.
 144 * @next_bridge:  The bridge on the eDP side.
 145 * @enable_gpio:  The GPIO we toggle to enable the bridge.
 146 * @supplies:     Data for bulk enabling/disabling our regulators.
 147 * @dp_lanes:     Count of dp_lanes we're using.
 148 * @ln_assign:    Value to program to the LN_ASSIGN register.
 149 * @ln_polrs:     Value for the 4-bit LN_POLRS field of SN_ENH_FRAME_REG.
 150 * @comms_enabled: If true then communication over the aux channel is enabled.
 151 * @comms_mutex:   Protects modification of comms_enabled.
 152 *
 153 * @gchip:        If we expose our GPIOs, this is used.
 154 * @gchip_output: A cache of whether we've set GPIOs to output.  This
 155 *                serves double-duty of keeping track of the direction and
 156 *                also keeping track of whether we've incremented the
 157 *                pm_runtime reference count for this pin, which we do
 158 *                whenever a pin is configured as an output.  This is a
 159 *                bitmap so we can do atomic ops on it without an extra
 160 *                lock so concurrent users of our 4 GPIOs don't stomp on
 161 *                each other's read-modify-write.
 162 *
 163 * @pchip:        pwm_chip if the PWM is exposed.
 164 * @pwm_enabled:  Used to track if the PWM signal is currently enabled.
 165 * @pwm_pin_busy: Track if GPIO4 is currently requested for GPIO or PWM.
 166 * @pwm_refclk_freq: Cache for the reference clock input to the PWM.
 167 */
 168struct ti_sn65dsi86 {
 169	struct auxiliary_device		bridge_aux;
 170	struct auxiliary_device		gpio_aux;
 171	struct auxiliary_device		aux_aux;
 172	struct auxiliary_device		pwm_aux;
 173
 174	struct device			*dev;
 175	struct regmap			*regmap;
 176	struct drm_dp_aux		aux;
 177	struct drm_bridge		bridge;
 178	struct drm_connector		*connector;
 179	struct device_node		*host_node;
 180	struct mipi_dsi_device		*dsi;
 181	struct clk			*refclk;
 182	struct drm_bridge		*next_bridge;
 183	struct gpio_desc		*enable_gpio;
 184	struct regulator_bulk_data	supplies[SN_REGULATOR_SUPPLY_NUM];
 185	int				dp_lanes;
 186	u8				ln_assign;
 187	u8				ln_polrs;
 188	bool				comms_enabled;
 189	struct mutex			comms_mutex;
 190
 191#if defined(CONFIG_OF_GPIO)
 192	struct gpio_chip		gchip;
 193	DECLARE_BITMAP(gchip_output, SN_NUM_GPIOS);
 194#endif
 195#if defined(CONFIG_PWM)
 196	struct pwm_chip			pchip;
 197	bool				pwm_enabled;
 198	atomic_t			pwm_pin_busy;
 199#endif
 200	unsigned int			pwm_refclk_freq;
 201};
 202
 203static const struct regmap_range ti_sn65dsi86_volatile_ranges[] = {
 204	{ .range_min = 0, .range_max = 0xFF },
 205};
 206
 207static const struct regmap_access_table ti_sn_bridge_volatile_table = {
 208	.yes_ranges = ti_sn65dsi86_volatile_ranges,
 209	.n_yes_ranges = ARRAY_SIZE(ti_sn65dsi86_volatile_ranges),
 210};
 211
 212static const struct regmap_config ti_sn65dsi86_regmap_config = {
 213	.reg_bits = 8,
 214	.val_bits = 8,
 215	.volatile_table = &ti_sn_bridge_volatile_table,
 216	.cache_type = REGCACHE_NONE,
 217	.max_register = 0xFF,
 218};
 219
 220static int __maybe_unused ti_sn65dsi86_read_u16(struct ti_sn65dsi86 *pdata,
 221						unsigned int reg, u16 *val)
 222{
 223	u8 buf[2];
 224	int ret;
 225
 226	ret = regmap_bulk_read(pdata->regmap, reg, buf, ARRAY_SIZE(buf));
 227	if (ret)
 228		return ret;
 229
 230	*val = buf[0] | (buf[1] << 8);
 231
 232	return 0;
 233}
 234
 235static void ti_sn65dsi86_write_u16(struct ti_sn65dsi86 *pdata,
 236				   unsigned int reg, u16 val)
 237{
 238	u8 buf[2] = { val & 0xff, val >> 8 };
 239
 240	regmap_bulk_write(pdata->regmap, reg, buf, ARRAY_SIZE(buf));
 241}
 242
 243static u32 ti_sn_bridge_get_dsi_freq(struct ti_sn65dsi86 *pdata)
 244{
 245	u32 bit_rate_khz, clk_freq_khz;
 246	struct drm_display_mode *mode =
 247		&pdata->bridge.encoder->crtc->state->adjusted_mode;
 248
 249	bit_rate_khz = mode->clock *
 250			mipi_dsi_pixel_format_to_bpp(pdata->dsi->format);
 251	clk_freq_khz = bit_rate_khz / (pdata->dsi->lanes * 2);
 252
 253	return clk_freq_khz;
 254}
 255
 256/* clk frequencies supported by bridge in Hz in case derived from REFCLK pin */
 257static const u32 ti_sn_bridge_refclk_lut[] = {
 258	12000000,
 259	19200000,
 260	26000000,
 261	27000000,
 262	38400000,
 263};
 264
 265/* clk frequencies supported by bridge in Hz in case derived from DACP/N pin */
 266static const u32 ti_sn_bridge_dsiclk_lut[] = {
 267	468000000,
 268	384000000,
 269	416000000,
 270	486000000,
 271	460800000,
 272};
 273
 274static void ti_sn_bridge_set_refclk_freq(struct ti_sn65dsi86 *pdata)
 275{
 276	int i;
 277	u32 refclk_rate;
 278	const u32 *refclk_lut;
 279	size_t refclk_lut_size;
 280
 281	if (pdata->refclk) {
 282		refclk_rate = clk_get_rate(pdata->refclk);
 283		refclk_lut = ti_sn_bridge_refclk_lut;
 284		refclk_lut_size = ARRAY_SIZE(ti_sn_bridge_refclk_lut);
 285		clk_prepare_enable(pdata->refclk);
 286	} else {
 287		refclk_rate = ti_sn_bridge_get_dsi_freq(pdata) * 1000;
 288		refclk_lut = ti_sn_bridge_dsiclk_lut;
 289		refclk_lut_size = ARRAY_SIZE(ti_sn_bridge_dsiclk_lut);
 290	}
 291
 292	/* for i equals to refclk_lut_size means default frequency */
 293	for (i = 0; i < refclk_lut_size; i++)
 294		if (refclk_lut[i] == refclk_rate)
 295			break;
 296
 297	regmap_update_bits(pdata->regmap, SN_DPPLL_SRC_REG, REFCLK_FREQ_MASK,
 298			   REFCLK_FREQ(i));
 299
 300	/*
 301	 * The PWM refclk is based on the value written to SN_DPPLL_SRC_REG,
 302	 * regardless of its actual sourcing.
 303	 */
 304	pdata->pwm_refclk_freq = ti_sn_bridge_refclk_lut[i];
 305}
 306
 307static void ti_sn65dsi86_enable_comms(struct ti_sn65dsi86 *pdata)
 308{
 309	mutex_lock(&pdata->comms_mutex);
 310
 311	/* configure bridge ref_clk */
 312	ti_sn_bridge_set_refclk_freq(pdata);
 313
 314	/*
 315	 * HPD on this bridge chip is a bit useless.  This is an eDP bridge
 316	 * so the HPD is an internal signal that's only there to signal that
 317	 * the panel is done powering up.  ...but the bridge chip debounces
 318	 * this signal by between 100 ms and 400 ms (depending on process,
 319	 * voltage, and temperate--I measured it at about 200 ms).  One
 320	 * particular panel asserted HPD 84 ms after it was powered on meaning
 321	 * that we saw HPD 284 ms after power on.  ...but the same panel said
 322	 * that instead of looking at HPD you could just hardcode a delay of
 323	 * 200 ms.  We'll assume that the panel driver will have the hardcoded
 324	 * delay in its prepare and always disable HPD.
 325	 *
 326	 * If HPD somehow makes sense on some future panel we'll have to
 327	 * change this to be conditional on someone specifying that HPD should
 328	 * be used.
 329	 */
 330	regmap_update_bits(pdata->regmap, SN_HPD_DISABLE_REG, HPD_DISABLE,
 331			   HPD_DISABLE);
 332
 333	pdata->comms_enabled = true;
 334
 335	mutex_unlock(&pdata->comms_mutex);
 336}
 337
 338static void ti_sn65dsi86_disable_comms(struct ti_sn65dsi86 *pdata)
 339{
 340	mutex_lock(&pdata->comms_mutex);
 341
 342	pdata->comms_enabled = false;
 343	clk_disable_unprepare(pdata->refclk);
 344
 345	mutex_unlock(&pdata->comms_mutex);
 346}
 347
 348static int __maybe_unused ti_sn65dsi86_resume(struct device *dev)
 349{
 350	struct ti_sn65dsi86 *pdata = dev_get_drvdata(dev);
 351	int ret;
 352
 353	ret = regulator_bulk_enable(SN_REGULATOR_SUPPLY_NUM, pdata->supplies);
 354	if (ret) {
 355		DRM_ERROR("failed to enable supplies %d\n", ret);
 356		return ret;
 357	}
 358
 359	/* td2: min 100 us after regulators before enabling the GPIO */
 360	usleep_range(100, 110);
 361
 362	gpiod_set_value(pdata->enable_gpio, 1);
 363
 364	/*
 365	 * If we have a reference clock we can enable communication w/ the
 366	 * panel (including the aux channel) w/out any need for an input clock
 367	 * so we can do it in resume which lets us read the EDID before
 368	 * pre_enable(). Without a reference clock we need the MIPI reference
 369	 * clock so reading early doesn't work.
 370	 */
 371	if (pdata->refclk)
 372		ti_sn65dsi86_enable_comms(pdata);
 373
 374	return ret;
 375}
 376
 377static int __maybe_unused ti_sn65dsi86_suspend(struct device *dev)
 378{
 379	struct ti_sn65dsi86 *pdata = dev_get_drvdata(dev);
 380	int ret;
 381
 382	if (pdata->refclk)
 383		ti_sn65dsi86_disable_comms(pdata);
 384
 385	gpiod_set_value(pdata->enable_gpio, 0);
 386
 387	ret = regulator_bulk_disable(SN_REGULATOR_SUPPLY_NUM, pdata->supplies);
 388	if (ret)
 389		DRM_ERROR("failed to disable supplies %d\n", ret);
 390
 391	return ret;
 392}
 393
 394static const struct dev_pm_ops ti_sn65dsi86_pm_ops = {
 395	SET_RUNTIME_PM_OPS(ti_sn65dsi86_suspend, ti_sn65dsi86_resume, NULL)
 396	SET_SYSTEM_SLEEP_PM_OPS(pm_runtime_force_suspend,
 397				pm_runtime_force_resume)
 398};
 399
 400static int status_show(struct seq_file *s, void *data)
 401{
 402	struct ti_sn65dsi86 *pdata = s->private;
 403	unsigned int reg, val;
 404
 405	seq_puts(s, "STATUS REGISTERS:\n");
 406
 407	pm_runtime_get_sync(pdata->dev);
 408
 409	/* IRQ Status Registers, see Table 31 in datasheet */
 410	for (reg = 0xf0; reg <= 0xf8; reg++) {
 411		regmap_read(pdata->regmap, reg, &val);
 412		seq_printf(s, "[0x%02x] = 0x%08x\n", reg, val);
 413	}
 414
 415	pm_runtime_put_autosuspend(pdata->dev);
 416
 417	return 0;
 418}
 419
 420DEFINE_SHOW_ATTRIBUTE(status);
 421
 422static void ti_sn65dsi86_debugfs_remove(void *data)
 423{
 424	debugfs_remove_recursive(data);
 425}
 426
 427static void ti_sn65dsi86_debugfs_init(struct ti_sn65dsi86 *pdata)
 428{
 429	struct device *dev = pdata->dev;
 430	struct dentry *debugfs;
 431	int ret;
 432
 433	debugfs = debugfs_create_dir(dev_name(dev), NULL);
 434
 435	/*
 436	 * We might get an error back if debugfs wasn't enabled in the kernel
 437	 * so let's just silently return upon failure.
 438	 */
 439	if (IS_ERR_OR_NULL(debugfs))
 440		return;
 441
 442	ret = devm_add_action_or_reset(dev, ti_sn65dsi86_debugfs_remove, debugfs);
 443	if (ret)
 444		return;
 445
 446	debugfs_create_file("status", 0600, debugfs, pdata, &status_fops);
 447}
 448
 449/* -----------------------------------------------------------------------------
 450 * Auxiliary Devices (*not* AUX)
 451 */
 452
 453static void ti_sn65dsi86_uninit_aux(void *data)
 454{
 455	auxiliary_device_uninit(data);
 456}
 457
 458static void ti_sn65dsi86_delete_aux(void *data)
 459{
 460	auxiliary_device_delete(data);
 461}
 462
 463/*
 464 * AUX bus docs say that a non-NULL release is mandatory, but it makes no
 465 * sense for the model used here where all of the aux devices are allocated
 466 * in the single shared structure. We'll use this noop as a workaround.
 467 */
 468static void ti_sn65dsi86_noop(struct device *dev) {}
 469
 470static int ti_sn65dsi86_add_aux_device(struct ti_sn65dsi86 *pdata,
 471				       struct auxiliary_device *aux,
 472				       const char *name)
 473{
 474	struct device *dev = pdata->dev;
 475	int ret;
 476
 477	aux->name = name;
 478	aux->dev.parent = dev;
 479	aux->dev.release = ti_sn65dsi86_noop;
 480	device_set_of_node_from_dev(&aux->dev, dev);
 481	ret = auxiliary_device_init(aux);
 482	if (ret)
 483		return ret;
 484	ret = devm_add_action_or_reset(dev, ti_sn65dsi86_uninit_aux, aux);
 485	if (ret)
 486		return ret;
 487
 488	ret = auxiliary_device_add(aux);
 489	if (ret)
 490		return ret;
 491	ret = devm_add_action_or_reset(dev, ti_sn65dsi86_delete_aux, aux);
 492
 493	return ret;
 494}
 495
 496/* -----------------------------------------------------------------------------
 497 * AUX Adapter
 498 */
 499
 500static struct ti_sn65dsi86 *aux_to_ti_sn65dsi86(struct drm_dp_aux *aux)
 501{
 502	return container_of(aux, struct ti_sn65dsi86, aux);
 503}
 504
 505static ssize_t ti_sn_aux_transfer(struct drm_dp_aux *aux,
 506				  struct drm_dp_aux_msg *msg)
 507{
 508	struct ti_sn65dsi86 *pdata = aux_to_ti_sn65dsi86(aux);
 509	u32 request = msg->request & ~(DP_AUX_I2C_MOT | DP_AUX_I2C_WRITE_STATUS_UPDATE);
 510	u32 request_val = AUX_CMD_REQ(msg->request);
 511	u8 *buf = msg->buffer;
 512	unsigned int len = msg->size;
 513	unsigned int val;
 514	int ret;
 515	u8 addr_len[SN_AUX_LENGTH_REG + 1 - SN_AUX_ADDR_19_16_REG];
 516
 517	if (len > SN_AUX_MAX_PAYLOAD_BYTES)
 518		return -EINVAL;
 519
 520	pm_runtime_get_sync(pdata->dev);
 521	mutex_lock(&pdata->comms_mutex);
 522
 523	/*
 524	 * If someone tries to do a DDC over AUX transaction before pre_enable()
 525	 * on a device without a dedicated reference clock then we just can't
 526	 * do it. Fail right away. This prevents non-refclk users from reading
 527	 * the EDID before enabling the panel but such is life.
 528	 */
 529	if (!pdata->comms_enabled) {
 530		ret = -EIO;
 531		goto exit;
 532	}
 533
 534	switch (request) {
 535	case DP_AUX_NATIVE_WRITE:
 536	case DP_AUX_I2C_WRITE:
 537	case DP_AUX_NATIVE_READ:
 538	case DP_AUX_I2C_READ:
 539		regmap_write(pdata->regmap, SN_AUX_CMD_REG, request_val);
 540		/* Assume it's good */
 541		msg->reply = 0;
 542		break;
 543	default:
 544		ret = -EINVAL;
 545		goto exit;
 546	}
 547
 548	BUILD_BUG_ON(sizeof(addr_len) != sizeof(__be32));
 549	put_unaligned_be32((msg->address & SN_AUX_ADDR_MASK) << 8 | len,
 550			   addr_len);
 551	regmap_bulk_write(pdata->regmap, SN_AUX_ADDR_19_16_REG, addr_len,
 552			  ARRAY_SIZE(addr_len));
 553
 554	if (request == DP_AUX_NATIVE_WRITE || request == DP_AUX_I2C_WRITE)
 555		regmap_bulk_write(pdata->regmap, SN_AUX_WDATA_REG(0), buf, len);
 556
 557	/* Clear old status bits before start so we don't get confused */
 558	regmap_write(pdata->regmap, SN_AUX_CMD_STATUS_REG,
 559		     AUX_IRQ_STATUS_NAT_I2C_FAIL |
 560		     AUX_IRQ_STATUS_AUX_RPLY_TOUT |
 561		     AUX_IRQ_STATUS_AUX_SHORT);
 562
 563	regmap_write(pdata->regmap, SN_AUX_CMD_REG, request_val | AUX_CMD_SEND);
 564
 565	/* Zero delay loop because i2c transactions are slow already */
 566	ret = regmap_read_poll_timeout(pdata->regmap, SN_AUX_CMD_REG, val,
 567				       !(val & AUX_CMD_SEND), 0, 50 * 1000);
 568	if (ret)
 569		goto exit;
 570
 571	ret = regmap_read(pdata->regmap, SN_AUX_CMD_STATUS_REG, &val);
 572	if (ret)
 573		goto exit;
 574
 575	if (val & AUX_IRQ_STATUS_AUX_RPLY_TOUT) {
 576		/*
 577		 * The hardware tried the message seven times per the DP spec
 578		 * but it hit a timeout. We ignore defers here because they're
 579		 * handled in hardware.
 580		 */
 581		ret = -ETIMEDOUT;
 582		goto exit;
 583	}
 584
 585	if (val & AUX_IRQ_STATUS_AUX_SHORT) {
 586		ret = regmap_read(pdata->regmap, SN_AUX_LENGTH_REG, &len);
 587		if (ret)
 588			goto exit;
 589	} else if (val & AUX_IRQ_STATUS_NAT_I2C_FAIL) {
 590		switch (request) {
 591		case DP_AUX_I2C_WRITE:
 592		case DP_AUX_I2C_READ:
 593			msg->reply |= DP_AUX_I2C_REPLY_NACK;
 594			break;
 595		case DP_AUX_NATIVE_READ:
 596		case DP_AUX_NATIVE_WRITE:
 597			msg->reply |= DP_AUX_NATIVE_REPLY_NACK;
 598			break;
 599		}
 600		len = 0;
 601		goto exit;
 602	}
 603
 604	if (request != DP_AUX_NATIVE_WRITE && request != DP_AUX_I2C_WRITE && len != 0)
 605		ret = regmap_bulk_read(pdata->regmap, SN_AUX_RDATA_REG(0), buf, len);
 606
 607exit:
 608	mutex_unlock(&pdata->comms_mutex);
 609	pm_runtime_mark_last_busy(pdata->dev);
 610	pm_runtime_put_autosuspend(pdata->dev);
 611
 612	if (ret)
 613		return ret;
 614	return len;
 615}
 616
 617static int ti_sn_aux_probe(struct auxiliary_device *adev,
 618			   const struct auxiliary_device_id *id)
 619{
 620	struct ti_sn65dsi86 *pdata = dev_get_drvdata(adev->dev.parent);
 621	int ret;
 622
 623	pdata->aux.name = "ti-sn65dsi86-aux";
 624	pdata->aux.dev = &adev->dev;
 625	pdata->aux.transfer = ti_sn_aux_transfer;
 626	drm_dp_aux_init(&pdata->aux);
 627
 628	ret = devm_of_dp_aux_populate_ep_devices(&pdata->aux);
 629	if (ret)
 630		return ret;
 631
 632	/*
 633	 * The eDP to MIPI bridge parts don't work until the AUX channel is
 634	 * setup so we don't add it in the main driver probe, we add it now.
 635	 */
 636	return ti_sn65dsi86_add_aux_device(pdata, &pdata->bridge_aux, "bridge");
 637}
 638
 639static const struct auxiliary_device_id ti_sn_aux_id_table[] = {
 640	{ .name = "ti_sn65dsi86.aux", },
 641	{},
 642};
 643
 644static struct auxiliary_driver ti_sn_aux_driver = {
 645	.name = "aux",
 646	.probe = ti_sn_aux_probe,
 647	.id_table = ti_sn_aux_id_table,
 648};
 649
 650/*------------------------------------------------------------------------------
 651 * DRM Bridge
 652 */
 653
 654static struct ti_sn65dsi86 *bridge_to_ti_sn65dsi86(struct drm_bridge *bridge)
 655{
 656	return container_of(bridge, struct ti_sn65dsi86, bridge);
 657}
 658
 659static int ti_sn_attach_host(struct ti_sn65dsi86 *pdata)
 660{
 661	int val;
 662	struct mipi_dsi_host *host;
 663	struct mipi_dsi_device *dsi;
 664	struct device *dev = pdata->dev;
 665	const struct mipi_dsi_device_info info = { .type = "ti_sn_bridge",
 666						   .channel = 0,
 667						   .node = NULL,
 668	};
 669
 670	host = of_find_mipi_dsi_host_by_node(pdata->host_node);
 671	if (!host)
 672		return -EPROBE_DEFER;
 673
 674	dsi = devm_mipi_dsi_device_register_full(dev, host, &info);
 675	if (IS_ERR(dsi))
 676		return PTR_ERR(dsi);
 677
 678	/* TODO: setting to 4 MIPI lanes always for now */
 679	dsi->lanes = 4;
 680	dsi->format = MIPI_DSI_FMT_RGB888;
 681	dsi->mode_flags = MIPI_DSI_MODE_VIDEO;
 682
 683	/* check if continuous dsi clock is required or not */
 684	pm_runtime_get_sync(dev);
 685	regmap_read(pdata->regmap, SN_DPPLL_SRC_REG, &val);
 686	pm_runtime_put_autosuspend(dev);
 687	if (!(val & DPPLL_CLK_SRC_DSICLK))
 688		dsi->mode_flags |= MIPI_DSI_CLOCK_NON_CONTINUOUS;
 689
 690	pdata->dsi = dsi;
 691
 692	return devm_mipi_dsi_attach(dev, dsi);
 693}
 694
 695static int ti_sn_bridge_attach(struct drm_bridge *bridge,
 696			       enum drm_bridge_attach_flags flags)
 697{
 698	struct ti_sn65dsi86 *pdata = bridge_to_ti_sn65dsi86(bridge);
 699	int ret;
 700
 701	if (flags & DRM_BRIDGE_ATTACH_NO_CONNECTOR) {
 702		DRM_ERROR("Fix bridge driver to make connector optional!");
 703		return -EINVAL;
 704	}
 705
 706	pdata->aux.drm_dev = bridge->dev;
 707	ret = drm_dp_aux_register(&pdata->aux);
 708	if (ret < 0) {
 709		drm_err(bridge->dev, "Failed to register DP AUX channel: %d\n", ret);
 710		return ret;
 711	}
 712
 713	/* We never want the next bridge to *also* create a connector: */
 714	flags |= DRM_BRIDGE_ATTACH_NO_CONNECTOR;
 715
 716	/* Attach the next bridge */
 717	ret = drm_bridge_attach(bridge->encoder, pdata->next_bridge,
 718				&pdata->bridge, flags);
 719	if (ret < 0)
 720		goto err_initted_aux;
 721
 722	pdata->connector = drm_bridge_connector_init(pdata->bridge.dev,
 723						     pdata->bridge.encoder);
 724	if (IS_ERR(pdata->connector)) {
 725		ret = PTR_ERR(pdata->connector);
 726		goto err_initted_aux;
 727	}
 728
 729	drm_connector_attach_encoder(pdata->connector, pdata->bridge.encoder);
 730
 731	return 0;
 732
 733err_initted_aux:
 734	drm_dp_aux_unregister(&pdata->aux);
 735	return ret;
 736}
 737
 738static void ti_sn_bridge_detach(struct drm_bridge *bridge)
 739{
 740	drm_dp_aux_unregister(&bridge_to_ti_sn65dsi86(bridge)->aux);
 741}
 742
 743static enum drm_mode_status
 744ti_sn_bridge_mode_valid(struct drm_bridge *bridge,
 745			const struct drm_display_info *info,
 746			const struct drm_display_mode *mode)
 747{
 748	/* maximum supported resolution is 4K at 60 fps */
 749	if (mode->clock > 594000)
 750		return MODE_CLOCK_HIGH;
 751
 752	return MODE_OK;
 753}
 754
 755static void ti_sn_bridge_atomic_disable(struct drm_bridge *bridge,
 756					struct drm_bridge_state *old_bridge_state)
 757{
 758	struct ti_sn65dsi86 *pdata = bridge_to_ti_sn65dsi86(bridge);
 759
 760	/* disable video stream */
 761	regmap_update_bits(pdata->regmap, SN_ENH_FRAME_REG, VSTREAM_ENABLE, 0);
 762}
 763
 764static void ti_sn_bridge_set_dsi_rate(struct ti_sn65dsi86 *pdata)
 765{
 766	unsigned int bit_rate_mhz, clk_freq_mhz;
 767	unsigned int val;
 768	struct drm_display_mode *mode =
 769		&pdata->bridge.encoder->crtc->state->adjusted_mode;
 770
 771	/* set DSIA clk frequency */
 772	bit_rate_mhz = (mode->clock / 1000) *
 773			mipi_dsi_pixel_format_to_bpp(pdata->dsi->format);
 774	clk_freq_mhz = bit_rate_mhz / (pdata->dsi->lanes * 2);
 775
 776	/* for each increment in val, frequency increases by 5MHz */
 777	val = (MIN_DSI_CLK_FREQ_MHZ / 5) +
 778		(((clk_freq_mhz - MIN_DSI_CLK_FREQ_MHZ) / 5) & 0xFF);
 779	regmap_write(pdata->regmap, SN_DSIA_CLK_FREQ_REG, val);
 780}
 781
 782static unsigned int ti_sn_bridge_get_bpp(struct ti_sn65dsi86 *pdata)
 783{
 784	if (pdata->connector->display_info.bpc <= 6)
 785		return 18;
 786	else
 787		return 24;
 788}
 789
 790/*
 791 * LUT index corresponds to register value and
 792 * LUT values corresponds to dp data rate supported
 793 * by the bridge in Mbps unit.
 794 */
 795static const unsigned int ti_sn_bridge_dp_rate_lut[] = {
 796	0, 1620, 2160, 2430, 2700, 3240, 4320, 5400
 797};
 798
 799static int ti_sn_bridge_calc_min_dp_rate_idx(struct ti_sn65dsi86 *pdata)
 800{
 801	unsigned int bit_rate_khz, dp_rate_mhz;
 802	unsigned int i;
 803	struct drm_display_mode *mode =
 804		&pdata->bridge.encoder->crtc->state->adjusted_mode;
 805
 806	/* Calculate minimum bit rate based on our pixel clock. */
 807	bit_rate_khz = mode->clock * ti_sn_bridge_get_bpp(pdata);
 808
 809	/* Calculate minimum DP data rate, taking 80% as per DP spec */
 810	dp_rate_mhz = DIV_ROUND_UP(bit_rate_khz * DP_CLK_FUDGE_NUM,
 811				   1000 * pdata->dp_lanes * DP_CLK_FUDGE_DEN);
 812
 813	for (i = 1; i < ARRAY_SIZE(ti_sn_bridge_dp_rate_lut) - 1; i++)
 814		if (ti_sn_bridge_dp_rate_lut[i] >= dp_rate_mhz)
 815			break;
 816
 817	return i;
 818}
 819
 820static unsigned int ti_sn_bridge_read_valid_rates(struct ti_sn65dsi86 *pdata)
 821{
 822	unsigned int valid_rates = 0;
 823	unsigned int rate_per_200khz;
 824	unsigned int rate_mhz;
 825	u8 dpcd_val;
 826	int ret;
 827	int i, j;
 828
 829	ret = drm_dp_dpcd_readb(&pdata->aux, DP_EDP_DPCD_REV, &dpcd_val);
 830	if (ret != 1) {
 831		DRM_DEV_ERROR(pdata->dev,
 832			      "Can't read eDP rev (%d), assuming 1.1\n", ret);
 833		dpcd_val = DP_EDP_11;
 834	}
 835
 836	if (dpcd_val >= DP_EDP_14) {
 837		/* eDP 1.4 devices must provide a custom table */
 838		__le16 sink_rates[DP_MAX_SUPPORTED_RATES];
 839
 840		ret = drm_dp_dpcd_read(&pdata->aux, DP_SUPPORTED_LINK_RATES,
 841				       sink_rates, sizeof(sink_rates));
 842
 843		if (ret != sizeof(sink_rates)) {
 844			DRM_DEV_ERROR(pdata->dev,
 845				"Can't read supported rate table (%d)\n", ret);
 846
 847			/* By zeroing we'll fall back to DP_MAX_LINK_RATE. */
 848			memset(sink_rates, 0, sizeof(sink_rates));
 849		}
 850
 851		for (i = 0; i < ARRAY_SIZE(sink_rates); i++) {
 852			rate_per_200khz = le16_to_cpu(sink_rates[i]);
 853
 854			if (!rate_per_200khz)
 855				break;
 856
 857			rate_mhz = rate_per_200khz * 200 / 1000;
 858			for (j = 0;
 859			     j < ARRAY_SIZE(ti_sn_bridge_dp_rate_lut);
 860			     j++) {
 861				if (ti_sn_bridge_dp_rate_lut[j] == rate_mhz)
 862					valid_rates |= BIT(j);
 863			}
 864		}
 865
 866		for (i = 0; i < ARRAY_SIZE(ti_sn_bridge_dp_rate_lut); i++) {
 867			if (valid_rates & BIT(i))
 868				return valid_rates;
 869		}
 870		DRM_DEV_ERROR(pdata->dev,
 871			      "No matching eDP rates in table; falling back\n");
 872	}
 873
 874	/* On older versions best we can do is use DP_MAX_LINK_RATE */
 875	ret = drm_dp_dpcd_readb(&pdata->aux, DP_MAX_LINK_RATE, &dpcd_val);
 876	if (ret != 1) {
 877		DRM_DEV_ERROR(pdata->dev,
 878			      "Can't read max rate (%d); assuming 5.4 GHz\n",
 879			      ret);
 880		dpcd_val = DP_LINK_BW_5_4;
 881	}
 882
 883	switch (dpcd_val) {
 884	default:
 885		DRM_DEV_ERROR(pdata->dev,
 886			      "Unexpected max rate (%#x); assuming 5.4 GHz\n",
 887			      (int)dpcd_val);
 888		fallthrough;
 889	case DP_LINK_BW_5_4:
 890		valid_rates |= BIT(7);
 891		fallthrough;
 892	case DP_LINK_BW_2_7:
 893		valid_rates |= BIT(4);
 894		fallthrough;
 895	case DP_LINK_BW_1_62:
 896		valid_rates |= BIT(1);
 897		break;
 898	}
 899
 900	return valid_rates;
 901}
 902
 903static void ti_sn_bridge_set_video_timings(struct ti_sn65dsi86 *pdata)
 904{
 905	struct drm_display_mode *mode =
 906		&pdata->bridge.encoder->crtc->state->adjusted_mode;
 907	u8 hsync_polarity = 0, vsync_polarity = 0;
 908
 909	if (mode->flags & DRM_MODE_FLAG_PHSYNC)
 910		hsync_polarity = CHA_HSYNC_POLARITY;
 911	if (mode->flags & DRM_MODE_FLAG_PVSYNC)
 912		vsync_polarity = CHA_VSYNC_POLARITY;
 913
 914	ti_sn65dsi86_write_u16(pdata, SN_CHA_ACTIVE_LINE_LENGTH_LOW_REG,
 915			       mode->hdisplay);
 916	ti_sn65dsi86_write_u16(pdata, SN_CHA_VERTICAL_DISPLAY_SIZE_LOW_REG,
 917			       mode->vdisplay);
 918	regmap_write(pdata->regmap, SN_CHA_HSYNC_PULSE_WIDTH_LOW_REG,
 919		     (mode->hsync_end - mode->hsync_start) & 0xFF);
 920	regmap_write(pdata->regmap, SN_CHA_HSYNC_PULSE_WIDTH_HIGH_REG,
 921		     (((mode->hsync_end - mode->hsync_start) >> 8) & 0x7F) |
 922		     hsync_polarity);
 923	regmap_write(pdata->regmap, SN_CHA_VSYNC_PULSE_WIDTH_LOW_REG,
 924		     (mode->vsync_end - mode->vsync_start) & 0xFF);
 925	regmap_write(pdata->regmap, SN_CHA_VSYNC_PULSE_WIDTH_HIGH_REG,
 926		     (((mode->vsync_end - mode->vsync_start) >> 8) & 0x7F) |
 927		     vsync_polarity);
 928
 929	regmap_write(pdata->regmap, SN_CHA_HORIZONTAL_BACK_PORCH_REG,
 930		     (mode->htotal - mode->hsync_end) & 0xFF);
 931	regmap_write(pdata->regmap, SN_CHA_VERTICAL_BACK_PORCH_REG,
 932		     (mode->vtotal - mode->vsync_end) & 0xFF);
 933
 934	regmap_write(pdata->regmap, SN_CHA_HORIZONTAL_FRONT_PORCH_REG,
 935		     (mode->hsync_start - mode->hdisplay) & 0xFF);
 936	regmap_write(pdata->regmap, SN_CHA_VERTICAL_FRONT_PORCH_REG,
 937		     (mode->vsync_start - mode->vdisplay) & 0xFF);
 938
 939	usleep_range(10000, 10500); /* 10ms delay recommended by spec */
 940}
 941
 942static unsigned int ti_sn_get_max_lanes(struct ti_sn65dsi86 *pdata)
 943{
 944	u8 data;
 945	int ret;
 946
 947	ret = drm_dp_dpcd_readb(&pdata->aux, DP_MAX_LANE_COUNT, &data);
 948	if (ret != 1) {
 949		DRM_DEV_ERROR(pdata->dev,
 950			      "Can't read lane count (%d); assuming 4\n", ret);
 951		return 4;
 952	}
 953
 954	return data & DP_LANE_COUNT_MASK;
 955}
 956
 957static int ti_sn_link_training(struct ti_sn65dsi86 *pdata, int dp_rate_idx,
 958			       const char **last_err_str)
 959{
 960	unsigned int val;
 961	int ret;
 962	int i;
 963
 964	/* set dp clk frequency value */
 965	regmap_update_bits(pdata->regmap, SN_DATARATE_CONFIG_REG,
 966			   DP_DATARATE_MASK, DP_DATARATE(dp_rate_idx));
 967
 968	/* enable DP PLL */
 969	regmap_write(pdata->regmap, SN_PLL_ENABLE_REG, 1);
 970
 971	ret = regmap_read_poll_timeout(pdata->regmap, SN_DPPLL_SRC_REG, val,
 972				       val & DPPLL_SRC_DP_PLL_LOCK, 1000,
 973				       50 * 1000);
 974	if (ret) {
 975		*last_err_str = "DP_PLL_LOCK polling failed";
 976		goto exit;
 977	}
 978
 979	/*
 980	 * We'll try to link train several times.  As part of link training
 981	 * the bridge chip will write DP_SET_POWER_D0 to DP_SET_POWER.  If
 982	 * the panel isn't ready quite it might respond NAK here which means
 983	 * we need to try again.
 984	 */
 985	for (i = 0; i < SN_LINK_TRAINING_TRIES; i++) {
 986		/* Semi auto link training mode */
 987		regmap_write(pdata->regmap, SN_ML_TX_MODE_REG, 0x0A);
 988		ret = regmap_read_poll_timeout(pdata->regmap, SN_ML_TX_MODE_REG, val,
 989					       val == ML_TX_MAIN_LINK_OFF ||
 990					       val == ML_TX_NORMAL_MODE, 1000,
 991					       500 * 1000);
 992		if (ret) {
 993			*last_err_str = "Training complete polling failed";
 994		} else if (val == ML_TX_MAIN_LINK_OFF) {
 995			*last_err_str = "Link training failed, link is off";
 996			ret = -EIO;
 997			continue;
 998		}
 999
1000		break;
1001	}
1002
1003	/* If we saw quite a few retries, add a note about it */
1004	if (!ret && i > SN_LINK_TRAINING_TRIES / 2)
1005		DRM_DEV_INFO(pdata->dev, "Link training needed %d retries\n", i);
1006
1007exit:
1008	/* Disable the PLL if we failed */
1009	if (ret)
1010		regmap_write(pdata->regmap, SN_PLL_ENABLE_REG, 0);
1011
1012	return ret;
1013}
1014
1015static void ti_sn_bridge_atomic_enable(struct drm_bridge *bridge,
1016				       struct drm_bridge_state *old_bridge_state)
1017{
1018	struct ti_sn65dsi86 *pdata = bridge_to_ti_sn65dsi86(bridge);
1019	const char *last_err_str = "No supported DP rate";
1020	unsigned int valid_rates;
1021	int dp_rate_idx;
1022	unsigned int val;
1023	int ret = -EINVAL;
1024	int max_dp_lanes;
1025
1026	max_dp_lanes = ti_sn_get_max_lanes(pdata);
1027	pdata->dp_lanes = min(pdata->dp_lanes, max_dp_lanes);
1028
1029	/* DSI_A lane config */
1030	val = CHA_DSI_LANES(SN_MAX_DP_LANES - pdata->dsi->lanes);
1031	regmap_update_bits(pdata->regmap, SN_DSI_LANES_REG,
1032			   CHA_DSI_LANES_MASK, val);
1033
1034	regmap_write(pdata->regmap, SN_LN_ASSIGN_REG, pdata->ln_assign);
1035	regmap_update_bits(pdata->regmap, SN_ENH_FRAME_REG, LN_POLRS_MASK,
1036			   pdata->ln_polrs << LN_POLRS_OFFSET);
1037
1038	/* set dsi clk frequency value */
1039	ti_sn_bridge_set_dsi_rate(pdata);
1040
1041	/*
1042	 * The SN65DSI86 only supports ASSR Display Authentication method and
1043	 * this method is enabled by default. An eDP panel must support this
1044	 * authentication method. We need to enable this method in the eDP panel
1045	 * at DisplayPort address 0x0010A prior to link training.
1046	 */
1047	drm_dp_dpcd_writeb(&pdata->aux, DP_EDP_CONFIGURATION_SET,
1048			   DP_ALTERNATE_SCRAMBLER_RESET_ENABLE);
1049
1050	/* Set the DP output format (18 bpp or 24 bpp) */
1051	val = (ti_sn_bridge_get_bpp(pdata) == 18) ? BPP_18_RGB : 0;
1052	regmap_update_bits(pdata->regmap, SN_DATA_FORMAT_REG, BPP_18_RGB, val);
1053
1054	/* DP lane config */
1055	val = DP_NUM_LANES(min(pdata->dp_lanes, 3));
1056	regmap_update_bits(pdata->regmap, SN_SSC_CONFIG_REG, DP_NUM_LANES_MASK,
1057			   val);
1058
1059	valid_rates = ti_sn_bridge_read_valid_rates(pdata);
1060
1061	/* Train until we run out of rates */
1062	for (dp_rate_idx = ti_sn_bridge_calc_min_dp_rate_idx(pdata);
1063	     dp_rate_idx < ARRAY_SIZE(ti_sn_bridge_dp_rate_lut);
1064	     dp_rate_idx++) {
1065		if (!(valid_rates & BIT(dp_rate_idx)))
1066			continue;
1067
1068		ret = ti_sn_link_training(pdata, dp_rate_idx, &last_err_str);
1069		if (!ret)
1070			break;
1071	}
1072	if (ret) {
1073		DRM_DEV_ERROR(pdata->dev, "%s (%d)\n", last_err_str, ret);
1074		return;
1075	}
1076
1077	/* config video parameters */
1078	ti_sn_bridge_set_video_timings(pdata);
1079
1080	/* enable video stream */
1081	regmap_update_bits(pdata->regmap, SN_ENH_FRAME_REG, VSTREAM_ENABLE,
1082			   VSTREAM_ENABLE);
1083}
1084
1085static void ti_sn_bridge_atomic_pre_enable(struct drm_bridge *bridge,
1086					   struct drm_bridge_state *old_bridge_state)
1087{
1088	struct ti_sn65dsi86 *pdata = bridge_to_ti_sn65dsi86(bridge);
1089
1090	pm_runtime_get_sync(pdata->dev);
1091
1092	if (!pdata->refclk)
1093		ti_sn65dsi86_enable_comms(pdata);
1094
1095	/* td7: min 100 us after enable before DSI data */
1096	usleep_range(100, 110);
1097}
1098
1099static void ti_sn_bridge_atomic_post_disable(struct drm_bridge *bridge,
1100					     struct drm_bridge_state *old_bridge_state)
1101{
1102	struct ti_sn65dsi86 *pdata = bridge_to_ti_sn65dsi86(bridge);
1103
1104	/* semi auto link training mode OFF */
1105	regmap_write(pdata->regmap, SN_ML_TX_MODE_REG, 0);
1106	/* Num lanes to 0 as per power sequencing in data sheet */
1107	regmap_update_bits(pdata->regmap, SN_SSC_CONFIG_REG, DP_NUM_LANES_MASK, 0);
1108	/* disable DP PLL */
1109	regmap_write(pdata->regmap, SN_PLL_ENABLE_REG, 0);
1110
1111	if (!pdata->refclk)
1112		ti_sn65dsi86_disable_comms(pdata);
1113
1114	pm_runtime_put_sync(pdata->dev);
1115}
1116
1117static const struct drm_bridge_funcs ti_sn_bridge_funcs = {
1118	.attach = ti_sn_bridge_attach,
1119	.detach = ti_sn_bridge_detach,
1120	.mode_valid = ti_sn_bridge_mode_valid,
1121	.atomic_pre_enable = ti_sn_bridge_atomic_pre_enable,
1122	.atomic_enable = ti_sn_bridge_atomic_enable,
1123	.atomic_disable = ti_sn_bridge_atomic_disable,
1124	.atomic_post_disable = ti_sn_bridge_atomic_post_disable,
1125	.atomic_reset = drm_atomic_helper_bridge_reset,
1126	.atomic_duplicate_state = drm_atomic_helper_bridge_duplicate_state,
1127	.atomic_destroy_state = drm_atomic_helper_bridge_destroy_state,
1128};
1129
1130static void ti_sn_bridge_parse_lanes(struct ti_sn65dsi86 *pdata,
1131				     struct device_node *np)
1132{
1133	u32 lane_assignments[SN_MAX_DP_LANES] = { 0, 1, 2, 3 };
1134	u32 lane_polarities[SN_MAX_DP_LANES] = { };
1135	struct device_node *endpoint;
1136	u8 ln_assign = 0;
1137	u8 ln_polrs = 0;
1138	int dp_lanes;
1139	int i;
1140
1141	/*
1142	 * Read config from the device tree about lane remapping and lane
1143	 * polarities.  These are optional and we assume identity map and
1144	 * normal polarity if nothing is specified.  It's OK to specify just
1145	 * data-lanes but not lane-polarities but not vice versa.
1146	 *
1147	 * Error checking is light (we just make sure we don't crash or
1148	 * buffer overrun) and we assume dts is well formed and specifying
1149	 * mappings that the hardware supports.
1150	 */
1151	endpoint = of_graph_get_endpoint_by_regs(np, 1, -1);
1152	dp_lanes = drm_of_get_data_lanes_count(endpoint, 1, SN_MAX_DP_LANES);
1153	if (dp_lanes > 0) {
1154		of_property_read_u32_array(endpoint, "data-lanes",
1155					   lane_assignments, dp_lanes);
1156		of_property_read_u32_array(endpoint, "lane-polarities",
1157					   lane_polarities, dp_lanes);
1158	} else {
1159		dp_lanes = SN_MAX_DP_LANES;
1160	}
1161	of_node_put(endpoint);
1162
1163	/*
1164	 * Convert into register format.  Loop over all lanes even if
1165	 * data-lanes had fewer elements so that we nicely initialize
1166	 * the LN_ASSIGN register.
1167	 */
1168	for (i = SN_MAX_DP_LANES - 1; i >= 0; i--) {
1169		ln_assign = ln_assign << LN_ASSIGN_WIDTH | lane_assignments[i];
1170		ln_polrs = ln_polrs << 1 | lane_polarities[i];
1171	}
1172
1173	/* Stash in our struct for when we power on */
1174	pdata->dp_lanes = dp_lanes;
1175	pdata->ln_assign = ln_assign;
1176	pdata->ln_polrs = ln_polrs;
1177}
1178
1179static int ti_sn_bridge_parse_dsi_host(struct ti_sn65dsi86 *pdata)
1180{
1181	struct device_node *np = pdata->dev->of_node;
1182
1183	pdata->host_node = of_graph_get_remote_node(np, 0, 0);
1184
1185	if (!pdata->host_node) {
1186		DRM_ERROR("remote dsi host node not found\n");
1187		return -ENODEV;
1188	}
1189
1190	return 0;
1191}
1192
1193static int ti_sn_bridge_probe(struct auxiliary_device *adev,
1194			      const struct auxiliary_device_id *id)
1195{
1196	struct ti_sn65dsi86 *pdata = dev_get_drvdata(adev->dev.parent);
1197	struct device_node *np = pdata->dev->of_node;
1198	int ret;
1199
1200	pdata->next_bridge = devm_drm_of_get_bridge(pdata->dev, np, 1, 0);
1201	if (IS_ERR(pdata->next_bridge)) {
1202		DRM_ERROR("failed to create panel bridge\n");
1203		return PTR_ERR(pdata->next_bridge);
1204	}
1205
1206	ti_sn_bridge_parse_lanes(pdata, np);
1207
1208	ret = ti_sn_bridge_parse_dsi_host(pdata);
1209	if (ret)
1210		return ret;
1211
1212	pdata->bridge.funcs = &ti_sn_bridge_funcs;
1213	pdata->bridge.of_node = np;
1214
1215	drm_bridge_add(&pdata->bridge);
1216
1217	ret = ti_sn_attach_host(pdata);
1218	if (ret) {
1219		dev_err_probe(pdata->dev, ret, "failed to attach dsi host\n");
1220		goto err_remove_bridge;
1221	}
1222
1223	return 0;
1224
1225err_remove_bridge:
1226	drm_bridge_remove(&pdata->bridge);
1227	return ret;
1228}
1229
1230static void ti_sn_bridge_remove(struct auxiliary_device *adev)
1231{
1232	struct ti_sn65dsi86 *pdata = dev_get_drvdata(adev->dev.parent);
1233
1234	if (!pdata)
1235		return;
1236
1237	drm_bridge_remove(&pdata->bridge);
1238
1239	of_node_put(pdata->host_node);
1240}
1241
1242static const struct auxiliary_device_id ti_sn_bridge_id_table[] = {
1243	{ .name = "ti_sn65dsi86.bridge", },
1244	{},
1245};
1246
1247static struct auxiliary_driver ti_sn_bridge_driver = {
1248	.name = "bridge",
1249	.probe = ti_sn_bridge_probe,
1250	.remove = ti_sn_bridge_remove,
1251	.id_table = ti_sn_bridge_id_table,
1252};
1253
1254/* -----------------------------------------------------------------------------
1255 * PWM Controller
1256 */
1257#if defined(CONFIG_PWM)
1258static int ti_sn_pwm_pin_request(struct ti_sn65dsi86 *pdata)
1259{
1260	return atomic_xchg(&pdata->pwm_pin_busy, 1) ? -EBUSY : 0;
1261}
1262
1263static void ti_sn_pwm_pin_release(struct ti_sn65dsi86 *pdata)
1264{
1265	atomic_set(&pdata->pwm_pin_busy, 0);
1266}
1267
1268static struct ti_sn65dsi86 *pwm_chip_to_ti_sn_bridge(struct pwm_chip *chip)
1269{
1270	return container_of(chip, struct ti_sn65dsi86, pchip);
1271}
1272
1273static int ti_sn_pwm_request(struct pwm_chip *chip, struct pwm_device *pwm)
1274{
1275	struct ti_sn65dsi86 *pdata = pwm_chip_to_ti_sn_bridge(chip);
1276
1277	return ti_sn_pwm_pin_request(pdata);
1278}
1279
1280static void ti_sn_pwm_free(struct pwm_chip *chip, struct pwm_device *pwm)
1281{
1282	struct ti_sn65dsi86 *pdata = pwm_chip_to_ti_sn_bridge(chip);
1283
1284	ti_sn_pwm_pin_release(pdata);
1285}
1286
1287/*
1288 * Limitations:
1289 * - The PWM signal is not driven when the chip is powered down, or in its
1290 *   reset state and the driver does not implement the "suspend state"
1291 *   described in the documentation. In order to save power, state->enabled is
1292 *   interpreted as denoting if the signal is expected to be valid, and is used
1293 *   to determine if the chip needs to be kept powered.
1294 * - Changing both period and duty_cycle is not done atomically, neither is the
1295 *   multi-byte register updates, so the output might briefly be undefined
1296 *   during update.
1297 */
1298static int ti_sn_pwm_apply(struct pwm_chip *chip, struct pwm_device *pwm,
1299			   const struct pwm_state *state)
1300{
1301	struct ti_sn65dsi86 *pdata = pwm_chip_to_ti_sn_bridge(chip);
1302	unsigned int pwm_en_inv;
1303	unsigned int backlight;
1304	unsigned int pre_div;
1305	unsigned int scale;
1306	u64 period_max;
1307	u64 period;
1308	int ret;
1309
1310	if (!pdata->pwm_enabled) {
1311		ret = pm_runtime_get_sync(pdata->dev);
1312		if (ret < 0) {
1313			pm_runtime_put_sync(pdata->dev);
1314			return ret;
1315		}
1316	}
1317
1318	if (state->enabled) {
1319		if (!pdata->pwm_enabled) {
1320			/*
1321			 * The chip might have been powered down while we
1322			 * didn't hold a PM runtime reference, so mux in the
1323			 * PWM function on the GPIO pin again.
1324			 */
1325			ret = regmap_update_bits(pdata->regmap, SN_GPIO_CTRL_REG,
1326						 SN_GPIO_MUX_MASK << (2 * SN_PWM_GPIO_IDX),
1327						 SN_GPIO_MUX_SPECIAL << (2 * SN_PWM_GPIO_IDX));
1328			if (ret) {
1329				dev_err(pdata->dev, "failed to mux in PWM function\n");
1330				goto out;
1331			}
1332		}
1333
1334		/*
1335		 * Per the datasheet the PWM frequency is given by:
1336		 *
1337		 *                          REFCLK_FREQ
1338		 *   PWM_FREQ = -----------------------------------
1339		 *               PWM_PRE_DIV * BACKLIGHT_SCALE + 1
1340		 *
1341		 * However, after careful review the author is convinced that
1342		 * the documentation has lost some parenthesis around
1343		 * "BACKLIGHT_SCALE + 1".
1344		 *
1345		 * With the period T_pwm = 1/PWM_FREQ this can be written:
1346		 *
1347		 *   T_pwm * REFCLK_FREQ = PWM_PRE_DIV * (BACKLIGHT_SCALE + 1)
1348		 *
1349		 * In order to keep BACKLIGHT_SCALE within its 16 bits,
1350		 * PWM_PRE_DIV must be:
1351		 *
1352		 *                     T_pwm * REFCLK_FREQ
1353		 *   PWM_PRE_DIV >= -------------------------
1354		 *                   BACKLIGHT_SCALE_MAX + 1
1355		 *
1356		 * To simplify the search and to favour higher resolution of
1357		 * the duty cycle over accuracy of the period, the lowest
1358		 * possible PWM_PRE_DIV is used. Finally the scale is
1359		 * calculated as:
1360		 *
1361		 *                      T_pwm * REFCLK_FREQ
1362		 *   BACKLIGHT_SCALE = ---------------------- - 1
1363		 *                          PWM_PRE_DIV
1364		 *
1365		 * Here T_pwm is represented in seconds, so appropriate scaling
1366		 * to nanoseconds is necessary.
1367		 */
1368
1369		/* Minimum T_pwm is 1 / REFCLK_FREQ */
1370		if (state->period <= NSEC_PER_SEC / pdata->pwm_refclk_freq) {
1371			ret = -EINVAL;
1372			goto out;
1373		}
1374
1375		/*
1376		 * Maximum T_pwm is 255 * (65535 + 1) / REFCLK_FREQ
1377		 * Limit period to this to avoid overflows
1378		 */
1379		period_max = div_u64((u64)NSEC_PER_SEC * 255 * (65535 + 1),
1380				     pdata->pwm_refclk_freq);
1381		period = min(state->period, period_max);
1382
1383		pre_div = DIV64_U64_ROUND_UP(period * pdata->pwm_refclk_freq,
1384					     (u64)NSEC_PER_SEC * (BACKLIGHT_SCALE_MAX + 1));
1385		scale = div64_u64(period * pdata->pwm_refclk_freq, (u64)NSEC_PER_SEC * pre_div) - 1;
1386
1387		/*
1388		 * The documentation has the duty ratio given as:
1389		 *
1390		 *     duty          BACKLIGHT
1391		 *   ------- = ---------------------
1392		 *    period    BACKLIGHT_SCALE + 1
1393		 *
1394		 * Solve for BACKLIGHT, substituting BACKLIGHT_SCALE according
1395		 * to definition above and adjusting for nanosecond
1396		 * representation of duty cycle gives us:
1397		 */
1398		backlight = div64_u64(state->duty_cycle * pdata->pwm_refclk_freq,
1399				      (u64)NSEC_PER_SEC * pre_div);
1400		if (backlight > scale)
1401			backlight = scale;
1402
1403		ret = regmap_write(pdata->regmap, SN_PWM_PRE_DIV_REG, pre_div);
1404		if (ret) {
1405			dev_err(pdata->dev, "failed to update PWM_PRE_DIV\n");
1406			goto out;
1407		}
1408
1409		ti_sn65dsi86_write_u16(pdata, SN_BACKLIGHT_SCALE_REG, scale);
1410		ti_sn65dsi86_write_u16(pdata, SN_BACKLIGHT_REG, backlight);
1411	}
1412
1413	pwm_en_inv = FIELD_PREP(SN_PWM_EN_MASK, state->enabled) |
1414		     FIELD_PREP(SN_PWM_INV_MASK, state->polarity == PWM_POLARITY_INVERSED);
1415	ret = regmap_write(pdata->regmap, SN_PWM_EN_INV_REG, pwm_en_inv);
1416	if (ret) {
1417		dev_err(pdata->dev, "failed to update PWM_EN/PWM_INV\n");
1418		goto out;
1419	}
1420
1421	pdata->pwm_enabled = state->enabled;
1422out:
1423
1424	if (!pdata->pwm_enabled)
1425		pm_runtime_put_sync(pdata->dev);
1426
1427	return ret;
1428}
1429
1430static void ti_sn_pwm_get_state(struct pwm_chip *chip, struct pwm_device *pwm,
1431				struct pwm_state *state)
1432{
1433	struct ti_sn65dsi86 *pdata = pwm_chip_to_ti_sn_bridge(chip);
1434	unsigned int pwm_en_inv;
1435	unsigned int pre_div;
1436	u16 backlight;
1437	u16 scale;
1438	int ret;
1439
1440	ret = regmap_read(pdata->regmap, SN_PWM_EN_INV_REG, &pwm_en_inv);
1441	if (ret)
1442		return;
1443
1444	ret = ti_sn65dsi86_read_u16(pdata, SN_BACKLIGHT_SCALE_REG, &scale);
1445	if (ret)
1446		return;
1447
1448	ret = ti_sn65dsi86_read_u16(pdata, SN_BACKLIGHT_REG, &backlight);
1449	if (ret)
1450		return;
1451
1452	ret = regmap_read(pdata->regmap, SN_PWM_PRE_DIV_REG, &pre_div);
1453	if (ret)
1454		return;
1455
1456	state->enabled = FIELD_GET(SN_PWM_EN_MASK, pwm_en_inv);
1457	if (FIELD_GET(SN_PWM_INV_MASK, pwm_en_inv))
1458		state->polarity = PWM_POLARITY_INVERSED;
1459	else
1460		state->polarity = PWM_POLARITY_NORMAL;
1461
1462	state->period = DIV_ROUND_UP_ULL((u64)NSEC_PER_SEC * pre_div * (scale + 1),
1463					 pdata->pwm_refclk_freq);
1464	state->duty_cycle = DIV_ROUND_UP_ULL((u64)NSEC_PER_SEC * pre_div * backlight,
1465					     pdata->pwm_refclk_freq);
1466
1467	if (state->duty_cycle > state->period)
1468		state->duty_cycle = state->period;
1469}
1470
1471static const struct pwm_ops ti_sn_pwm_ops = {
1472	.request = ti_sn_pwm_request,
1473	.free = ti_sn_pwm_free,
1474	.apply = ti_sn_pwm_apply,
1475	.get_state = ti_sn_pwm_get_state,
1476	.owner = THIS_MODULE,
1477};
1478
1479static int ti_sn_pwm_probe(struct auxiliary_device *adev,
1480			   const struct auxiliary_device_id *id)
1481{
1482	struct ti_sn65dsi86 *pdata = dev_get_drvdata(adev->dev.parent);
1483
1484	pdata->pchip.dev = pdata->dev;
1485	pdata->pchip.ops = &ti_sn_pwm_ops;
1486	pdata->pchip.npwm = 1;
1487	pdata->pchip.of_xlate = of_pwm_single_xlate;
1488	pdata->pchip.of_pwm_n_cells = 1;
1489
1490	return pwmchip_add(&pdata->pchip);
1491}
1492
1493static void ti_sn_pwm_remove(struct auxiliary_device *adev)
1494{
1495	struct ti_sn65dsi86 *pdata = dev_get_drvdata(adev->dev.parent);
1496
1497	pwmchip_remove(&pdata->pchip);
1498
1499	if (pdata->pwm_enabled)
1500		pm_runtime_put_sync(pdata->dev);
1501}
1502
1503static const struct auxiliary_device_id ti_sn_pwm_id_table[] = {
1504	{ .name = "ti_sn65dsi86.pwm", },
1505	{},
1506};
1507
1508static struct auxiliary_driver ti_sn_pwm_driver = {
1509	.name = "pwm",
1510	.probe = ti_sn_pwm_probe,
1511	.remove = ti_sn_pwm_remove,
1512	.id_table = ti_sn_pwm_id_table,
1513};
1514
1515static int __init ti_sn_pwm_register(void)
1516{
1517	return auxiliary_driver_register(&ti_sn_pwm_driver);
1518}
1519
1520static void ti_sn_pwm_unregister(void)
1521{
1522	auxiliary_driver_unregister(&ti_sn_pwm_driver);
1523}
1524
1525#else
1526static inline int ti_sn_pwm_pin_request(struct ti_sn65dsi86 *pdata) { return 0; }
1527static inline void ti_sn_pwm_pin_release(struct ti_sn65dsi86 *pdata) {}
1528
1529static inline int ti_sn_pwm_register(void) { return 0; }
1530static inline void ti_sn_pwm_unregister(void) {}
1531#endif
1532
1533/* -----------------------------------------------------------------------------
1534 * GPIO Controller
1535 */
1536#if defined(CONFIG_OF_GPIO)
1537
1538static int tn_sn_bridge_of_xlate(struct gpio_chip *chip,
1539				 const struct of_phandle_args *gpiospec,
1540				 u32 *flags)
1541{
1542	if (WARN_ON(gpiospec->args_count < chip->of_gpio_n_cells))
1543		return -EINVAL;
1544
1545	if (gpiospec->args[0] > chip->ngpio || gpiospec->args[0] < 1)
1546		return -EINVAL;
1547
1548	if (flags)
1549		*flags = gpiospec->args[1];
1550
1551	return gpiospec->args[0] - SN_GPIO_PHYSICAL_OFFSET;
1552}
1553
1554static int ti_sn_bridge_gpio_get_direction(struct gpio_chip *chip,
1555					   unsigned int offset)
1556{
1557	struct ti_sn65dsi86 *pdata = gpiochip_get_data(chip);
1558
1559	/*
1560	 * We already have to keep track of the direction because we use
1561	 * that to figure out whether we've powered the device.  We can
1562	 * just return that rather than (maybe) powering up the device
1563	 * to ask its direction.
1564	 */
1565	return test_bit(offset, pdata->gchip_output) ?
1566		GPIO_LINE_DIRECTION_OUT : GPIO_LINE_DIRECTION_IN;
1567}
1568
1569static int ti_sn_bridge_gpio_get(struct gpio_chip *chip, unsigned int offset)
1570{
1571	struct ti_sn65dsi86 *pdata = gpiochip_get_data(chip);
1572	unsigned int val;
1573	int ret;
1574
1575	/*
1576	 * When the pin is an input we don't forcibly keep the bridge
1577	 * powered--we just power it on to read the pin.  NOTE: part of
1578	 * the reason this works is that the bridge defaults (when
1579	 * powered back on) to all 4 GPIOs being configured as GPIO input.
1580	 * Also note that if something else is keeping the chip powered the
1581	 * pm_runtime functions are lightweight increments of a refcount.
1582	 */
1583	pm_runtime_get_sync(pdata->dev);
1584	ret = regmap_read(pdata->regmap, SN_GPIO_IO_REG, &val);
1585	pm_runtime_put_autosuspend(pdata->dev);
1586
1587	if (ret)
1588		return ret;
1589
1590	return !!(val & BIT(SN_GPIO_INPUT_SHIFT + offset));
1591}
1592
1593static void ti_sn_bridge_gpio_set(struct gpio_chip *chip, unsigned int offset,
1594				  int val)
1595{
1596	struct ti_sn65dsi86 *pdata = gpiochip_get_data(chip);
1597	int ret;
1598
1599	if (!test_bit(offset, pdata->gchip_output)) {
1600		dev_err(pdata->dev, "Ignoring GPIO set while input\n");
1601		return;
1602	}
1603
1604	val &= 1;
1605	ret = regmap_update_bits(pdata->regmap, SN_GPIO_IO_REG,
1606				 BIT(SN_GPIO_OUTPUT_SHIFT + offset),
1607				 val << (SN_GPIO_OUTPUT_SHIFT + offset));
1608	if (ret)
1609		dev_warn(pdata->dev,
1610			 "Failed to set bridge GPIO %u: %d\n", offset, ret);
1611}
1612
1613static int ti_sn_bridge_gpio_direction_input(struct gpio_chip *chip,
1614					     unsigned int offset)
1615{
1616	struct ti_sn65dsi86 *pdata = gpiochip_get_data(chip);
1617	int shift = offset * 2;
1618	int ret;
1619
1620	if (!test_and_clear_bit(offset, pdata->gchip_output))
1621		return 0;
1622
1623	ret = regmap_update_bits(pdata->regmap, SN_GPIO_CTRL_REG,
1624				 SN_GPIO_MUX_MASK << shift,
1625				 SN_GPIO_MUX_INPUT << shift);
1626	if (ret) {
1627		set_bit(offset, pdata->gchip_output);
1628		return ret;
1629	}
1630
1631	/*
1632	 * NOTE: if nobody else is powering the device this may fully power
1633	 * it off and when it comes back it will have lost all state, but
1634	 * that's OK because the default is input and we're now an input.
1635	 */
1636	pm_runtime_put_autosuspend(pdata->dev);
1637
1638	return 0;
1639}
1640
1641static int ti_sn_bridge_gpio_direction_output(struct gpio_chip *chip,
1642					      unsigned int offset, int val)
1643{
1644	struct ti_sn65dsi86 *pdata = gpiochip_get_data(chip);
1645	int shift = offset * 2;
1646	int ret;
1647
1648	if (test_and_set_bit(offset, pdata->gchip_output))
1649		return 0;
1650
1651	pm_runtime_get_sync(pdata->dev);
1652
1653	/* Set value first to avoid glitching */
1654	ti_sn_bridge_gpio_set(chip, offset, val);
1655
1656	/* Set direction */
1657	ret = regmap_update_bits(pdata->regmap, SN_GPIO_CTRL_REG,
1658				 SN_GPIO_MUX_MASK << shift,
1659				 SN_GPIO_MUX_OUTPUT << shift);
1660	if (ret) {
1661		clear_bit(offset, pdata->gchip_output);
1662		pm_runtime_put_autosuspend(pdata->dev);
1663	}
1664
1665	return ret;
1666}
1667
1668static int ti_sn_bridge_gpio_request(struct gpio_chip *chip, unsigned int offset)
1669{
1670	struct ti_sn65dsi86 *pdata = gpiochip_get_data(chip);
1671
1672	if (offset == SN_PWM_GPIO_IDX)
1673		return ti_sn_pwm_pin_request(pdata);
1674
1675	return 0;
1676}
1677
1678static void ti_sn_bridge_gpio_free(struct gpio_chip *chip, unsigned int offset)
1679{
1680	struct ti_sn65dsi86 *pdata = gpiochip_get_data(chip);
1681
1682	/* We won't keep pm_runtime if we're input, so switch there on free */
1683	ti_sn_bridge_gpio_direction_input(chip, offset);
1684
1685	if (offset == SN_PWM_GPIO_IDX)
1686		ti_sn_pwm_pin_release(pdata);
1687}
1688
1689static const char * const ti_sn_bridge_gpio_names[SN_NUM_GPIOS] = {
1690	"GPIO1", "GPIO2", "GPIO3", "GPIO4"
1691};
1692
1693static int ti_sn_gpio_probe(struct auxiliary_device *adev,
1694			    const struct auxiliary_device_id *id)
1695{
1696	struct ti_sn65dsi86 *pdata = dev_get_drvdata(adev->dev.parent);
1697	int ret;
1698
1699	/* Only init if someone is going to use us as a GPIO controller */
1700	if (!of_property_read_bool(pdata->dev->of_node, "gpio-controller"))
1701		return 0;
1702
1703	pdata->gchip.label = dev_name(pdata->dev);
1704	pdata->gchip.parent = pdata->dev;
1705	pdata->gchip.owner = THIS_MODULE;
1706	pdata->gchip.of_xlate = tn_sn_bridge_of_xlate;
1707	pdata->gchip.of_gpio_n_cells = 2;
1708	pdata->gchip.request = ti_sn_bridge_gpio_request;
1709	pdata->gchip.free = ti_sn_bridge_gpio_free;
1710	pdata->gchip.get_direction = ti_sn_bridge_gpio_get_direction;
1711	pdata->gchip.direction_input = ti_sn_bridge_gpio_direction_input;
1712	pdata->gchip.direction_output = ti_sn_bridge_gpio_direction_output;
1713	pdata->gchip.get = ti_sn_bridge_gpio_get;
1714	pdata->gchip.set = ti_sn_bridge_gpio_set;
1715	pdata->gchip.can_sleep = true;
1716	pdata->gchip.names = ti_sn_bridge_gpio_names;
1717	pdata->gchip.ngpio = SN_NUM_GPIOS;
1718	pdata->gchip.base = -1;
1719	ret = devm_gpiochip_add_data(&adev->dev, &pdata->gchip, pdata);
1720	if (ret)
1721		dev_err(pdata->dev, "can't add gpio chip\n");
1722
1723	return ret;
1724}
1725
1726static const struct auxiliary_device_id ti_sn_gpio_id_table[] = {
1727	{ .name = "ti_sn65dsi86.gpio", },
1728	{},
1729};
1730
1731MODULE_DEVICE_TABLE(auxiliary, ti_sn_gpio_id_table);
1732
1733static struct auxiliary_driver ti_sn_gpio_driver = {
1734	.name = "gpio",
1735	.probe = ti_sn_gpio_probe,
1736	.id_table = ti_sn_gpio_id_table,
1737};
1738
1739static int __init ti_sn_gpio_register(void)
1740{
1741	return auxiliary_driver_register(&ti_sn_gpio_driver);
1742}
1743
1744static void ti_sn_gpio_unregister(void)
1745{
1746	auxiliary_driver_unregister(&ti_sn_gpio_driver);
1747}
1748
1749#else
1750
1751static inline int ti_sn_gpio_register(void) { return 0; }
1752static inline void ti_sn_gpio_unregister(void) {}
1753
1754#endif
1755
1756/* -----------------------------------------------------------------------------
1757 * Probe & Remove
1758 */
1759
1760static void ti_sn65dsi86_runtime_disable(void *data)
1761{
1762	pm_runtime_dont_use_autosuspend(data);
1763	pm_runtime_disable(data);
1764}
1765
1766static int ti_sn65dsi86_parse_regulators(struct ti_sn65dsi86 *pdata)
1767{
1768	unsigned int i;
1769	const char * const ti_sn_bridge_supply_names[] = {
1770		"vcca", "vcc", "vccio", "vpll",
1771	};
1772
1773	for (i = 0; i < SN_REGULATOR_SUPPLY_NUM; i++)
1774		pdata->supplies[i].supply = ti_sn_bridge_supply_names[i];
1775
1776	return devm_regulator_bulk_get(pdata->dev, SN_REGULATOR_SUPPLY_NUM,
1777				       pdata->supplies);
1778}
1779
1780static int ti_sn65dsi86_probe(struct i2c_client *client,
1781			      const struct i2c_device_id *id)
1782{
1783	struct device *dev = &client->dev;
1784	struct ti_sn65dsi86 *pdata;
1785	int ret;
1786
1787	if (!i2c_check_functionality(client->adapter, I2C_FUNC_I2C)) {
1788		DRM_ERROR("device doesn't support I2C\n");
1789		return -ENODEV;
1790	}
1791
1792	pdata = devm_kzalloc(dev, sizeof(struct ti_sn65dsi86), GFP_KERNEL);
1793	if (!pdata)
1794		return -ENOMEM;
1795	dev_set_drvdata(dev, pdata);
1796	pdata->dev = dev;
1797
1798	mutex_init(&pdata->comms_mutex);
1799
1800	pdata->regmap = devm_regmap_init_i2c(client,
1801					     &ti_sn65dsi86_regmap_config);
1802	if (IS_ERR(pdata->regmap))
1803		return dev_err_probe(dev, PTR_ERR(pdata->regmap),
1804				     "regmap i2c init failed\n");
1805
1806	pdata->enable_gpio = devm_gpiod_get_optional(dev, "enable",
1807						     GPIOD_OUT_LOW);
1808	if (IS_ERR(pdata->enable_gpio))
1809		return dev_err_probe(dev, PTR_ERR(pdata->enable_gpio),
1810				     "failed to get enable gpio from DT\n");
1811
1812	ret = ti_sn65dsi86_parse_regulators(pdata);
1813	if (ret)
1814		return dev_err_probe(dev, ret, "failed to parse regulators\n");
1815
1816	pdata->refclk = devm_clk_get_optional(dev, "refclk");
1817	if (IS_ERR(pdata->refclk))
1818		return dev_err_probe(dev, PTR_ERR(pdata->refclk),
1819				     "failed to get reference clock\n");
1820
1821	pm_runtime_enable(dev);
1822	pm_runtime_set_autosuspend_delay(pdata->dev, 500);
1823	pm_runtime_use_autosuspend(pdata->dev);
1824	ret = devm_add_action_or_reset(dev, ti_sn65dsi86_runtime_disable, dev);
1825	if (ret)
1826		return ret;
1827
1828	ti_sn65dsi86_debugfs_init(pdata);
1829
1830	/*
1831	 * Break ourselves up into a collection of aux devices. The only real
1832	 * motiviation here is to solve the chicken-and-egg problem of probe
1833	 * ordering. The bridge wants the panel to be there when it probes.
1834	 * The panel wants its HPD GPIO (provided by sn65dsi86 on some boards)
1835	 * when it probes. The panel and maybe backlight might want the DDC
1836	 * bus or the pwm_chip. Having sub-devices allows the some sub devices
1837	 * to finish probing even if others return -EPROBE_DEFER and gets us
1838	 * around the problems.
1839	 */
1840
1841	if (IS_ENABLED(CONFIG_OF_GPIO)) {
1842		ret = ti_sn65dsi86_add_aux_device(pdata, &pdata->gpio_aux, "gpio");
1843		if (ret)
1844			return ret;
1845	}
1846
1847	if (IS_ENABLED(CONFIG_PWM)) {
1848		ret = ti_sn65dsi86_add_aux_device(pdata, &pdata->pwm_aux, "pwm");
1849		if (ret)
1850			return ret;
1851	}
1852
1853	/*
1854	 * NOTE: At the end of the AUX channel probe we'll add the aux device
1855	 * for the bridge. This is because the bridge can't be used until the
1856	 * AUX channel is there and this is a very simple solution to the
1857	 * dependency problem.
1858	 */
1859	return ti_sn65dsi86_add_aux_device(pdata, &pdata->aux_aux, "aux");
1860}
1861
1862static struct i2c_device_id ti_sn65dsi86_id[] = {
1863	{ "ti,sn65dsi86", 0},
1864	{},
1865};
1866MODULE_DEVICE_TABLE(i2c, ti_sn65dsi86_id);
1867
1868static const struct of_device_id ti_sn65dsi86_match_table[] = {
1869	{.compatible = "ti,sn65dsi86"},
1870	{},
1871};
1872MODULE_DEVICE_TABLE(of, ti_sn65dsi86_match_table);
1873
1874static struct i2c_driver ti_sn65dsi86_driver = {
1875	.driver = {
1876		.name = "ti_sn65dsi86",
1877		.of_match_table = ti_sn65dsi86_match_table,
1878		.pm = &ti_sn65dsi86_pm_ops,
1879	},
1880	.probe = ti_sn65dsi86_probe,
1881	.id_table = ti_sn65dsi86_id,
1882};
1883
1884static int __init ti_sn65dsi86_init(void)
1885{
1886	int ret;
1887
1888	ret = i2c_add_driver(&ti_sn65dsi86_driver);
1889	if (ret)
1890		return ret;
1891
1892	ret = ti_sn_gpio_register();
1893	if (ret)
1894		goto err_main_was_registered;
1895
1896	ret = ti_sn_pwm_register();
1897	if (ret)
1898		goto err_gpio_was_registered;
1899
1900	ret = auxiliary_driver_register(&ti_sn_aux_driver);
1901	if (ret)
1902		goto err_pwm_was_registered;
1903
1904	ret = auxiliary_driver_register(&ti_sn_bridge_driver);
1905	if (ret)
1906		goto err_aux_was_registered;
1907
1908	return 0;
1909
1910err_aux_was_registered:
1911	auxiliary_driver_unregister(&ti_sn_aux_driver);
1912err_pwm_was_registered:
1913	ti_sn_pwm_unregister();
1914err_gpio_was_registered:
1915	ti_sn_gpio_unregister();
1916err_main_was_registered:
1917	i2c_del_driver(&ti_sn65dsi86_driver);
1918
1919	return ret;
1920}
1921module_init(ti_sn65dsi86_init);
1922
1923static void __exit ti_sn65dsi86_exit(void)
1924{
1925	auxiliary_driver_unregister(&ti_sn_bridge_driver);
1926	auxiliary_driver_unregister(&ti_sn_aux_driver);
1927	ti_sn_pwm_unregister();
1928	ti_sn_gpio_unregister();
1929	i2c_del_driver(&ti_sn65dsi86_driver);
1930}
1931module_exit(ti_sn65dsi86_exit);
1932
1933MODULE_AUTHOR("Sandeep Panda <spanda@codeaurora.org>");
1934MODULE_DESCRIPTION("sn65dsi86 DSI to eDP bridge driver");
1935MODULE_LICENSE("GPL v2");
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