Contributors: 15
Author Tokens Token Proportion Commits Commit Proportion
Bhawanpreet Lakha 1240 48.12% 2 8.70%
David Francis 454 17.62% 3 13.04%
abdoulaye berthe 445 17.27% 3 13.04%
Thomas Lim 203 7.88% 1 4.35%
Chiawen Huang 63 2.44% 1 4.35%
George Shen 49 1.90% 1 4.35%
Xiaodong Yan 43 1.67% 1 4.35%
Martin Leung 25 0.97% 1 4.35%
Anthony Koo 18 0.70% 2 8.70%
Yongqiang Sun 18 0.70% 2 8.70%
Sam Ravnborg 6 0.23% 2 8.70%
Aric Cyr 6 0.23% 1 4.35%
Wenjing Liu 4 0.16% 1 4.35%
Joe Perches 2 0.08% 1 4.35%
John Barberiz 1 0.04% 1 4.35%
Total 2577 23


/*
 * Copyright 2012-15 Advanced Micro Devices, Inc.
 *
 * Permission is hereby granted, free of charge, to any person obtaining a
 * copy of this software and associated documentation files (the "Software"),
 * to deal in the Software without restriction, including without limitation
 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
 * and/or sell copies of the Software, and to permit persons to whom the
 * Software is furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in
 * all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
 * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
 * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
 * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
 * OTHER DEALINGS IN THE SOFTWARE.
 *
 * Authors: AMD
 *
 */

#include <linux/delay.h>
#include <linux/slab.h>

#include "dm_services.h"
#include "core_types.h"
#include "dce_aux.h"
#include "dce/dce_11_0_sh_mask.h"
#include "dm_event_log.h"

#define CTX \
	aux110->base.ctx
#define REG(reg_name)\
	(aux110->regs->reg_name)

#define DC_LOGGER \
	engine->ctx->logger

#include "reg_helper.h"

#undef FN
#define FN(reg_name, field_name) \
	aux110->shift->field_name, aux110->mask->field_name

#define FROM_AUX_ENGINE(ptr) \
	container_of((ptr), struct aux_engine_dce110, base)

#define FROM_ENGINE(ptr) \
	FROM_AUX_ENGINE(container_of((ptr), struct dce_aux, base))

#define FROM_AUX_ENGINE_ENGINE(ptr) \
	container_of((ptr), struct dce_aux, base)
enum {
	AUX_INVALID_REPLY_RETRY_COUNTER = 1,
	AUX_TIMED_OUT_RETRY_COUNTER = 2,
	AUX_DEFER_RETRY_COUNTER = 6
};

#define TIME_OUT_INCREMENT        1016
#define TIME_OUT_MULTIPLIER_8     8
#define TIME_OUT_MULTIPLIER_16    16
#define TIME_OUT_MULTIPLIER_32    32
#define TIME_OUT_MULTIPLIER_64    64
#define MAX_TIMEOUT_LENGTH        127
#define DEFAULT_AUX_ENGINE_MULT   0
#define DEFAULT_AUX_ENGINE_LENGTH 69

static void release_engine(
	struct dce_aux *engine)
{
	struct aux_engine_dce110 *aux110 = FROM_AUX_ENGINE(engine);

	dal_ddc_close(engine->ddc);

	engine->ddc = NULL;

	REG_UPDATE(AUX_ARB_CONTROL, AUX_SW_DONE_USING_AUX_REG, 1);
}

#define SW_CAN_ACCESS_AUX 1
#define DMCU_CAN_ACCESS_AUX 2

static bool is_engine_available(
	struct dce_aux *engine)
{
	struct aux_engine_dce110 *aux110 = FROM_AUX_ENGINE(engine);

	uint32_t value = REG_READ(AUX_ARB_CONTROL);
	uint32_t field = get_reg_field_value(
			value,
			AUX_ARB_CONTROL,
			AUX_REG_RW_CNTL_STATUS);

	return (field != DMCU_CAN_ACCESS_AUX);
}
static bool acquire_engine(
	struct dce_aux *engine)
{
	struct aux_engine_dce110 *aux110 = FROM_AUX_ENGINE(engine);

	uint32_t value = REG_READ(AUX_ARB_CONTROL);
	uint32_t field = get_reg_field_value(
			value,
			AUX_ARB_CONTROL,
			AUX_REG_RW_CNTL_STATUS);
	if (field == DMCU_CAN_ACCESS_AUX)
		return false;
	/* enable AUX before request SW to access AUX */
	value = REG_READ(AUX_CONTROL);
	field = get_reg_field_value(value,
				AUX_CONTROL,
				AUX_EN);

	if (field == 0) {
		set_reg_field_value(
				value,
				1,
				AUX_CONTROL,
				AUX_EN);

		if (REG(AUX_RESET_MASK)) {
			/*DP_AUX block as part of the enable sequence*/
			set_reg_field_value(
				value,
				1,
				AUX_CONTROL,
				AUX_RESET);
		}

		REG_WRITE(AUX_CONTROL, value);

		if (REG(AUX_RESET_MASK)) {
			/*poll HW to make sure reset it done*/

			REG_WAIT(AUX_CONTROL, AUX_RESET_DONE, 1,
					1, 11);

			set_reg_field_value(
				value,
				0,
				AUX_CONTROL,
				AUX_RESET);

			REG_WRITE(AUX_CONTROL, value);

			REG_WAIT(AUX_CONTROL, AUX_RESET_DONE, 0,
					1, 11);
		}
	} /*if (field)*/

	/* request SW to access AUX */
	REG_UPDATE(AUX_ARB_CONTROL, AUX_SW_USE_AUX_REG_REQ, 1);

	value = REG_READ(AUX_ARB_CONTROL);
	field = get_reg_field_value(
			value,
			AUX_ARB_CONTROL,
			AUX_REG_RW_CNTL_STATUS);

	return (field == SW_CAN_ACCESS_AUX);
}

#define COMPOSE_AUX_SW_DATA_16_20(command, address) \
	((command) | ((0xF0000 & (address)) >> 16))

#define COMPOSE_AUX_SW_DATA_8_15(address) \
	((0xFF00 & (address)) >> 8)

#define COMPOSE_AUX_SW_DATA_0_7(address) \
	(0xFF & (address))

static void submit_channel_request(
	struct dce_aux *engine,
	struct aux_request_transaction_data *request)
{
	struct aux_engine_dce110 *aux110 = FROM_AUX_ENGINE(engine);
	uint32_t value;
	uint32_t length;

	bool is_write =
		((request->type == AUX_TRANSACTION_TYPE_DP) &&
		 (request->action == I2CAUX_TRANSACTION_ACTION_DP_WRITE)) ||
		((request->type == AUX_TRANSACTION_TYPE_I2C) &&
		((request->action == I2CAUX_TRANSACTION_ACTION_I2C_WRITE) ||
		 (request->action == I2CAUX_TRANSACTION_ACTION_I2C_WRITE_MOT)));
	if (REG(AUXN_IMPCAL)) {
		/* clear_aux_error */
		REG_UPDATE_SEQ_2(AUXN_IMPCAL,
				AUXN_CALOUT_ERROR_AK, 1,
				AUXN_CALOUT_ERROR_AK, 0);

		REG_UPDATE_SEQ_2(AUXP_IMPCAL,
				AUXP_CALOUT_ERROR_AK, 1,
				AUXP_CALOUT_ERROR_AK, 0);

		/* force_default_calibrate */
		REG_UPDATE_SEQ_2(AUXN_IMPCAL,
				AUXN_IMPCAL_ENABLE, 1,
				AUXN_IMPCAL_OVERRIDE_ENABLE, 0);

		/* bug? why AUXN update EN and OVERRIDE_EN 1 by 1 while AUX P toggles OVERRIDE? */

		REG_UPDATE_SEQ_2(AUXP_IMPCAL,
				AUXP_IMPCAL_OVERRIDE_ENABLE, 1,
				AUXP_IMPCAL_OVERRIDE_ENABLE, 0);
	}

	REG_UPDATE(AUX_INTERRUPT_CONTROL, AUX_SW_DONE_ACK, 1);

	REG_WAIT(AUX_SW_STATUS, AUX_SW_DONE, 0,
				10, aux110->polling_timeout_period/10);

	/* set the delay and the number of bytes to write */

	/* The length include
	 * the 4 bit header and the 20 bit address
	 * (that is 3 byte).
	 * If the requested length is non zero this means
	 * an addition byte specifying the length is required.
	 */

	length = request->length ? 4 : 3;
	if (is_write)
		length += request->length;

	REG_UPDATE_2(AUX_SW_CONTROL,
			AUX_SW_START_DELAY, request->delay,
			AUX_SW_WR_BYTES, length);

	/* program action and address and payload data (if 'is_write') */
	value = REG_UPDATE_4(AUX_SW_DATA,
			AUX_SW_INDEX, 0,
			AUX_SW_DATA_RW, 0,
			AUX_SW_AUTOINCREMENT_DISABLE, 1,
			AUX_SW_DATA, COMPOSE_AUX_SW_DATA_16_20(request->action, request->address));

	value = REG_SET_2(AUX_SW_DATA, value,
			AUX_SW_AUTOINCREMENT_DISABLE, 0,
			AUX_SW_DATA, COMPOSE_AUX_SW_DATA_8_15(request->address));

	value = REG_SET(AUX_SW_DATA, value,
			AUX_SW_DATA, COMPOSE_AUX_SW_DATA_0_7(request->address));

	if (request->length) {
		value = REG_SET(AUX_SW_DATA, value,
				AUX_SW_DATA, request->length - 1);
	}

	if (is_write) {
		/* Load the HW buffer with the Data to be sent.
		 * This is relevant for write operation.
		 * For read, the data recived data will be
		 * processed in process_channel_reply().
		 */
		uint32_t i = 0;

		while (i < request->length) {
			value = REG_SET(AUX_SW_DATA, value,
					AUX_SW_DATA, request->data[i]);

			++i;
		}
	}

	REG_UPDATE(AUX_SW_CONTROL, AUX_SW_GO, 1);
	EVENT_LOG_AUX_REQ(engine->ddc->pin_data->en, EVENT_LOG_AUX_ORIGIN_NATIVE,
					request->action, request->address, request->length, request->data);
}

static int read_channel_reply(struct dce_aux *engine, uint32_t size,
			      uint8_t *buffer, uint8_t *reply_result,
			      uint32_t *sw_status)
{
	struct aux_engine_dce110 *aux110 = FROM_AUX_ENGINE(engine);
	uint32_t bytes_replied;
	uint32_t reply_result_32;

	*sw_status = REG_GET(AUX_SW_STATUS, AUX_SW_REPLY_BYTE_COUNT,
			     &bytes_replied);

	/* In case HPD is LOW, exit AUX transaction */
	if ((*sw_status & AUX_SW_STATUS__AUX_SW_HPD_DISCON_MASK))
		return -1;

	/* Need at least the status byte */
	if (!bytes_replied)
		return -1;

	REG_UPDATE_SEQ_3(AUX_SW_DATA,
			  AUX_SW_INDEX, 0,
			  AUX_SW_AUTOINCREMENT_DISABLE, 1,
			  AUX_SW_DATA_RW, 1);

	REG_GET(AUX_SW_DATA, AUX_SW_DATA, &reply_result_32);
	reply_result_32 = reply_result_32 >> 4;
	if (reply_result != NULL)
		*reply_result = (uint8_t)reply_result_32;

	if (reply_result_32 == 0) { /* ACK */
		uint32_t i = 0;

		/* First byte was already used to get the command status */
		--bytes_replied;

		/* Do not overflow buffer */
		if (bytes_replied > size)
			return -1;

		while (i < bytes_replied) {
			uint32_t aux_sw_data_val;

			REG_GET(AUX_SW_DATA, AUX_SW_DATA, &aux_sw_data_val);
			buffer[i] = aux_sw_data_val;
			++i;
		}

		return i;
	}

	return 0;
}

static enum aux_channel_operation_result get_channel_status(
	struct dce_aux *engine,
	uint8_t *returned_bytes)
{
	struct aux_engine_dce110 *aux110 = FROM_AUX_ENGINE(engine);

	uint32_t value;

	if (returned_bytes == NULL) {
		/*caller pass NULL pointer*/
		ASSERT_CRITICAL(false);
		return AUX_CHANNEL_OPERATION_FAILED_REASON_UNKNOWN;
	}
	*returned_bytes = 0;

	/* poll to make sure that SW_DONE is asserted */
	REG_WAIT(AUX_SW_STATUS, AUX_SW_DONE, 1,
				10, aux110->polling_timeout_period/10);

	value = REG_READ(AUX_SW_STATUS);
	/* in case HPD is LOW, exit AUX transaction */
	if ((value & AUX_SW_STATUS__AUX_SW_HPD_DISCON_MASK))
		return AUX_CHANNEL_OPERATION_FAILED_HPD_DISCON;

	/* Note that the following bits are set in 'status.bits'
	 * during CTS 4.2.1.2 (FW 3.3.1):
	 * AUX_SW_RX_MIN_COUNT_VIOL, AUX_SW_RX_INVALID_STOP,
	 * AUX_SW_RX_RECV_NO_DET, AUX_SW_RX_RECV_INVALID_H.
	 *
	 * AUX_SW_RX_MIN_COUNT_VIOL is an internal,
	 * HW debugging bit and should be ignored.
	 */
	if (value & AUX_SW_STATUS__AUX_SW_DONE_MASK) {
		if ((value & AUX_SW_STATUS__AUX_SW_RX_TIMEOUT_STATE_MASK) ||
			(value & AUX_SW_STATUS__AUX_SW_RX_TIMEOUT_MASK))
			return AUX_CHANNEL_OPERATION_FAILED_TIMEOUT;

		else if ((value & AUX_SW_STATUS__AUX_SW_RX_INVALID_STOP_MASK) ||
			(value & AUX_SW_STATUS__AUX_SW_RX_RECV_NO_DET_MASK) ||
			(value &
				AUX_SW_STATUS__AUX_SW_RX_RECV_INVALID_H_MASK) ||
			(value & AUX_SW_STATUS__AUX_SW_RX_RECV_INVALID_L_MASK))
			return AUX_CHANNEL_OPERATION_FAILED_INVALID_REPLY;

		*returned_bytes = get_reg_field_value(value,
				AUX_SW_STATUS,
				AUX_SW_REPLY_BYTE_COUNT);

		if (*returned_bytes == 0)
			return
			AUX_CHANNEL_OPERATION_FAILED_INVALID_REPLY;
		else {
			*returned_bytes -= 1;
			return AUX_CHANNEL_OPERATION_SUCCEEDED;
		}
	} else {
		/*time_elapsed >= aux_engine->timeout_period
		 *  AUX_SW_STATUS__AUX_SW_HPD_DISCON = at this point
		 */
		ASSERT_CRITICAL(false);
		return AUX_CHANNEL_OPERATION_FAILED_TIMEOUT;
	}
}

enum i2caux_engine_type get_engine_type(
		const struct dce_aux *engine)
{
	return I2CAUX_ENGINE_TYPE_AUX;
}

static bool acquire(
	struct dce_aux *engine,
	struct ddc *ddc)
{
	enum gpio_result result;

	if ((engine == NULL) || !is_engine_available(engine))
		return false;

	result = dal_ddc_open(ddc, GPIO_MODE_HARDWARE,
		GPIO_DDC_CONFIG_TYPE_MODE_AUX);

	if (result != GPIO_RESULT_OK)
		return false;

	if (!acquire_engine(engine)) {
		dal_ddc_close(ddc);
		return false;
	}

	engine->ddc = ddc;

	return true;
}

void dce110_engine_destroy(struct dce_aux **engine)
{

	struct aux_engine_dce110 *engine110 = FROM_AUX_ENGINE(*engine);

	kfree(engine110);
	*engine = NULL;

}

static uint32_t dce_aux_configure_timeout(struct ddc_service *ddc,
		uint32_t timeout_in_us)
{
	uint32_t multiplier = 0;
	uint32_t length = 0;
	uint32_t prev_length = 0;
	uint32_t prev_mult = 0;
	uint32_t prev_timeout_val = 0;
	struct ddc *ddc_pin = ddc->ddc_pin;
	struct dce_aux *aux_engine = ddc->ctx->dc->res_pool->engines[ddc_pin->pin_data->en];
	struct aux_engine_dce110 *aux110 = FROM_AUX_ENGINE(aux_engine);

	/* 1-Update polling timeout period */
	aux110->polling_timeout_period = timeout_in_us * SW_AUX_TIMEOUT_PERIOD_MULTIPLIER;

	/* 2-Update aux timeout period length and multiplier */
	if (timeout_in_us == 0) {
		multiplier = DEFAULT_AUX_ENGINE_MULT;
		length = DEFAULT_AUX_ENGINE_LENGTH;
	} else if (timeout_in_us <= TIME_OUT_INCREMENT) {
		multiplier = 0;
		length = timeout_in_us/TIME_OUT_MULTIPLIER_8;
		if (timeout_in_us % TIME_OUT_MULTIPLIER_8 != 0)
			length++;
	} else if (timeout_in_us <= 2 * TIME_OUT_INCREMENT) {
		multiplier = 1;
		length = timeout_in_us/TIME_OUT_MULTIPLIER_16;
		if (timeout_in_us % TIME_OUT_MULTIPLIER_16 != 0)
			length++;
	} else if (timeout_in_us <= 4 * TIME_OUT_INCREMENT) {
		multiplier = 2;
		length = timeout_in_us/TIME_OUT_MULTIPLIER_32;
		if (timeout_in_us % TIME_OUT_MULTIPLIER_32 != 0)
			length++;
	} else if (timeout_in_us > 4 * TIME_OUT_INCREMENT) {
		multiplier = 3;
		length = timeout_in_us/TIME_OUT_MULTIPLIER_64;
		if (timeout_in_us % TIME_OUT_MULTIPLIER_64 != 0)
			length++;
	}

	length = (length < MAX_TIMEOUT_LENGTH) ? length : MAX_TIMEOUT_LENGTH;

	REG_GET_2(AUX_DPHY_RX_CONTROL1, AUX_RX_TIMEOUT_LEN, &prev_length, AUX_RX_TIMEOUT_LEN_MUL, &prev_mult);

	switch (prev_mult) {
	case 0:
		prev_timeout_val = prev_length * TIME_OUT_MULTIPLIER_8;
		break;
	case 1:
		prev_timeout_val = prev_length * TIME_OUT_MULTIPLIER_16;
		break;
	case 2:
		prev_timeout_val = prev_length * TIME_OUT_MULTIPLIER_32;
		break;
	case 3:
		prev_timeout_val = prev_length * TIME_OUT_MULTIPLIER_64;
		break;
	default:
		prev_timeout_val = DEFAULT_AUX_ENGINE_LENGTH * TIME_OUT_MULTIPLIER_8;
		break;
	}

	REG_UPDATE_SEQ_2(AUX_DPHY_RX_CONTROL1, AUX_RX_TIMEOUT_LEN, length, AUX_RX_TIMEOUT_LEN_MUL, multiplier);

	return prev_timeout_val;
}

static struct dce_aux_funcs aux_functions = {
	.configure_timeout = NULL,
	.destroy = NULL,
};

struct dce_aux *dce110_aux_engine_construct(struct aux_engine_dce110 *aux_engine110,
		struct dc_context *ctx,
		uint32_t inst,
		uint32_t timeout_period,
		const struct dce110_aux_registers *regs,
		const struct dce110_aux_registers_mask *mask,
		const struct dce110_aux_registers_shift *shift,
		bool is_ext_aux_timeout_configurable)
{
	aux_engine110->base.ddc = NULL;
	aux_engine110->base.ctx = ctx;
	aux_engine110->base.delay = 0;
	aux_engine110->base.max_defer_write_retry = 0;
	aux_engine110->base.inst = inst;
	aux_engine110->polling_timeout_period = timeout_period;
	aux_engine110->regs = regs;

	aux_engine110->mask = mask;
	aux_engine110->shift = shift;
	aux_engine110->base.funcs = &aux_functions;
	if (is_ext_aux_timeout_configurable)
		aux_engine110->base.funcs->configure_timeout = &dce_aux_configure_timeout;

	return &aux_engine110->base;
}

static enum i2caux_transaction_action i2caux_action_from_payload(struct aux_payload *payload)
{
	if (payload->i2c_over_aux) {
		if (payload->write) {
			if (payload->mot)
				return I2CAUX_TRANSACTION_ACTION_I2C_WRITE_MOT;
			return I2CAUX_TRANSACTION_ACTION_I2C_WRITE;
		}
		if (payload->mot)
			return I2CAUX_TRANSACTION_ACTION_I2C_READ_MOT;
		return I2CAUX_TRANSACTION_ACTION_I2C_READ;
	}
	if (payload->write)
		return I2CAUX_TRANSACTION_ACTION_DP_WRITE;
	return I2CAUX_TRANSACTION_ACTION_DP_READ;
}

int dce_aux_transfer_raw(struct ddc_service *ddc,
		struct aux_payload *payload,
		enum aux_channel_operation_result *operation_result)
{
	struct ddc *ddc_pin = ddc->ddc_pin;
	struct dce_aux *aux_engine;
	struct aux_request_transaction_data aux_req;
	struct aux_reply_transaction_data aux_rep;
	uint8_t returned_bytes = 0;
	int res = -1;
	uint32_t status;

	memset(&aux_req, 0, sizeof(aux_req));
	memset(&aux_rep, 0, sizeof(aux_rep));

	aux_engine = ddc->ctx->dc->res_pool->engines[ddc_pin->pin_data->en];
	if (!acquire(aux_engine, ddc_pin)) {
		*operation_result = AUX_CHANNEL_OPERATION_FAILED_ENGINE_ACQUIRE;
		return -1;
	}

	if (payload->i2c_over_aux)
		aux_req.type = AUX_TRANSACTION_TYPE_I2C;
	else
		aux_req.type = AUX_TRANSACTION_TYPE_DP;

	aux_req.action = i2caux_action_from_payload(payload);

	aux_req.address = payload->address;
	aux_req.delay = 0;
	aux_req.length = payload->length;
	aux_req.data = payload->data;

	submit_channel_request(aux_engine, &aux_req);
	*operation_result = get_channel_status(aux_engine, &returned_bytes);

	if (*operation_result == AUX_CHANNEL_OPERATION_SUCCEEDED) {
		int bytes_replied = 0;
		bytes_replied = read_channel_reply(aux_engine, payload->length,
					 payload->data, payload->reply,
					 &status);
		EVENT_LOG_AUX_REP(aux_engine->ddc->pin_data->en,
					EVENT_LOG_AUX_ORIGIN_NATIVE, *payload->reply,
					bytes_replied, payload->data);
		res = returned_bytes;
	} else {
		res = -1;
	}

	release_engine(aux_engine);
	return res;
}

#define AUX_MAX_RETRIES 7
#define AUX_MAX_DEFER_RETRIES 7
#define AUX_MAX_I2C_DEFER_RETRIES 7
#define AUX_MAX_INVALID_REPLY_RETRIES 2
#define AUX_MAX_TIMEOUT_RETRIES 3

bool dce_aux_transfer_with_retries(struct ddc_service *ddc,
		struct aux_payload *payload)
{
	int i, ret = 0;
	uint8_t reply;
	bool payload_reply = true;
	enum aux_channel_operation_result operation_result;
	bool retry_on_defer = false;

	int aux_ack_retries = 0,
		aux_defer_retries = 0,
		aux_i2c_defer_retries = 0,
		aux_timeout_retries = 0,
		aux_invalid_reply_retries = 0;

	if (!payload->reply) {
		payload_reply = false;
		payload->reply = &reply;
	}

	for (i = 0; i < AUX_MAX_RETRIES; i++) {
		ret = dce_aux_transfer_raw(ddc, payload, &operation_result);
		switch (operation_result) {
		case AUX_CHANNEL_OPERATION_SUCCEEDED:
			aux_timeout_retries = 0;
			aux_invalid_reply_retries = 0;

			switch (*payload->reply) {
			case AUX_TRANSACTION_REPLY_AUX_ACK:
				if (!payload->write && payload->length != ret) {
					if (++aux_ack_retries >= AUX_MAX_RETRIES)
						goto fail;
					else
						udelay(300);
				} else
					return true;
			break;

			case AUX_TRANSACTION_REPLY_AUX_DEFER:
			case AUX_TRANSACTION_REPLY_I2C_OVER_AUX_DEFER:
				retry_on_defer = true;
				fallthrough;
			case AUX_TRANSACTION_REPLY_I2C_OVER_AUX_NACK:
				if (++aux_defer_retries >= AUX_MAX_DEFER_RETRIES) {
					goto fail;
				} else {
					if ((*payload->reply == AUX_TRANSACTION_REPLY_AUX_DEFER) ||
						(*payload->reply == AUX_TRANSACTION_REPLY_I2C_OVER_AUX_DEFER)) {
						if (payload->defer_delay > 0)
							msleep(payload->defer_delay);
					}
				}
				break;

			case AUX_TRANSACTION_REPLY_I2C_DEFER:
				aux_defer_retries = 0;
				if (++aux_i2c_defer_retries >= AUX_MAX_I2C_DEFER_RETRIES)
					goto fail;
				break;

			case AUX_TRANSACTION_REPLY_AUX_NACK:
			case AUX_TRANSACTION_REPLY_HPD_DISCON:
			default:
				goto fail;
			}
			break;

		case AUX_CHANNEL_OPERATION_FAILED_INVALID_REPLY:
			if (++aux_invalid_reply_retries >= AUX_MAX_INVALID_REPLY_RETRIES)
				goto fail;
			else
				udelay(400);
			break;

		case AUX_CHANNEL_OPERATION_FAILED_TIMEOUT:
			// Check whether a DEFER had occurred before the timeout.
			// If so, treat timeout as a DEFER.
			if (retry_on_defer) {
				if (++aux_defer_retries >= AUX_MAX_DEFER_RETRIES)
					goto fail;
				else if (payload->defer_delay > 0)
					msleep(payload->defer_delay);
			} else {
				if (++aux_timeout_retries >= AUX_MAX_TIMEOUT_RETRIES)
					goto fail;
				else {
					/*
					 * DP 1.4, 2.8.2:  AUX Transaction Response/Reply Timeouts
					 * According to the DP spec there should be 3 retries total
					 * with a 400us wait inbetween each. Hardware already waits
					 * for 550us therefore no wait is required here.
					 */
				}
			}
			break;

		case AUX_CHANNEL_OPERATION_FAILED_HPD_DISCON:
		case AUX_CHANNEL_OPERATION_FAILED_ENGINE_ACQUIRE:
		case AUX_CHANNEL_OPERATION_FAILED_REASON_UNKNOWN:
		default:
			goto fail;
		}
	}

fail:
	if (!payload_reply)
		payload->reply = NULL;
	return false;
}