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linux/drivers/gpu/drm/amd/display/dc/i2caux/aux_engine.c
Chiawen Huang 6787359b14 drm/amd/display: clean code for transition event log. 
[Why]
There are same purpose transition events.

[How]
remove the redundant event log.

Signed-off-by: Chiawen Huang <chiawen.huang@amd.com>
Reviewed-by: Tony Cheng <Tony.Cheng@amd.com>
Acked-by: Bhawanpreet Lakha <Bhawanpreet.Lakha@amd.com>
Signed-off-by: Alex Deucher <alexander.deucher@amd.com>
2018-09-10 22:44:16 -05:00

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/*
* 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 "dm_services.h"
#include "dm_event_log.h"
/*
* Pre-requisites: headers required by header of this unit
*/
#include "include/i2caux_interface.h"
#include "engine.h"
/*
* Header of this unit
*/
#include "aux_engine.h"
/*
* Post-requisites: headers required by this unit
*/
#include "include/link_service_types.h"
/*
* This unit
*/
enum {
AUX_INVALID_REPLY_RETRY_COUNTER = 1,
AUX_TIMED_OUT_RETRY_COUNTER = 2,
AUX_DEFER_RETRY_COUNTER = 6
};
#define FROM_ENGINE(ptr) \
container_of((ptr), struct aux_engine, base)
#define DC_LOGGER \
engine->base.ctx->logger
enum i2caux_engine_type dal_aux_engine_get_engine_type(
const struct engine *engine)
{
return I2CAUX_ENGINE_TYPE_AUX;
}
bool dal_aux_engine_acquire(
struct engine *engine,
struct ddc *ddc)
{
struct aux_engine *aux_engine = FROM_ENGINE(engine);
enum gpio_result result;
if (aux_engine->funcs->is_engine_available) {
/*check whether SW could use the engine*/
if (!aux_engine->funcs->is_engine_available(aux_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 (!aux_engine->funcs->acquire_engine(aux_engine)) {
dal_ddc_close(ddc);
return false;
}
engine->ddc = ddc;
return true;
}
struct read_command_context {
uint8_t *buffer;
uint32_t current_read_length;
uint32_t offset;
enum i2caux_transaction_status status;
struct aux_request_transaction_data request;
struct aux_reply_transaction_data reply;
uint8_t returned_byte;
uint32_t timed_out_retry_aux;
uint32_t invalid_reply_retry_aux;
uint32_t defer_retry_aux;
uint32_t defer_retry_i2c;
uint32_t invalid_reply_retry_aux_on_ack;
bool transaction_complete;
bool operation_succeeded;
};
static void process_read_reply(
struct aux_engine *engine,
struct read_command_context *ctx)
{
engine->funcs->process_channel_reply(engine, &ctx->reply);
switch (ctx->reply.status) {
case AUX_TRANSACTION_REPLY_AUX_ACK:
ctx->defer_retry_aux = 0;
if (ctx->returned_byte > ctx->current_read_length) {
ctx->status =
I2CAUX_TRANSACTION_STATUS_FAILED_PROTOCOL_ERROR;
ctx->operation_succeeded = false;
} else if (ctx->returned_byte < ctx->current_read_length) {
ctx->current_read_length -= ctx->returned_byte;
ctx->offset += ctx->returned_byte;
++ctx->invalid_reply_retry_aux_on_ack;
if (ctx->invalid_reply_retry_aux_on_ack >
AUX_INVALID_REPLY_RETRY_COUNTER) {
ctx->status =
I2CAUX_TRANSACTION_STATUS_FAILED_PROTOCOL_ERROR;
ctx->operation_succeeded = false;
}
} else {
ctx->status = I2CAUX_TRANSACTION_STATUS_SUCCEEDED;
ctx->transaction_complete = true;
ctx->operation_succeeded = true;
}
break;
case AUX_TRANSACTION_REPLY_AUX_NACK:
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_NACK;
ctx->operation_succeeded = false;
break;
case AUX_TRANSACTION_REPLY_AUX_DEFER:
++ctx->defer_retry_aux;
if (ctx->defer_retry_aux > AUX_DEFER_RETRY_COUNTER) {
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_TIMEOUT;
ctx->operation_succeeded = false;
}
break;
case AUX_TRANSACTION_REPLY_I2C_DEFER:
ctx->defer_retry_aux = 0;
++ctx->defer_retry_i2c;
if (ctx->defer_retry_i2c > AUX_DEFER_RETRY_COUNTER) {
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_TIMEOUT;
ctx->operation_succeeded = false;
}
break;
case AUX_TRANSACTION_REPLY_HPD_DISCON:
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_HPD_DISCON;
ctx->operation_succeeded = false;
break;
default:
ctx->status = I2CAUX_TRANSACTION_STATUS_UNKNOWN;
ctx->operation_succeeded = false;
}
}
static void process_read_request(
struct aux_engine *engine,
struct read_command_context *ctx)
{
enum aux_channel_operation_result operation_result;
engine->funcs->submit_channel_request(engine, &ctx->request);
operation_result = engine->funcs->get_channel_status(
engine, &ctx->returned_byte);
switch (operation_result) {
case AUX_CHANNEL_OPERATION_SUCCEEDED:
if (ctx->returned_byte > ctx->current_read_length) {
ctx->status =
I2CAUX_TRANSACTION_STATUS_FAILED_PROTOCOL_ERROR;
ctx->operation_succeeded = false;
} else {
ctx->timed_out_retry_aux = 0;
ctx->invalid_reply_retry_aux = 0;
ctx->reply.length = ctx->returned_byte;
ctx->reply.data = ctx->buffer;
process_read_reply(engine, ctx);
}
break;
case AUX_CHANNEL_OPERATION_FAILED_INVALID_REPLY:
++ctx->invalid_reply_retry_aux;
if (ctx->invalid_reply_retry_aux >
AUX_INVALID_REPLY_RETRY_COUNTER) {
ctx->status =
I2CAUX_TRANSACTION_STATUS_FAILED_PROTOCOL_ERROR;
ctx->operation_succeeded = false;
} else
udelay(400);
break;
case AUX_CHANNEL_OPERATION_FAILED_TIMEOUT:
++ctx->timed_out_retry_aux;
if (ctx->timed_out_retry_aux > AUX_TIMED_OUT_RETRY_COUNTER) {
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_TIMEOUT;
ctx->operation_succeeded = false;
} else {
/* DP 1.2a, table 2-58:
* "S3: AUX Request CMD PENDING:
* retry 3 times, with 400usec wait on each"
* The HW timeout is set to 550usec,
* so we should not wait here */
}
break;
case AUX_CHANNEL_OPERATION_FAILED_HPD_DISCON:
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_HPD_DISCON;
ctx->operation_succeeded = false;
break;
default:
ctx->status = I2CAUX_TRANSACTION_STATUS_UNKNOWN;
ctx->operation_succeeded = false;
}
}
static bool read_command(
struct aux_engine *engine,
struct i2caux_transaction_request *request,
bool middle_of_transaction)
{
struct read_command_context ctx;
ctx.buffer = request->payload.data;
ctx.current_read_length = request->payload.length;
ctx.offset = 0;
ctx.timed_out_retry_aux = 0;
ctx.invalid_reply_retry_aux = 0;
ctx.defer_retry_aux = 0;
ctx.defer_retry_i2c = 0;
ctx.invalid_reply_retry_aux_on_ack = 0;
ctx.transaction_complete = false;
ctx.operation_succeeded = true;
if (request->payload.address_space ==
I2CAUX_TRANSACTION_ADDRESS_SPACE_DPCD) {
ctx.request.type = AUX_TRANSACTION_TYPE_DP;
ctx.request.action = I2CAUX_TRANSACTION_ACTION_DP_READ;
ctx.request.address = request->payload.address;
} else if (request->payload.address_space ==
I2CAUX_TRANSACTION_ADDRESS_SPACE_I2C) {
ctx.request.type = AUX_TRANSACTION_TYPE_I2C;
ctx.request.action = middle_of_transaction ?
I2CAUX_TRANSACTION_ACTION_I2C_READ_MOT :
I2CAUX_TRANSACTION_ACTION_I2C_READ;
ctx.request.address = request->payload.address >> 1;
} else {
/* in DAL2, there was no return in such case */
BREAK_TO_DEBUGGER();
return false;
}
ctx.request.delay = 0;
do {
memset(ctx.buffer + ctx.offset, 0, ctx.current_read_length);
ctx.request.data = ctx.buffer + ctx.offset;
ctx.request.length = ctx.current_read_length;
process_read_request(engine, &ctx);
request->status = ctx.status;
if (ctx.operation_succeeded && !ctx.transaction_complete)
if (ctx.request.type == AUX_TRANSACTION_TYPE_I2C)
msleep(engine->delay);
} while (ctx.operation_succeeded && !ctx.transaction_complete);
if (request->payload.address_space ==
I2CAUX_TRANSACTION_ADDRESS_SPACE_DPCD) {
DC_LOG_I2C_AUX("READ: addr:0x%x value:0x%x Result:%d",
request->payload.address,
request->payload.data[0],
ctx.operation_succeeded);
}
return ctx.operation_succeeded;
}
struct write_command_context {
bool mot;
uint8_t *buffer;
uint32_t current_write_length;
enum i2caux_transaction_status status;
struct aux_request_transaction_data request;
struct aux_reply_transaction_data reply;
uint8_t returned_byte;
uint32_t timed_out_retry_aux;
uint32_t invalid_reply_retry_aux;
uint32_t defer_retry_aux;
uint32_t defer_retry_i2c;
uint32_t max_defer_retry;
uint32_t ack_m_retry;
uint8_t reply_data[DEFAULT_AUX_MAX_DATA_SIZE];
bool transaction_complete;
bool operation_succeeded;
};
static void process_write_reply(
struct aux_engine *engine,
struct write_command_context *ctx)
{
engine->funcs->process_channel_reply(engine, &ctx->reply);
switch (ctx->reply.status) {
case AUX_TRANSACTION_REPLY_AUX_ACK:
ctx->operation_succeeded = true;
if (ctx->returned_byte) {
ctx->request.action = ctx->mot ?
I2CAUX_TRANSACTION_ACTION_I2C_STATUS_REQUEST_MOT :
I2CAUX_TRANSACTION_ACTION_I2C_STATUS_REQUEST;
ctx->current_write_length = 0;
++ctx->ack_m_retry;
if (ctx->ack_m_retry > AUX_DEFER_RETRY_COUNTER) {
ctx->status =
I2CAUX_TRANSACTION_STATUS_FAILED_TIMEOUT;
ctx->operation_succeeded = false;
} else
udelay(300);
} else {
ctx->status = I2CAUX_TRANSACTION_STATUS_SUCCEEDED;
ctx->defer_retry_aux = 0;
ctx->ack_m_retry = 0;
ctx->transaction_complete = true;
}
break;
case AUX_TRANSACTION_REPLY_AUX_NACK:
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_NACK;
ctx->operation_succeeded = false;
break;
case AUX_TRANSACTION_REPLY_AUX_DEFER:
++ctx->defer_retry_aux;
if (ctx->defer_retry_aux > ctx->max_defer_retry) {
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_TIMEOUT;
ctx->operation_succeeded = false;
}
break;
case AUX_TRANSACTION_REPLY_I2C_DEFER:
ctx->defer_retry_aux = 0;
ctx->current_write_length = 0;
ctx->request.action = ctx->mot ?
I2CAUX_TRANSACTION_ACTION_I2C_STATUS_REQUEST_MOT :
I2CAUX_TRANSACTION_ACTION_I2C_STATUS_REQUEST;
++ctx->defer_retry_i2c;
if (ctx->defer_retry_i2c > ctx->max_defer_retry) {
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_TIMEOUT;
ctx->operation_succeeded = false;
}
break;
case AUX_TRANSACTION_REPLY_HPD_DISCON:
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_HPD_DISCON;
ctx->operation_succeeded = false;
break;
default:
ctx->status = I2CAUX_TRANSACTION_STATUS_UNKNOWN;
ctx->operation_succeeded = false;
}
}
static void process_write_request(
struct aux_engine *engine,
struct write_command_context *ctx)
{
enum aux_channel_operation_result operation_result;
engine->funcs->submit_channel_request(engine, &ctx->request);
operation_result = engine->funcs->get_channel_status(
engine, &ctx->returned_byte);
switch (operation_result) {
case AUX_CHANNEL_OPERATION_SUCCEEDED:
ctx->timed_out_retry_aux = 0;
ctx->invalid_reply_retry_aux = 0;
ctx->reply.length = ctx->returned_byte;
ctx->reply.data = ctx->reply_data;
process_write_reply(engine, ctx);
break;
case AUX_CHANNEL_OPERATION_FAILED_INVALID_REPLY:
++ctx->invalid_reply_retry_aux;
if (ctx->invalid_reply_retry_aux >
AUX_INVALID_REPLY_RETRY_COUNTER) {
ctx->status =
I2CAUX_TRANSACTION_STATUS_FAILED_PROTOCOL_ERROR;
ctx->operation_succeeded = false;
} else
udelay(400);
break;
case AUX_CHANNEL_OPERATION_FAILED_TIMEOUT:
++ctx->timed_out_retry_aux;
if (ctx->timed_out_retry_aux > AUX_TIMED_OUT_RETRY_COUNTER) {
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_TIMEOUT;
ctx->operation_succeeded = false;
} else {
/* DP 1.2a, table 2-58:
* "S3: AUX Request CMD PENDING:
* retry 3 times, with 400usec wait on each"
* The HW timeout is set to 550usec,
* so we should not wait here */
}
break;
case AUX_CHANNEL_OPERATION_FAILED_HPD_DISCON:
ctx->status = I2CAUX_TRANSACTION_STATUS_FAILED_HPD_DISCON;
ctx->operation_succeeded = false;
break;
default:
ctx->status = I2CAUX_TRANSACTION_STATUS_UNKNOWN;
ctx->operation_succeeded = false;
}
}
static bool write_command(
struct aux_engine *engine,
struct i2caux_transaction_request *request,
bool middle_of_transaction)
{
struct write_command_context ctx;
ctx.mot = middle_of_transaction;
ctx.buffer = request->payload.data;
ctx.current_write_length = request->payload.length;
ctx.timed_out_retry_aux = 0;
ctx.invalid_reply_retry_aux = 0;
ctx.defer_retry_aux = 0;
ctx.defer_retry_i2c = 0;
ctx.ack_m_retry = 0;
ctx.transaction_complete = false;
ctx.operation_succeeded = true;
if (request->payload.address_space ==
I2CAUX_TRANSACTION_ADDRESS_SPACE_DPCD) {
ctx.request.type = AUX_TRANSACTION_TYPE_DP;
ctx.request.action = I2CAUX_TRANSACTION_ACTION_DP_WRITE;
ctx.request.address = request->payload.address;
} else if (request->payload.address_space ==
I2CAUX_TRANSACTION_ADDRESS_SPACE_I2C) {
ctx.request.type = AUX_TRANSACTION_TYPE_I2C;
ctx.request.action = middle_of_transaction ?
I2CAUX_TRANSACTION_ACTION_I2C_WRITE_MOT :
I2CAUX_TRANSACTION_ACTION_I2C_WRITE;
ctx.request.address = request->payload.address >> 1;
} else {
/* in DAL2, there was no return in such case */
BREAK_TO_DEBUGGER();
return false;
}
ctx.request.delay = 0;
ctx.max_defer_retry =
(engine->max_defer_write_retry > AUX_DEFER_RETRY_COUNTER) ?
engine->max_defer_write_retry : AUX_DEFER_RETRY_COUNTER;
do {
ctx.request.data = ctx.buffer;
ctx.request.length = ctx.current_write_length;
process_write_request(engine, &ctx);
request->status = ctx.status;
if (ctx.operation_succeeded && !ctx.transaction_complete)
if (ctx.request.type == AUX_TRANSACTION_TYPE_I2C)
msleep(engine->delay);
} while (ctx.operation_succeeded && !ctx.transaction_complete);
if (request->payload.address_space ==
I2CAUX_TRANSACTION_ADDRESS_SPACE_DPCD) {
DC_LOG_I2C_AUX("WRITE: addr:0x%x value:0x%x Result:%d",
request->payload.address,
request->payload.data[0],
ctx.operation_succeeded);
}
return ctx.operation_succeeded;
}
static bool end_of_transaction_command(
struct aux_engine *engine,
struct i2caux_transaction_request *request)
{
struct i2caux_transaction_request dummy_request;
uint8_t dummy_data;
/* [tcheng] We only need to send the stop (read with MOT = 0)
* for I2C-over-Aux, not native AUX */
if (request->payload.address_space !=
I2CAUX_TRANSACTION_ADDRESS_SPACE_I2C)
return false;
dummy_request.operation = request->operation;
dummy_request.payload.address_space = request->payload.address_space;
dummy_request.payload.address = request->payload.address;
/*
* Add a dummy byte due to some receiver quirk
* where one byte is sent along with MOT = 0.
* Ideally this should be 0.
*/
dummy_request.payload.length = 0;
dummy_request.payload.data = &dummy_data;
if (request->operation == I2CAUX_TRANSACTION_READ)
return read_command(engine, &dummy_request, false);
else
return write_command(engine, &dummy_request, false);
/* according Syed, it does not need now DoDummyMOT */
}
bool dal_aux_engine_submit_request(
struct engine *engine,
struct i2caux_transaction_request *request,
bool middle_of_transaction)
{
struct aux_engine *aux_engine = FROM_ENGINE(engine);
bool result;
bool mot_used = true;
switch (request->operation) {
case I2CAUX_TRANSACTION_READ:
result = read_command(aux_engine, request, mot_used);
break;
case I2CAUX_TRANSACTION_WRITE:
result = write_command(aux_engine, request, mot_used);
break;
default:
result = false;
}
/* [tcheng]
* need to send stop for the last transaction to free up the AUX
* if the above command fails, this would be the last transaction */
if (!middle_of_transaction || !result)
end_of_transaction_command(aux_engine, request);
/* mask AUX interrupt */
return result;
}
void dal_aux_engine_construct(
struct aux_engine *engine,
struct dc_context *ctx)
{
dal_i2caux_construct_engine(&engine->base, ctx);
engine->delay = 0;
engine->max_defer_write_retry = 0;
}
void dal_aux_engine_destruct(
struct aux_engine *engine)
{
dal_i2caux_destruct_engine(&engine->base);
}
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