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|
/*
* Copyright 2018 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 "dce_i2c.h"
#include "dce_i2c_hw.h"
#include "reg_helper.h"
#include "include/gpio_service_interface.h"
#define CTX \
dce_i2c_hw->ctx
#define REG(reg)\
dce_i2c_hw->regs->reg
#undef FN
#define FN(reg_name, field_name) \
dce_i2c_hw->shifts->field_name, dce_i2c_hw->masks->field_name
static void execute_transaction(
struct dce_i2c_hw *dce_i2c_hw)
{
REG_UPDATE_N(SETUP, 5,
FN(DC_I2C_DDC1_SETUP, DC_I2C_DDC1_DATA_DRIVE_EN), 0,
FN(DC_I2C_DDC1_SETUP, DC_I2C_DDC1_CLK_DRIVE_EN), 0,
FN(DC_I2C_DDC1_SETUP, DC_I2C_DDC1_DATA_DRIVE_SEL), 0,
FN(DC_I2C_DDC1_SETUP, DC_I2C_DDC1_INTRA_TRANSACTION_DELAY), 0,
FN(DC_I2C_DDC1_SETUP, DC_I2C_DDC1_INTRA_BYTE_DELAY), 0);
REG_UPDATE_5(DC_I2C_CONTROL,
DC_I2C_SOFT_RESET, 0,
DC_I2C_SW_STATUS_RESET, 0,
DC_I2C_SEND_RESET, 0,
DC_I2C_GO, 0,
DC_I2C_TRANSACTION_COUNT, dce_i2c_hw->transaction_count - 1);
/* start I2C transfer */
REG_UPDATE(DC_I2C_CONTROL, DC_I2C_GO, 1);
/* all transactions were executed and HW buffer became empty
* (even though it actually happens when status becomes DONE)
*/
dce_i2c_hw->transaction_count = 0;
dce_i2c_hw->buffer_used_bytes = 0;
}
static enum i2c_channel_operation_result get_channel_status(
struct dce_i2c_hw *dce_i2c_hw,
uint8_t *returned_bytes)
{
uint32_t i2c_sw_status = 0;
uint32_t value =
REG_GET(DC_I2C_SW_STATUS, DC_I2C_SW_STATUS, &i2c_sw_status);
if (i2c_sw_status == DC_I2C_STATUS__DC_I2C_STATUS_USED_BY_SW)
return I2C_CHANNEL_OPERATION_ENGINE_BUSY;
else if (value & dce_i2c_hw->masks->DC_I2C_SW_STOPPED_ON_NACK)
return I2C_CHANNEL_OPERATION_NO_RESPONSE;
else if (value & dce_i2c_hw->masks->DC_I2C_SW_TIMEOUT)
return I2C_CHANNEL_OPERATION_TIMEOUT;
else if (value & dce_i2c_hw->masks->DC_I2C_SW_ABORTED)
return I2C_CHANNEL_OPERATION_FAILED;
else if (value & dce_i2c_hw->masks->DC_I2C_SW_DONE)
return I2C_CHANNEL_OPERATION_SUCCEEDED;
/*
* this is the case when HW used for communication, I2C_SW_STATUS
* could be zero
*/
return I2C_CHANNEL_OPERATION_SUCCEEDED;
}
static uint32_t get_hw_buffer_available_size(
const struct dce_i2c_hw *dce_i2c_hw)
{
return dce_i2c_hw->buffer_size -
dce_i2c_hw->buffer_used_bytes;
}
uint32_t get_reference_clock(
struct dc_bios *bios)
{
struct dc_firmware_info info = { { 0 } };
if (bios->funcs->get_firmware_info(bios, &info) != BP_RESULT_OK)
return 0;
return info.pll_info.crystal_frequency;
}
static uint32_t get_speed(
const struct dce_i2c_hw *dce_i2c_hw)
{
uint32_t pre_scale = 0;
REG_GET(SPEED, DC_I2C_DDC1_PRESCALE, &pre_scale);
/* [anaumov] it seems following is unnecessary */
/*ASSERT(value.bits.DC_I2C_DDC1_PRESCALE);*/
return pre_scale ?
dce_i2c_hw->reference_frequency / pre_scale :
dce_i2c_hw->default_speed;
}
static void process_channel_reply(
struct dce_i2c_hw *dce_i2c_hw,
struct i2c_payload *reply)
{
uint32_t length = reply->length;
uint8_t *buffer = reply->data;
REG_SET_3(DC_I2C_DATA, 0,
DC_I2C_INDEX, dce_i2c_hw->buffer_used_write,
DC_I2C_DATA_RW, 1,
DC_I2C_INDEX_WRITE, 1);
while (length) {
/* after reading the status,
* if the I2C operation executed successfully
* (i.e. DC_I2C_STATUS_DONE = 1) then the I2C controller
* should read data bytes from I2C circular data buffer
*/
uint32_t i2c_data;
REG_GET(DC_I2C_DATA, DC_I2C_DATA, &i2c_data);
*buffer++ = i2c_data;
--length;
}
}
static bool process_transaction(
struct dce_i2c_hw *dce_i2c_hw,
struct i2c_request_transaction_data *request)
{
uint32_t length = request->length;
uint8_t *buffer = request->data;
bool last_transaction = false;
uint32_t value = 0;
last_transaction = ((dce_i2c_hw->transaction_count == 3) ||
(request->action == DCE_I2C_TRANSACTION_ACTION_I2C_WRITE) ||
(request->action & DCE_I2C_TRANSACTION_ACTION_I2C_READ));
switch (dce_i2c_hw->transaction_count) {
case 0:
REG_UPDATE_5(DC_I2C_TRANSACTION0,
DC_I2C_STOP_ON_NACK0, 1,
DC_I2C_START0, 1,
DC_I2C_RW0, 0 != (request->action & DCE_I2C_TRANSACTION_ACTION_I2C_READ),
DC_I2C_COUNT0, length,
DC_I2C_STOP0, last_transaction ? 1 : 0);
break;
case 1:
REG_UPDATE_5(DC_I2C_TRANSACTION1,
DC_I2C_STOP_ON_NACK0, 1,
DC_I2C_START0, 1,
DC_I2C_RW0, 0 != (request->action & DCE_I2C_TRANSACTION_ACTION_I2C_READ),
DC_I2C_COUNT0, length,
DC_I2C_STOP0, last_transaction ? 1 : 0);
break;
case 2:
REG_UPDATE_5(DC_I2C_TRANSACTION2,
DC_I2C_STOP_ON_NACK0, 1,
DC_I2C_START0, 1,
DC_I2C_RW0, 0 != (request->action & DCE_I2C_TRANSACTION_ACTION_I2C_READ),
DC_I2C_COUNT0, length,
DC_I2C_STOP0, last_transaction ? 1 : 0);
break;
case 3:
REG_UPDATE_5(DC_I2C_TRANSACTION3,
DC_I2C_STOP_ON_NACK0, 1,
DC_I2C_START0, 1,
DC_I2C_RW0, 0 != (request->action & DCE_I2C_TRANSACTION_ACTION_I2C_READ),
DC_I2C_COUNT0, length,
DC_I2C_STOP0, last_transaction ? 1 : 0);
break;
default:
/* TODO Warning ? */
break;
}
/* Write the I2C address and I2C data
* into the hardware circular buffer, one byte per entry.
* As an example, the 7-bit I2C slave address for CRT monitor
* for reading DDC/EDID information is 0b1010001.
* For an I2C send operation, the LSB must be programmed to 0;
* for I2C receive operation, the LSB must be programmed to 1.
*/
if (dce_i2c_hw->transaction_count == 0) {
value = REG_SET_4(DC_I2C_DATA, 0,
DC_I2C_DATA_RW, false,
DC_I2C_DATA, request->address,
DC_I2C_INDEX, 0,
DC_I2C_INDEX_WRITE, 1);
dce_i2c_hw->buffer_used_write = 0;
} else
value = REG_SET_2(DC_I2C_DATA, 0,
DC_I2C_DATA_RW, false,
DC_I2C_DATA, request->address);
dce_i2c_hw->buffer_used_write++;
if (!(request->action & DCE_I2C_TRANSACTION_ACTION_I2C_READ)) {
while (length) {
REG_SET_2(DC_I2C_DATA, value,
DC_I2C_INDEX_WRITE, 0,
DC_I2C_DATA, *buffer++);
dce_i2c_hw->buffer_used_write++;
--length;
}
}
++dce_i2c_hw->transaction_count;
dce_i2c_hw->buffer_used_bytes += length + 1;
return last_transaction;
}
static inline void reset_hw_engine(struct dce_i2c_hw *dce_i2c_hw)
{
REG_UPDATE_2(DC_I2C_CONTROL,
DC_I2C_SW_STATUS_RESET, 1,
DC_I2C_SW_STATUS_RESET, 1);
}
static void set_speed(
struct dce_i2c_hw *dce_i2c_hw,
uint32_t speed)
{
if (speed) {
if (dce_i2c_hw->masks->DC_I2C_DDC1_START_STOP_TIMING_CNTL)
REG_UPDATE_N(SPEED, 3,
FN(DC_I2C_DDC1_SPEED, DC_I2C_DDC1_PRESCALE), dce_i2c_hw->reference_frequency / speed,
FN(DC_I2C_DDC1_SPEED, DC_I2C_DDC1_THRESHOLD), 2,
FN(DC_I2C_DDC1_SPEED, DC_I2C_DDC1_START_STOP_TIMING_CNTL), speed > 50 ? 2:1);
else
REG_UPDATE_N(SPEED, 2,
FN(DC_I2C_DDC1_SPEED, DC_I2C_DDC1_PRESCALE), dce_i2c_hw->reference_frequency / speed,
FN(DC_I2C_DDC1_SPEED, DC_I2C_DDC1_THRESHOLD), 2);
}
}
static bool setup_engine(
struct dce_i2c_hw *dce_i2c_hw)
{
uint32_t i2c_setup_limit = I2C_SETUP_TIME_LIMIT_DCE;
if (dce_i2c_hw->setup_limit != 0)
i2c_setup_limit = dce_i2c_hw->setup_limit;
/* Program pin select */
REG_UPDATE_6(DC_I2C_CONTROL,
DC_I2C_GO, 0,
DC_I2C_SOFT_RESET, 0,
DC_I2C_SEND_RESET, 0,
DC_I2C_SW_STATUS_RESET, 1,
DC_I2C_TRANSACTION_COUNT, 0,
DC_I2C_DDC_SELECT, dce_i2c_hw->engine_id);
/* Program time limit */
if (dce_i2c_hw->send_reset_length == 0) {
/*pre-dcn*/
REG_UPDATE_N(SETUP, 2,
FN(DC_I2C_DDC1_SETUP, DC_I2C_DDC1_TIME_LIMIT), i2c_setup_limit,
FN(DC_I2C_DDC1_SETUP, DC_I2C_DDC1_ENABLE), 1);
}
/* Program HW priority
* set to High - interrupt software I2C at any time
* Enable restart of SW I2C that was interrupted by HW
* disable queuing of software while I2C is in use by HW
*/
REG_UPDATE_2(DC_I2C_ARBITRATION,
DC_I2C_NO_QUEUED_SW_GO, 0,
DC_I2C_SW_PRIORITY, DC_I2C_ARBITRATION__DC_I2C_SW_PRIORITY_NORMAL);
return true;
}
static bool is_hw_busy(struct dce_i2c_hw *dce_i2c_hw)
{
uint32_t i2c_sw_status = 0;
REG_GET(DC_I2C_SW_STATUS, DC_I2C_SW_STATUS, &i2c_sw_status);
if (i2c_sw_status == DC_I2C_STATUS__DC_I2C_STATUS_IDLE)
return false;
reset_hw_engine(dce_i2c_hw);
REG_GET(DC_I2C_SW_STATUS, DC_I2C_SW_STATUS, &i2c_sw_status);
return i2c_sw_status != DC_I2C_STATUS__DC_I2C_STATUS_IDLE;
}
static void release_engine(
struct dce_i2c_hw *dce_i2c_hw)
{
bool safe_to_reset;
/* Restore original HW engine speed */
set_speed(dce_i2c_hw, dce_i2c_hw->original_speed);
/* Release I2C */
REG_UPDATE(DC_I2C_ARBITRATION, DC_I2C_SW_DONE_USING_I2C_REG, 1);
/* Reset HW engine */
{
uint32_t i2c_sw_status = 0;
REG_GET(DC_I2C_SW_STATUS, DC_I2C_SW_STATUS, &i2c_sw_status);
/* if used by SW, safe to reset */
safe_to_reset = (i2c_sw_status == 1);
}
if (safe_to_reset)
REG_UPDATE_2(DC_I2C_CONTROL,
DC_I2C_SOFT_RESET, 1,
DC_I2C_SW_STATUS_RESET, 1);
else
REG_UPDATE(DC_I2C_CONTROL, DC_I2C_SW_STATUS_RESET, 1);
/* HW I2c engine - clock gating feature */
if (!dce_i2c_hw->engine_keep_power_up_count)
REG_UPDATE_N(SETUP, 1, FN(SETUP, DC_I2C_DDC1_ENABLE), 0);
}
struct dce_i2c_hw *acquire_i2c_hw_engine(
struct resource_pool *pool,
struct ddc *ddc)
{
uint32_t counter = 0;
enum gpio_result result;
uint32_t current_speed;
struct dce_i2c_hw *dce_i2c_hw = NULL;
if (!ddc)
return NULL;
if (ddc->hw_info.hw_supported) {
enum gpio_ddc_line line = dal_ddc_get_line(ddc);
if (line < pool->pipe_count)
dce_i2c_hw = pool->hw_i2cs[line];
}
if (!dce_i2c_hw)
return NULL;
if (pool->i2c_hw_buffer_in_use)
return NULL;
do {
result = dal_ddc_open(ddc, GPIO_MODE_HARDWARE,
GPIO_DDC_CONFIG_TYPE_MODE_I2C);
if (result == GPIO_RESULT_OK)
break;
/* i2c_engine is busy by VBios, lets wait and retry */
udelay(10);
++counter;
} while (counter < 2);
if (result != GPIO_RESULT_OK)
return NULL;
dce_i2c_hw->ddc = ddc;
current_speed = get_speed(dce_i2c_hw);
if (current_speed)
dce_i2c_hw->original_speed = current_speed;
if (!setup_engine(dce_i2c_hw)) {
release_engine(dce_i2c_hw);
return NULL;
}
pool->i2c_hw_buffer_in_use = true;
return dce_i2c_hw;
}
enum i2c_channel_operation_result dce_i2c_hw_engine_wait_on_operation_result(
struct dce_i2c_hw *dce_i2c_hw,
uint32_t timeout,
enum i2c_channel_operation_result expected_result)
{
enum i2c_channel_operation_result result;
uint32_t i = 0;
if (!timeout)
return I2C_CHANNEL_OPERATION_SUCCEEDED;
do {
result = get_channel_status(
dce_i2c_hw, NULL);
if (result != expected_result)
break;
udelay(1);
++i;
} while (i < timeout);
return result;
}
static void submit_channel_request_hw(
struct dce_i2c_hw *dce_i2c_hw,
struct i2c_request_transaction_data *request)
{
request->status = I2C_CHANNEL_OPERATION_SUCCEEDED;
if (!process_transaction(dce_i2c_hw, request))
return;
if (is_hw_busy(dce_i2c_hw)) {
request->status = I2C_CHANNEL_OPERATION_ENGINE_BUSY;
return;
}
execute_transaction(dce_i2c_hw);
}
static uint32_t get_transaction_timeout_hw(
const struct dce_i2c_hw *dce_i2c_hw,
uint32_t length)
{
uint32_t speed = get_speed(dce_i2c_hw);
uint32_t period_timeout;
uint32_t num_of_clock_stretches;
if (!speed)
return 0;
period_timeout = (1000 * TRANSACTION_TIMEOUT_IN_I2C_CLOCKS) / speed;
num_of_clock_stretches = 1 + (length << 3) + 1;
num_of_clock_stretches +=
(dce_i2c_hw->buffer_used_bytes << 3) +
(dce_i2c_hw->transaction_count << 1);
return period_timeout * num_of_clock_stretches;
}
bool dce_i2c_hw_engine_submit_payload(
struct dce_i2c_hw *dce_i2c_hw,
struct i2c_payload *payload,
bool middle_of_transaction)
{
struct i2c_request_transaction_data request;
uint32_t transaction_timeout;
enum i2c_channel_operation_result operation_result;
bool result = false;
/* We need following:
* transaction length will not exceed
* the number of free bytes in HW buffer (minus one for address)
*/
if (payload->length >=
get_hw_buffer_available_size(dce_i2c_hw)) {
return false;
}
if (!payload->write)
request.action = middle_of_transaction ?
DCE_I2C_TRANSACTION_ACTION_I2C_READ_MOT :
DCE_I2C_TRANSACTION_ACTION_I2C_READ;
else
request.action = middle_of_transaction ?
DCE_I2C_TRANSACTION_ACTION_I2C_WRITE_MOT :
DCE_I2C_TRANSACTION_ACTION_I2C_WRITE;
request.address = (uint8_t) ((payload->address << 1) | !payload->write);
request.length = payload->length;
request.data = payload->data;
/* obtain timeout value before submitting request */
transaction_timeout = get_transaction_timeout_hw(
dce_i2c_hw, payload->length + 1);
submit_channel_request_hw(
dce_i2c_hw, &request);
if ((request.status == I2C_CHANNEL_OPERATION_FAILED) ||
(request.status == I2C_CHANNEL_OPERATION_ENGINE_BUSY))
return false;
/* wait until transaction proceed */
operation_result = dce_i2c_hw_engine_wait_on_operation_result(
dce_i2c_hw,
transaction_timeout,
I2C_CHANNEL_OPERATION_ENGINE_BUSY);
/* update transaction status */
if (operation_result == I2C_CHANNEL_OPERATION_SUCCEEDED)
result = true;
if (result && (!payload->write))
process_channel_reply(dce_i2c_hw, payload);
return result;
}
bool dce_i2c_submit_command_hw(
struct resource_pool *pool,
struct ddc *ddc,
struct i2c_command *cmd,
struct dce_i2c_hw *dce_i2c_hw)
{
uint8_t index_of_payload = 0;
bool result;
set_speed(dce_i2c_hw, cmd->speed);
result = true;
while (index_of_payload < cmd->number_of_payloads) {
bool mot = (index_of_payload != cmd->number_of_payloads - 1);
struct i2c_payload *payload = cmd->payloads + index_of_payload;
if (!dce_i2c_hw_engine_submit_payload(
dce_i2c_hw, payload, mot)) {
result = false;
break;
}
++index_of_payload;
}
pool->i2c_hw_buffer_in_use = false;
release_engine(dce_i2c_hw);
dal_ddc_close(dce_i2c_hw->ddc);
dce_i2c_hw->ddc = NULL;
return result;
}
void dce_i2c_hw_construct(
struct dce_i2c_hw *dce_i2c_hw,
struct dc_context *ctx,
uint32_t engine_id,
const struct dce_i2c_registers *regs,
const struct dce_i2c_shift *shifts,
const struct dce_i2c_mask *masks)
{
dce_i2c_hw->ctx = ctx;
dce_i2c_hw->engine_id = engine_id;
dce_i2c_hw->reference_frequency = get_reference_clock(ctx->dc_bios) >> 1;
dce_i2c_hw->regs = regs;
dce_i2c_hw->shifts = shifts;
dce_i2c_hw->masks = masks;
dce_i2c_hw->buffer_used_bytes = 0;
dce_i2c_hw->transaction_count = 0;
dce_i2c_hw->engine_keep_power_up_count = 1;
dce_i2c_hw->original_speed = DEFAULT_I2C_HW_SPEED;
dce_i2c_hw->default_speed = DEFAULT_I2C_HW_SPEED;
dce_i2c_hw->send_reset_length = 0;
dce_i2c_hw->setup_limit = I2C_SETUP_TIME_LIMIT_DCE;
dce_i2c_hw->buffer_size = I2C_HW_BUFFER_SIZE_DCE;
}
void dce100_i2c_hw_construct(
struct dce_i2c_hw *dce_i2c_hw,
struct dc_context *ctx,
uint32_t engine_id,
const struct dce_i2c_registers *regs,
const struct dce_i2c_shift *shifts,
const struct dce_i2c_mask *masks)
{
uint32_t xtal_ref_div = 0;
dce_i2c_hw_construct(dce_i2c_hw,
ctx,
engine_id,
regs,
shifts,
masks);
dce_i2c_hw->buffer_size = I2C_HW_BUFFER_SIZE_DCE100;
REG_GET(MICROSECOND_TIME_BASE_DIV, XTAL_REF_DIV, &xtal_ref_div);
if (xtal_ref_div == 0)
xtal_ref_div = 2;
/*Calculating Reference Clock by divding original frequency by
* XTAL_REF_DIV.
* At upper level, uint32_t reference_frequency =
* dal_dce_i2c_get_reference_clock(as) >> 1
* which already divided by 2. So we need x2 to get original
* reference clock from ppll_info
*/
dce_i2c_hw->reference_frequency =
(dce_i2c_hw->reference_frequency * 2) / xtal_ref_div;
}
void dce112_i2c_hw_construct(
struct dce_i2c_hw *dce_i2c_hw,
struct dc_context *ctx,
uint32_t engine_id,
const struct dce_i2c_registers *regs,
const struct dce_i2c_shift *shifts,
const struct dce_i2c_mask *masks)
{
dce100_i2c_hw_construct(dce_i2c_hw,
ctx,
engine_id,
regs,
shifts,
masks);
dce_i2c_hw->default_speed = DEFAULT_I2C_HW_SPEED_100KHZ;
}
void dcn1_i2c_hw_construct(
struct dce_i2c_hw *dce_i2c_hw,
struct dc_context *ctx,
uint32_t engine_id,
const struct dce_i2c_registers *regs,
const struct dce_i2c_shift *shifts,
const struct dce_i2c_mask *masks)
{
dce112_i2c_hw_construct(dce_i2c_hw,
ctx,
engine_id,
regs,
shifts,
masks);
dce_i2c_hw->setup_limit = I2C_SETUP_TIME_LIMIT_DCN;
}
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