u-boot/drivers/video/exynos/exynos_dp_lowlevel.c
Tom Rini 83d290c56f SPDX: Convert all of our single license tags to Linux Kernel style
When U-Boot started using SPDX tags we were among the early adopters and
there weren't a lot of other examples to borrow from.  So we picked the
area of the file that usually had a full license text and replaced it
with an appropriate SPDX-License-Identifier: entry.  Since then, the
Linux Kernel has adopted SPDX tags and they place it as the very first
line in a file (except where shebangs are used, then it's second line)
and with slightly different comment styles than us.

In part due to community overlap, in part due to better tag visibility
and in part for other minor reasons, switch over to that style.

This commit changes all instances where we have a single declared
license in the tag as both the before and after are identical in tag
contents.  There's also a few places where I found we did not have a tag
and have introduced one.

Signed-off-by: Tom Rini <trini@konsulko.com>
2018-05-07 09:34:12 -04:00

1250 lines
30 KiB
C

// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2012 Samsung Electronics
*
* Author: Donghwa Lee <dh09.lee@samsung.com>
*/
#include <config.h>
#include <common.h>
#include <linux/err.h>
#include <asm/arch/cpu.h>
#include <asm/arch/dp_info.h>
#include <asm/arch/dp.h>
#include <fdtdec.h>
#include <linux/libfdt.h>
#include "exynos_dp_lowlevel.h"
/* Declare global data pointer */
static void exynos_dp_enable_video_input(struct exynos_dp *dp_regs,
unsigned int enable)
{
unsigned int reg;
reg = readl(&dp_regs->video_ctl1);
reg &= ~VIDEO_EN_MASK;
/* enable video input */
if (enable)
reg |= VIDEO_EN_MASK;
writel(reg, &dp_regs->video_ctl1);
return;
}
void exynos_dp_enable_video_bist(struct exynos_dp *dp_regs, unsigned int enable)
{
/* enable video bist */
unsigned int reg;
reg = readl(&dp_regs->video_ctl4);
reg &= ~VIDEO_BIST_MASK;
/* enable video bist */
if (enable)
reg |= VIDEO_BIST_MASK;
writel(reg, &dp_regs->video_ctl4);
return;
}
void exynos_dp_enable_video_mute(struct exynos_dp *dp_regs, unsigned int enable)
{
unsigned int reg;
reg = readl(&dp_regs->video_ctl1);
reg &= ~(VIDEO_MUTE_MASK);
if (enable)
reg |= VIDEO_MUTE_MASK;
writel(reg, &dp_regs->video_ctl1);
return;
}
static void exynos_dp_init_analog_param(struct exynos_dp *dp_regs)
{
unsigned int reg;
/*
* Set termination
* Normal bandgap, Normal swing, Tx terminal registor 61 ohm
* 24M Phy clock, TX digital logic power is 100:1.0625V
*/
reg = SEL_BG_NEW_BANDGAP | TX_TERMINAL_CTRL_61_OHM |
SWING_A_30PER_G_NORMAL;
writel(reg, &dp_regs->analog_ctl1);
reg = SEL_24M | TX_DVDD_BIT_1_0625V;
writel(reg, &dp_regs->analog_ctl2);
/*
* Set power source for internal clk driver to 1.0625v.
* Select current reference of TX driver current to 00:Ipp/2+Ic/2.
* Set VCO range of PLL +- 0uA
*/
reg = DRIVE_DVDD_BIT_1_0625V | SEL_CURRENT_DEFAULT | VCO_BIT_000_MICRO;
writel(reg, &dp_regs->analog_ctl3);
/*
* Set AUX TX terminal resistor to 102 ohm
* Set AUX channel amplitude control
*/
reg = PD_RING_OSC | AUX_TERMINAL_CTRL_52_OHM | TX_CUR1_2X | TX_CUR_4_MA;
writel(reg, &dp_regs->pll_filter_ctl1);
/*
* PLL loop filter bandwidth
* For 2.7Gbps: 175KHz, For 1.62Gbps: 234KHz
* PLL digital power select: 1.2500V
*/
reg = CH3_AMP_0_MV | CH2_AMP_0_MV | CH1_AMP_0_MV | CH0_AMP_0_MV;
writel(reg, &dp_regs->amp_tuning_ctl);
/*
* PLL loop filter bandwidth
* For 2.7Gbps: 175KHz, For 1.62Gbps: 234KHz
* PLL digital power select: 1.1250V
*/
reg = DP_PLL_LOOP_BIT_DEFAULT | DP_PLL_REF_BIT_1_1250V;
writel(reg, &dp_regs->pll_ctl);
}
static void exynos_dp_init_interrupt(struct exynos_dp *dp_regs)
{
/* Set interrupt registers to initial states */
/*
* Disable interrupt
* INT pin assertion polarity. It must be configured
* correctly according to ICU setting.
* 1 = assert high, 0 = assert low
*/
writel(INT_POL, &dp_regs->int_ctl);
/* Clear pending registers */
writel(0xff, &dp_regs->common_int_sta1);
writel(0xff, &dp_regs->common_int_sta2);
writel(0xff, &dp_regs->common_int_sta3);
writel(0xff, &dp_regs->common_int_sta4);
writel(0xff, &dp_regs->int_sta);
/* 0:mask,1: unmask */
writel(0x00, &dp_regs->int_sta_mask1);
writel(0x00, &dp_regs->int_sta_mask2);
writel(0x00, &dp_regs->int_sta_mask3);
writel(0x00, &dp_regs->int_sta_mask4);
writel(0x00, &dp_regs->int_sta_mask);
}
void exynos_dp_reset(struct exynos_dp *dp_regs)
{
unsigned int reg_func_1;
/* dp tx sw reset */
writel(RESET_DP_TX, &dp_regs->tx_sw_reset);
exynos_dp_enable_video_input(dp_regs, DP_DISABLE);
exynos_dp_enable_video_bist(dp_regs, DP_DISABLE);
exynos_dp_enable_video_mute(dp_regs, DP_DISABLE);
/* software reset */
reg_func_1 = MASTER_VID_FUNC_EN_N | SLAVE_VID_FUNC_EN_N |
AUD_FIFO_FUNC_EN_N | AUD_FUNC_EN_N |
HDCP_FUNC_EN_N | SW_FUNC_EN_N;
writel(reg_func_1, &dp_regs->func_en1);
writel(reg_func_1, &dp_regs->func_en2);
mdelay(1);
exynos_dp_init_analog_param(dp_regs);
exynos_dp_init_interrupt(dp_regs);
return;
}
void exynos_dp_enable_sw_func(struct exynos_dp *dp_regs, unsigned int enable)
{
unsigned int reg;
reg = readl(&dp_regs->func_en1);
reg &= ~(SW_FUNC_EN_N);
if (!enable)
reg |= SW_FUNC_EN_N;
writel(reg, &dp_regs->func_en1);
return;
}
unsigned int exynos_dp_set_analog_power_down(struct exynos_dp *dp_regs,
unsigned int block, u32 enable)
{
unsigned int reg;
reg = readl(&dp_regs->phy_pd);
switch (block) {
case AUX_BLOCK:
reg &= ~(AUX_PD);
if (enable)
reg |= AUX_PD;
break;
case CH0_BLOCK:
reg &= ~(CH0_PD);
if (enable)
reg |= CH0_PD;
break;
case CH1_BLOCK:
reg &= ~(CH1_PD);
if (enable)
reg |= CH1_PD;
break;
case CH2_BLOCK:
reg &= ~(CH2_PD);
if (enable)
reg |= CH2_PD;
break;
case CH3_BLOCK:
reg &= ~(CH3_PD);
if (enable)
reg |= CH3_PD;
break;
case ANALOG_TOTAL:
reg &= ~PHY_PD;
if (enable)
reg |= PHY_PD;
break;
case POWER_ALL:
reg &= ~(PHY_PD | AUX_PD | CH0_PD | CH1_PD | CH2_PD |
CH3_PD);
if (enable)
reg |= (PHY_PD | AUX_PD | CH0_PD | CH1_PD |
CH2_PD | CH3_PD);
break;
default:
printf("DP undefined block number : %d\n", block);
return -1;
}
writel(reg, &dp_regs->phy_pd);
return 0;
}
unsigned int exynos_dp_get_pll_lock_status(struct exynos_dp *dp_regs)
{
unsigned int reg;
reg = readl(&dp_regs->debug_ctl);
if (reg & PLL_LOCK)
return PLL_LOCKED;
else
return PLL_UNLOCKED;
}
static void exynos_dp_set_pll_power(struct exynos_dp *dp_regs,
unsigned int enable)
{
unsigned int reg;
reg = readl(&dp_regs->pll_ctl);
reg &= ~(DP_PLL_PD);
if (!enable)
reg |= DP_PLL_PD;
writel(reg, &dp_regs->pll_ctl);
}
int exynos_dp_init_analog_func(struct exynos_dp *dp_regs)
{
int ret = EXYNOS_DP_SUCCESS;
unsigned int retry_cnt = 10;
unsigned int reg;
/* Power On All Analog block */
exynos_dp_set_analog_power_down(dp_regs, POWER_ALL, DP_DISABLE);
reg = PLL_LOCK_CHG;
writel(reg, &dp_regs->common_int_sta1);
reg = readl(&dp_regs->debug_ctl);
reg &= ~(F_PLL_LOCK | PLL_LOCK_CTRL);
writel(reg, &dp_regs->debug_ctl);
/* Assert DP PLL Reset */
reg = readl(&dp_regs->pll_ctl);
reg |= DP_PLL_RESET;
writel(reg, &dp_regs->pll_ctl);
mdelay(1);
/* Deassert DP PLL Reset */
reg = readl(&dp_regs->pll_ctl);
reg &= ~(DP_PLL_RESET);
writel(reg, &dp_regs->pll_ctl);
exynos_dp_set_pll_power(dp_regs, DP_ENABLE);
while (exynos_dp_get_pll_lock_status(dp_regs) == PLL_UNLOCKED) {
mdelay(1);
retry_cnt--;
if (retry_cnt == 0) {
printf("DP dp's pll lock failed : retry : %d\n",
retry_cnt);
return -EINVAL;
}
}
debug("dp's pll lock success(%d)\n", retry_cnt);
/* Enable Serdes FIFO function and Link symbol clock domain module */
reg = readl(&dp_regs->func_en2);
reg &= ~(SERDES_FIFO_FUNC_EN_N | LS_CLK_DOMAIN_FUNC_EN_N
| AUX_FUNC_EN_N);
writel(reg, &dp_regs->func_en2);
return ret;
}
void exynos_dp_init_hpd(struct exynos_dp *dp_regs)
{
unsigned int reg;
/* Clear interrupts related to Hot Plug Detect */
reg = HOTPLUG_CHG | HPD_LOST | PLUG;
writel(reg, &dp_regs->common_int_sta4);
reg = INT_HPD;
writel(reg, &dp_regs->int_sta);
reg = readl(&dp_regs->sys_ctl3);
reg &= ~(F_HPD | HPD_CTRL);
writel(reg, &dp_regs->sys_ctl3);
return;
}
static inline void exynos_dp_reset_aux(struct exynos_dp *dp_regs)
{
unsigned int reg;
/* Disable AUX channel module */
reg = readl(&dp_regs->func_en2);
reg |= AUX_FUNC_EN_N;
writel(reg, &dp_regs->func_en2);
return;
}
void exynos_dp_init_aux(struct exynos_dp *dp_regs)
{
unsigned int reg;
/* Clear interrupts related to AUX channel */
reg = RPLY_RECEIV | AUX_ERR;
writel(reg, &dp_regs->int_sta);
exynos_dp_reset_aux(dp_regs);
/* Disable AUX transaction H/W retry */
reg = AUX_BIT_PERIOD_EXPECTED_DELAY(3) | AUX_HW_RETRY_COUNT_SEL(3)|
AUX_HW_RETRY_INTERVAL_600_MICROSECONDS;
writel(reg, &dp_regs->aux_hw_retry_ctl);
/* Receive AUX Channel DEFER commands equal to DEFER_COUNT*64 */
reg = DEFER_CTRL_EN | DEFER_COUNT(1);
writel(reg, &dp_regs->aux_ch_defer_ctl);
/* Enable AUX channel module */
reg = readl(&dp_regs->func_en2);
reg &= ~AUX_FUNC_EN_N;
writel(reg, &dp_regs->func_en2);
return;
}
void exynos_dp_config_interrupt(struct exynos_dp *dp_regs)
{
unsigned int reg;
/* 0: mask, 1: unmask */
reg = COMMON_INT_MASK_1;
writel(reg, &dp_regs->common_int_mask1);
reg = COMMON_INT_MASK_2;
writel(reg, &dp_regs->common_int_mask2);
reg = COMMON_INT_MASK_3;
writel(reg, &dp_regs->common_int_mask3);
reg = COMMON_INT_MASK_4;
writel(reg, &dp_regs->common_int_mask4);
reg = INT_STA_MASK;
writel(reg, &dp_regs->int_sta_mask);
return;
}
unsigned int exynos_dp_get_plug_in_status(struct exynos_dp *dp_regs)
{
unsigned int reg;
reg = readl(&dp_regs->sys_ctl3);
if (reg & HPD_STATUS)
return 0;
return -1;
}
unsigned int exynos_dp_detect_hpd(struct exynos_dp *dp_regs)
{
int timeout_loop = DP_TIMEOUT_LOOP_COUNT;
mdelay(2);
while (exynos_dp_get_plug_in_status(dp_regs) != 0) {
if (timeout_loop == 0)
return -EINVAL;
mdelay(10);
timeout_loop--;
}
return EXYNOS_DP_SUCCESS;
}
unsigned int exynos_dp_start_aux_transaction(struct exynos_dp *dp_regs)
{
unsigned int reg;
unsigned int ret = 0;
unsigned int retry_cnt;
/* Enable AUX CH operation */
reg = readl(&dp_regs->aux_ch_ctl2);
reg |= AUX_EN;
writel(reg, &dp_regs->aux_ch_ctl2);
retry_cnt = 10;
while (retry_cnt) {
reg = readl(&dp_regs->int_sta);
if (!(reg & RPLY_RECEIV)) {
if (retry_cnt == 0) {
printf("DP Reply Timeout!!\n");
ret = -EAGAIN;
return ret;
}
mdelay(1);
retry_cnt--;
} else
break;
}
/* Clear interrupt source for AUX CH command reply */
writel(reg, &dp_regs->int_sta);
/* Clear interrupt source for AUX CH access error */
reg = readl(&dp_regs->int_sta);
if (reg & AUX_ERR) {
printf("DP Aux Access Error\n");
writel(AUX_ERR, &dp_regs->int_sta);
ret = -EAGAIN;
return ret;
}
/* Check AUX CH error access status */
reg = readl(&dp_regs->aux_ch_sta);
if ((reg & AUX_STATUS_MASK) != 0) {
debug("DP AUX CH error happens: %x\n", reg & AUX_STATUS_MASK);
ret = -EAGAIN;
return ret;
}
return EXYNOS_DP_SUCCESS;
}
unsigned int exynos_dp_write_byte_to_dpcd(struct exynos_dp *dp_regs,
unsigned int reg_addr,
unsigned char data)
{
unsigned int reg, ret;
/* Clear AUX CH data buffer */
reg = BUF_CLR;
writel(reg, &dp_regs->buffer_data_ctl);
/* Select DPCD device address */
reg = AUX_ADDR_7_0(reg_addr);
writel(reg, &dp_regs->aux_addr_7_0);
reg = AUX_ADDR_15_8(reg_addr);
writel(reg, &dp_regs->aux_addr_15_8);
reg = AUX_ADDR_19_16(reg_addr);
writel(reg, &dp_regs->aux_addr_19_16);
/* Write data buffer */
reg = (unsigned int)data;
writel(reg, &dp_regs->buf_data0);
/*
* Set DisplayPort transaction and write 1 byte
* If bit 3 is 1, DisplayPort transaction.
* If Bit 3 is 0, I2C transaction.
*/
reg = AUX_TX_COMM_DP_TRANSACTION | AUX_TX_COMM_WRITE;
writel(reg, &dp_regs->aux_ch_ctl1);
/* Start AUX transaction */
ret = exynos_dp_start_aux_transaction(dp_regs);
if (ret != EXYNOS_DP_SUCCESS) {
printf("DP Aux transaction failed\n");
return ret;
}
return ret;
}
unsigned int exynos_dp_read_byte_from_dpcd(struct exynos_dp *dp_regs,
unsigned int reg_addr,
unsigned char *data)
{
unsigned int reg;
int retval;
/* Clear AUX CH data buffer */
reg = BUF_CLR;
writel(reg, &dp_regs->buffer_data_ctl);
/* Select DPCD device address */
reg = AUX_ADDR_7_0(reg_addr);
writel(reg, &dp_regs->aux_addr_7_0);
reg = AUX_ADDR_15_8(reg_addr);
writel(reg, &dp_regs->aux_addr_15_8);
reg = AUX_ADDR_19_16(reg_addr);
writel(reg, &dp_regs->aux_addr_19_16);
/*
* Set DisplayPort transaction and read 1 byte
* If bit 3 is 1, DisplayPort transaction.
* If Bit 3 is 0, I2C transaction.
*/
reg = AUX_TX_COMM_DP_TRANSACTION | AUX_TX_COMM_READ;
writel(reg, &dp_regs->aux_ch_ctl1);
/* Start AUX transaction */
retval = exynos_dp_start_aux_transaction(dp_regs);
if (!retval)
debug("DP Aux Transaction fail!\n");
/* Read data buffer */
reg = readl(&dp_regs->buf_data0);
*data = (unsigned char)(reg & 0xff);
return retval;
}
unsigned int exynos_dp_write_bytes_to_dpcd(struct exynos_dp *dp_regs,
unsigned int reg_addr,
unsigned int count,
unsigned char data[])
{
unsigned int reg;
unsigned int start_offset;
unsigned int cur_data_count;
unsigned int cur_data_idx;
unsigned int retry_cnt;
unsigned int ret = 0;
/* Clear AUX CH data buffer */
reg = BUF_CLR;
writel(reg, &dp_regs->buffer_data_ctl);
start_offset = 0;
while (start_offset < count) {
/* Buffer size of AUX CH is 16 * 4bytes */
if ((count - start_offset) > 16)
cur_data_count = 16;
else
cur_data_count = count - start_offset;
retry_cnt = 5;
while (retry_cnt) {
/* Select DPCD device address */
reg = AUX_ADDR_7_0(reg_addr + start_offset);
writel(reg, &dp_regs->aux_addr_7_0);
reg = AUX_ADDR_15_8(reg_addr + start_offset);
writel(reg, &dp_regs->aux_addr_15_8);
reg = AUX_ADDR_19_16(reg_addr + start_offset);
writel(reg, &dp_regs->aux_addr_19_16);
for (cur_data_idx = 0; cur_data_idx < cur_data_count;
cur_data_idx++) {
reg = data[start_offset + cur_data_idx];
writel(reg, (unsigned int)&dp_regs->buf_data0 +
(4 * cur_data_idx));
}
/*
* Set DisplayPort transaction and write
* If bit 3 is 1, DisplayPort transaction.
* If Bit 3 is 0, I2C transaction.
*/
reg = AUX_LENGTH(cur_data_count) |
AUX_TX_COMM_DP_TRANSACTION | AUX_TX_COMM_WRITE;
writel(reg, &dp_regs->aux_ch_ctl1);
/* Start AUX transaction */
ret = exynos_dp_start_aux_transaction(dp_regs);
if (ret != EXYNOS_DP_SUCCESS) {
if (retry_cnt == 0) {
printf("DP Aux Transaction failed\n");
return ret;
}
retry_cnt--;
} else
break;
}
start_offset += cur_data_count;
}
return ret;
}
unsigned int exynos_dp_read_bytes_from_dpcd(struct exynos_dp *dp_regs,
unsigned int reg_addr,
unsigned int count,
unsigned char data[])
{
unsigned int reg;
unsigned int start_offset;
unsigned int cur_data_count;
unsigned int cur_data_idx;
unsigned int retry_cnt;
unsigned int ret = 0;
/* Clear AUX CH data buffer */
reg = BUF_CLR;
writel(reg, &dp_regs->buffer_data_ctl);
start_offset = 0;
while (start_offset < count) {
/* Buffer size of AUX CH is 16 * 4bytes */
if ((count - start_offset) > 16)
cur_data_count = 16;
else
cur_data_count = count - start_offset;
retry_cnt = 5;
while (retry_cnt) {
/* Select DPCD device address */
reg = AUX_ADDR_7_0(reg_addr + start_offset);
writel(reg, &dp_regs->aux_addr_7_0);
reg = AUX_ADDR_15_8(reg_addr + start_offset);
writel(reg, &dp_regs->aux_addr_15_8);
reg = AUX_ADDR_19_16(reg_addr + start_offset);
writel(reg, &dp_regs->aux_addr_19_16);
/*
* Set DisplayPort transaction and read
* If bit 3 is 1, DisplayPort transaction.
* If Bit 3 is 0, I2C transaction.
*/
reg = AUX_LENGTH(cur_data_count) |
AUX_TX_COMM_DP_TRANSACTION | AUX_TX_COMM_READ;
writel(reg, &dp_regs->aux_ch_ctl1);
/* Start AUX transaction */
ret = exynos_dp_start_aux_transaction(dp_regs);
if (ret != EXYNOS_DP_SUCCESS) {
if (retry_cnt == 0) {
printf("DP Aux Transaction failed\n");
return ret;
}
retry_cnt--;
} else
break;
}
for (cur_data_idx = 0; cur_data_idx < cur_data_count;
cur_data_idx++) {
reg = readl((unsigned int)&dp_regs->buf_data0 +
4 * cur_data_idx);
data[start_offset + cur_data_idx] = (unsigned char)reg;
}
start_offset += cur_data_count;
}
return ret;
}
int exynos_dp_select_i2c_device(struct exynos_dp *dp_regs,
unsigned int device_addr, unsigned int reg_addr)
{
unsigned int reg;
int retval;
/* Set EDID device address */
reg = device_addr;
writel(reg, &dp_regs->aux_addr_7_0);
writel(0x0, &dp_regs->aux_addr_15_8);
writel(0x0, &dp_regs->aux_addr_19_16);
/* Set offset from base address of EDID device */
writel(reg_addr, &dp_regs->buf_data0);
/*
* Set I2C transaction and write address
* If bit 3 is 1, DisplayPort transaction.
* If Bit 3 is 0, I2C transaction.
*/
reg = AUX_TX_COMM_I2C_TRANSACTION | AUX_TX_COMM_MOT |
AUX_TX_COMM_WRITE;
writel(reg, &dp_regs->aux_ch_ctl1);
/* Start AUX transaction */
retval = exynos_dp_start_aux_transaction(dp_regs);
if (retval != 0)
printf("%s: DP Aux Transaction fail!\n", __func__);
return retval;
}
int exynos_dp_read_byte_from_i2c(struct exynos_dp *dp_regs,
unsigned int device_addr,
unsigned int reg_addr, unsigned int *data)
{
unsigned int reg;
int i;
int retval;
for (i = 0; i < 10; i++) {
/* Clear AUX CH data buffer */
reg = BUF_CLR;
writel(reg, &dp_regs->buffer_data_ctl);
/* Select EDID device */
retval = exynos_dp_select_i2c_device(dp_regs, device_addr,
reg_addr);
if (retval != 0) {
printf("DP Select EDID device fail. retry !\n");
continue;
}
/*
* Set I2C transaction and read data
* If bit 3 is 1, DisplayPort transaction.
* If Bit 3 is 0, I2C transaction.
*/
reg = AUX_TX_COMM_I2C_TRANSACTION |
AUX_TX_COMM_READ;
writel(reg, &dp_regs->aux_ch_ctl1);
/* Start AUX transaction */
retval = exynos_dp_start_aux_transaction(dp_regs);
if (retval != EXYNOS_DP_SUCCESS)
printf("%s: DP Aux Transaction fail!\n", __func__);
}
/* Read data */
if (retval == 0)
*data = readl(&dp_regs->buf_data0);
return retval;
}
int exynos_dp_read_bytes_from_i2c(struct exynos_dp *dp_regs,
unsigned int device_addr,
unsigned int reg_addr, unsigned int count,
unsigned char edid[])
{
unsigned int reg;
unsigned int i, j;
unsigned int cur_data_idx;
unsigned int defer = 0;
int retval = 0;
for (i = 0; i < count; i += 16) { /* use 16 burst */
for (j = 0; j < 100; j++) {
/* Clear AUX CH data buffer */
reg = BUF_CLR;
writel(reg, &dp_regs->buffer_data_ctl);
/* Set normal AUX CH command */
reg = readl(&dp_regs->aux_ch_ctl2);
reg &= ~ADDR_ONLY;
writel(reg, &dp_regs->aux_ch_ctl2);
/*
* If Rx sends defer, Tx sends only reads
* request without sending addres
*/
if (!defer)
retval = exynos_dp_select_i2c_device(
dp_regs, device_addr, reg_addr + i);
else
defer = 0;
if (retval == EXYNOS_DP_SUCCESS) {
/*
* Set I2C transaction and write data
* If bit 3 is 1, DisplayPort transaction.
* If Bit 3 is 0, I2C transaction.
*/
reg = AUX_LENGTH(16) |
AUX_TX_COMM_I2C_TRANSACTION |
AUX_TX_COMM_READ;
writel(reg, &dp_regs->aux_ch_ctl1);
/* Start AUX transaction */
retval = exynos_dp_start_aux_transaction(
dp_regs);
if (retval == 0)
break;
else
printf("DP Aux Transaction fail!\n");
}
/* Check if Rx sends defer */
reg = readl(&dp_regs->aux_rx_comm);
if (reg == AUX_RX_COMM_AUX_DEFER ||
reg == AUX_RX_COMM_I2C_DEFER) {
printf("DP Defer: %d\n", reg);
defer = 1;
}
}
for (cur_data_idx = 0; cur_data_idx < 16; cur_data_idx++) {
reg = readl((unsigned int)&dp_regs->buf_data0
+ 4 * cur_data_idx);
edid[i + cur_data_idx] = (unsigned char)reg;
}
}
return retval;
}
void exynos_dp_reset_macro(struct exynos_dp *dp_regs)
{
unsigned int reg;
reg = readl(&dp_regs->phy_test);
reg |= MACRO_RST;
writel(reg, &dp_regs->phy_test);
/* 10 us is the minimum Macro reset time. */
mdelay(1);
reg &= ~MACRO_RST;
writel(reg, &dp_regs->phy_test);
}
void exynos_dp_set_link_bandwidth(struct exynos_dp *dp_regs,
unsigned char bwtype)
{
unsigned int reg;
reg = (unsigned int)bwtype;
/* Set bandwidth to 2.7G or 1.62G */
if ((bwtype == DP_LANE_BW_1_62) || (bwtype == DP_LANE_BW_2_70))
writel(reg, &dp_regs->link_bw_set);
}
unsigned char exynos_dp_get_link_bandwidth(struct exynos_dp *dp_regs)
{
unsigned char ret;
unsigned int reg;
reg = readl(&dp_regs->link_bw_set);
ret = (unsigned char)reg;
return ret;
}
void exynos_dp_set_lane_count(struct exynos_dp *dp_regs, unsigned char count)
{
unsigned int reg;
reg = (unsigned int)count;
if ((count == DP_LANE_CNT_1) || (count == DP_LANE_CNT_2) ||
(count == DP_LANE_CNT_4))
writel(reg, &dp_regs->lane_count_set);
}
unsigned int exynos_dp_get_lane_count(struct exynos_dp *dp_regs)
{
return readl(&dp_regs->lane_count_set);
}
unsigned char exynos_dp_get_lanex_pre_emphasis(struct exynos_dp *dp_regs,
unsigned char lanecnt)
{
unsigned int reg_list[DP_LANE_CNT_4] = {
(unsigned int)&dp_regs->ln0_link_training_ctl,
(unsigned int)&dp_regs->ln1_link_training_ctl,
(unsigned int)&dp_regs->ln2_link_training_ctl,
(unsigned int)&dp_regs->ln3_link_training_ctl,
};
return readl(reg_list[lanecnt]);
}
void exynos_dp_set_lanex_pre_emphasis(struct exynos_dp *dp_regs,
unsigned char request_val,
unsigned char lanecnt)
{
unsigned int reg_list[DP_LANE_CNT_4] = {
(unsigned int)&dp_regs->ln0_link_training_ctl,
(unsigned int)&dp_regs->ln1_link_training_ctl,
(unsigned int)&dp_regs->ln2_link_training_ctl,
(unsigned int)&dp_regs->ln3_link_training_ctl,
};
writel(request_val, reg_list[lanecnt]);
}
void exynos_dp_set_lane_pre_emphasis(struct exynos_dp *dp_regs,
unsigned int level, unsigned char lanecnt)
{
unsigned char i;
unsigned int reg;
unsigned int reg_list[DP_LANE_CNT_4] = {
(unsigned int)&dp_regs->ln0_link_training_ctl,
(unsigned int)&dp_regs->ln1_link_training_ctl,
(unsigned int)&dp_regs->ln2_link_training_ctl,
(unsigned int)&dp_regs->ln3_link_training_ctl,
};
unsigned int reg_shift[DP_LANE_CNT_4] = {
PRE_EMPHASIS_SET_0_SHIFT,
PRE_EMPHASIS_SET_1_SHIFT,
PRE_EMPHASIS_SET_2_SHIFT,
PRE_EMPHASIS_SET_3_SHIFT
};
for (i = 0; i < lanecnt; i++) {
reg = level << reg_shift[i];
writel(reg, reg_list[i]);
}
}
void exynos_dp_set_training_pattern(struct exynos_dp *dp_regs,
unsigned int pattern)
{
unsigned int reg = 0;
switch (pattern) {
case PRBS7:
reg = SCRAMBLING_ENABLE | LINK_QUAL_PATTERN_SET_PRBS7;
break;
case D10_2:
reg = SCRAMBLING_ENABLE | LINK_QUAL_PATTERN_SET_D10_2;
break;
case TRAINING_PTN1:
reg = SCRAMBLING_DISABLE | SW_TRAINING_PATTERN_SET_PTN1;
break;
case TRAINING_PTN2:
reg = SCRAMBLING_DISABLE | SW_TRAINING_PATTERN_SET_PTN2;
break;
case DP_NONE:
reg = SCRAMBLING_ENABLE | LINK_QUAL_PATTERN_SET_DISABLE |
SW_TRAINING_PATTERN_SET_NORMAL;
break;
default:
break;
}
writel(reg, &dp_regs->training_ptn_set);
}
void exynos_dp_enable_enhanced_mode(struct exynos_dp *dp_regs,
unsigned char enable)
{
unsigned int reg;
reg = readl(&dp_regs->sys_ctl4);
reg &= ~ENHANCED;
if (enable)
reg |= ENHANCED;
writel(reg, &dp_regs->sys_ctl4);
}
void exynos_dp_enable_scrambling(struct exynos_dp *dp_regs, unsigned int enable)
{
unsigned int reg;
reg = readl(&dp_regs->training_ptn_set);
reg &= ~(SCRAMBLING_DISABLE);
if (!enable)
reg |= SCRAMBLING_DISABLE;
writel(reg, &dp_regs->training_ptn_set);
}
int exynos_dp_init_video(struct exynos_dp *dp_regs)
{
unsigned int reg;
/* Clear VID_CLK_CHG[1] and VID_FORMAT_CHG[3] and VSYNC_DET[7] */
reg = VSYNC_DET | VID_FORMAT_CHG | VID_CLK_CHG;
writel(reg, &dp_regs->common_int_sta1);
/* I_STRM__CLK detect : DE_CTL : Auto detect */
reg &= ~DET_CTRL;
writel(reg, &dp_regs->sys_ctl1);
return 0;
}
void exynos_dp_config_video_slave_mode(struct exynos_dp *dp_regs,
struct edp_video_info *video_info)
{
unsigned int reg;
/* Video Slave mode setting */
reg = readl(&dp_regs->func_en1);
reg &= ~(MASTER_VID_FUNC_EN_N|SLAVE_VID_FUNC_EN_N);
reg |= MASTER_VID_FUNC_EN_N;
writel(reg, &dp_regs->func_en1);
/* Configure Interlaced for slave mode video */
reg = readl(&dp_regs->video_ctl10);
reg &= ~INTERACE_SCAN_CFG;
reg |= (video_info->interlaced << INTERACE_SCAN_CFG_SHIFT);
writel(reg, &dp_regs->video_ctl10);
/* Configure V sync polarity for slave mode video */
reg = readl(&dp_regs->video_ctl10);
reg &= ~VSYNC_POLARITY_CFG;
reg |= (video_info->v_sync_polarity << V_S_POLARITY_CFG_SHIFT);
writel(reg, &dp_regs->video_ctl10);
/* Configure H sync polarity for slave mode video */
reg = readl(&dp_regs->video_ctl10);
reg &= ~HSYNC_POLARITY_CFG;
reg |= (video_info->h_sync_polarity << H_S_POLARITY_CFG_SHIFT);
writel(reg, &dp_regs->video_ctl10);
/* Set video mode to slave mode */
reg = AUDIO_MODE_SPDIF_MODE | VIDEO_MODE_SLAVE_MODE;
writel(reg, &dp_regs->soc_general_ctl);
}
void exynos_dp_set_video_color_format(struct exynos_dp *dp_regs,
struct edp_video_info *video_info)
{
unsigned int reg;
/* Configure the input color depth, color space, dynamic range */
reg = (video_info->dynamic_range << IN_D_RANGE_SHIFT) |
(video_info->color_depth << IN_BPC_SHIFT) |
(video_info->color_space << IN_COLOR_F_SHIFT);
writel(reg, &dp_regs->video_ctl2);
/* Set Input Color YCbCr Coefficients to ITU601 or ITU709 */
reg = readl(&dp_regs->video_ctl3);
reg &= ~IN_YC_COEFFI_MASK;
if (video_info->ycbcr_coeff)
reg |= IN_YC_COEFFI_ITU709;
else
reg |= IN_YC_COEFFI_ITU601;
writel(reg, &dp_regs->video_ctl3);
}
int exynos_dp_config_video_bist(struct exynos_dp *dp_regs,
struct exynos_dp_priv *priv)
{
unsigned int reg;
unsigned int bist_type = 0;
struct edp_video_info video_info = priv->video_info;
/* For master mode, you don't need to set the video format */
if (video_info.master_mode == 0) {
writel(TOTAL_LINE_CFG_L(priv->disp_info.v_total),
&dp_regs->total_ln_cfg_l);
writel(TOTAL_LINE_CFG_H(priv->disp_info.v_total),
&dp_regs->total_ln_cfg_h);
writel(ACTIVE_LINE_CFG_L(priv->disp_info.v_res),
&dp_regs->active_ln_cfg_l);
writel(ACTIVE_LINE_CFG_H(priv->disp_info.v_res),
&dp_regs->active_ln_cfg_h);
writel(priv->disp_info.v_sync_width, &dp_regs->vsw_cfg);
writel(priv->disp_info.v_back_porch, &dp_regs->vbp_cfg);
writel(priv->disp_info.v_front_porch, &dp_regs->vfp_cfg);
writel(TOTAL_PIXEL_CFG_L(priv->disp_info.h_total),
&dp_regs->total_pix_cfg_l);
writel(TOTAL_PIXEL_CFG_H(priv->disp_info.h_total),
&dp_regs->total_pix_cfg_h);
writel(ACTIVE_PIXEL_CFG_L(priv->disp_info.h_res),
&dp_regs->active_pix_cfg_l);
writel(ACTIVE_PIXEL_CFG_H(priv->disp_info.h_res),
&dp_regs->active_pix_cfg_h);
writel(H_F_PORCH_CFG_L(priv->disp_info.h_front_porch),
&dp_regs->hfp_cfg_l);
writel(H_F_PORCH_CFG_H(priv->disp_info.h_front_porch),
&dp_regs->hfp_cfg_h);
writel(H_SYNC_PORCH_CFG_L(priv->disp_info.h_sync_width),
&dp_regs->hsw_cfg_l);
writel(H_SYNC_PORCH_CFG_H(priv->disp_info.h_sync_width),
&dp_regs->hsw_cfg_h);
writel(H_B_PORCH_CFG_L(priv->disp_info.h_back_porch),
&dp_regs->hbp_cfg_l);
writel(H_B_PORCH_CFG_H(priv->disp_info.h_back_porch),
&dp_regs->hbp_cfg_h);
/*
* Set SLAVE_I_SCAN_CFG[2], VSYNC_P_CFG[1],
* HSYNC_P_CFG[0] properly
*/
reg = (video_info.interlaced << INTERACE_SCAN_CFG_SHIFT |
video_info.v_sync_polarity << V_S_POLARITY_CFG_SHIFT |
video_info.h_sync_polarity << H_S_POLARITY_CFG_SHIFT);
writel(reg, &dp_regs->video_ctl10);
}
/* BIST color bar width set--set to each bar is 32 pixel width */
switch (video_info.bist_pattern) {
case COLORBAR_32:
bist_type = BIST_WIDTH_BAR_32_PIXEL |
BIST_TYPE_COLOR_BAR;
break;
case COLORBAR_64:
bist_type = BIST_WIDTH_BAR_64_PIXEL |
BIST_TYPE_COLOR_BAR;
break;
case WHITE_GRAY_BALCKBAR_32:
bist_type = BIST_WIDTH_BAR_32_PIXEL |
BIST_TYPE_WHITE_GRAY_BLACK_BAR;
break;
case WHITE_GRAY_BALCKBAR_64:
bist_type = BIST_WIDTH_BAR_64_PIXEL |
BIST_TYPE_WHITE_GRAY_BLACK_BAR;
break;
case MOBILE_WHITEBAR_32:
bist_type = BIST_WIDTH_BAR_32_PIXEL |
BIST_TYPE_MOBILE_WHITE_BAR;
break;
case MOBILE_WHITEBAR_64:
bist_type = BIST_WIDTH_BAR_64_PIXEL |
BIST_TYPE_MOBILE_WHITE_BAR;
break;
default:
return -1;
}
reg = bist_type;
writel(reg, &dp_regs->video_ctl4);
return 0;
}
unsigned int exynos_dp_is_slave_video_stream_clock_on(struct exynos_dp *dp_regs)
{
unsigned int reg;
/* Update Video stream clk detect status */
reg = readl(&dp_regs->sys_ctl1);
writel(reg, &dp_regs->sys_ctl1);
reg = readl(&dp_regs->sys_ctl1);
if (!(reg & DET_STA)) {
debug("DP Input stream clock not detected.\n");
return -EIO;
}
return EXYNOS_DP_SUCCESS;
}
void exynos_dp_set_video_cr_mn(struct exynos_dp *dp_regs, unsigned int type,
unsigned int m_value, unsigned int n_value)
{
unsigned int reg;
if (type == REGISTER_M) {
reg = readl(&dp_regs->sys_ctl4);
reg |= FIX_M_VID;
writel(reg, &dp_regs->sys_ctl4);
reg = M_VID0_CFG(m_value);
writel(reg, &dp_regs->m_vid0);
reg = M_VID1_CFG(m_value);
writel(reg, &dp_regs->m_vid1);
reg = M_VID2_CFG(m_value);
writel(reg, &dp_regs->m_vid2);
reg = N_VID0_CFG(n_value);
writel(reg, &dp_regs->n_vid0);
reg = N_VID1_CFG(n_value);
writel(reg, &dp_regs->n_vid1);
reg = N_VID2_CFG(n_value);
writel(reg, &dp_regs->n_vid2);
} else {
reg = readl(&dp_regs->sys_ctl4);
reg &= ~FIX_M_VID;
writel(reg, &dp_regs->sys_ctl4);
}
}
void exynos_dp_set_video_timing_mode(struct exynos_dp *dp_regs,
unsigned int type)
{
unsigned int reg;
reg = readl(&dp_regs->video_ctl10);
reg &= ~FORMAT_SEL;
if (type != VIDEO_TIMING_FROM_CAPTURE)
reg |= FORMAT_SEL;
writel(reg, &dp_regs->video_ctl10);
}
void exynos_dp_enable_video_master(struct exynos_dp *dp_regs,
unsigned int enable)
{
unsigned int reg;
reg = readl(&dp_regs->soc_general_ctl);
if (enable) {
reg &= ~VIDEO_MODE_MASK;
reg |= VIDEO_MASTER_MODE_EN | VIDEO_MODE_MASTER_MODE;
} else {
reg &= ~VIDEO_MODE_MASK;
reg |= VIDEO_MODE_SLAVE_MODE;
}
writel(reg, &dp_regs->soc_general_ctl);
}
void exynos_dp_start_video(struct exynos_dp *dp_regs)
{
unsigned int reg;
/* Enable Video input and disable Mute */
reg = readl(&dp_regs->video_ctl1);
reg |= VIDEO_EN;
writel(reg, &dp_regs->video_ctl1);
}
unsigned int exynos_dp_is_video_stream_on(struct exynos_dp *dp_regs)
{
unsigned int reg;
/* Update STRM_VALID */
reg = readl(&dp_regs->sys_ctl3);
writel(reg, &dp_regs->sys_ctl3);
reg = readl(&dp_regs->sys_ctl3);
if (!(reg & STRM_VALID))
return -EIO;
return EXYNOS_DP_SUCCESS;
}