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/*
* * Copyright (c) 2010, Code Aurora Forum. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
* * Neither the name of Code Aurora Forum, Inc. nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
* OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <debug.h>
#include <kernel/thread.h>
#include <i2c_qup.h>
#include <platform/iomap.h>
#include <platform/gpio_hw.h>
#include <platform/clock.h>
#include <platform/pmic.h>
#define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0]))
static struct qup_i2c_dev *dev = NULL;
uint8_t expander_read(uint8_t addr)
{
uint8_t ret = 0;
/* Create a i2c_msg buffer, that is used to put the controller into read
mode and then to read some data. */
struct i2c_msg msg_buf[] = {
{CORE_GPIO_EXPANDER_I2C_ADDRESS, I2C_M_WR, 1, &addr},
{CORE_GPIO_EXPANDER_I2C_ADDRESS, I2C_M_RD, 1, &ret}
};
qup_i2c_xfer(dev, msg_buf, 2);
return ret;
}
uint8_t expander_write(uint8_t addr, uint8_t val)
{
uint8_t data_buf[] = { addr, val };
/* Create a i2c_msg buffer, that is used to put the controller into write
mode and then to write some data. */
struct i2c_msg msg_buf[] = { {CORE_GPIO_EXPANDER_I2C_ADDRESS,
I2C_M_WR, 2, data_buf}
};
qup_i2c_xfer(dev, msg_buf, 1);
/* Double check that the write worked. */
if (val != expander_read(addr)) {
return -1;
}
return 0;
}
void panel_poweron(void)
{
panel_backlight(1);
lcdc_on();
}
void panel_backlight(int on)
{
}
static int display_common_power(int on)
{
}
static int lcd_power_on()
{
uint8_t buffer = 0x0, mask = 0x0, prev_val = 0x0;
int ret = 0;
/* Configure LDO L2 TEST Bank 2, to Range Select 0 */
buffer = (0x80); /* Write mode */
buffer |= (PM8901_LDO_TEST_BANK(2)); /* Test Bank 2 */
mask = buffer | LDO_TEST_RANGE_SELECT_MASK;
if ((ret = pm8901_test_bank_read(&prev_val,
PM8901_LDO_TEST_BANK(2),
PM8901_LDO_L2_TEST_BANK))) {
return ret;
}
if ((ret = pm8901_vreg_write(&buffer, mask, PM8901_LDO_L2_TEST_BANK,
prev_val))) {
return ret;
}
/* Configure LDO L2 TEST Bank 4, for High Range Mode */
buffer = (0x80); /* Write mode */
buffer |= (PM8901_LDO_TEST_BANK(4)); /* Test Bank 4 */
buffer |= (0x01); /* Put into High Range Mode */
mask = buffer | LDO_TEST_OUTPUT_RANGE_MASK;
if ((ret = pm8901_test_bank_read(&prev_val,
PM8901_LDO_TEST_BANK(4),
PM8901_LDO_L2_TEST_BANK))) {
return ret;
}
if ((ret = pm8901_vreg_write(&buffer, mask, PM8901_LDO_L2_TEST_BANK,
prev_val))) {
return ret;
}
/* Configure LDO L2 TEST Bank 5, for XO_EN<3-0> to 1 */
buffer = (0x80); /* Write mode */
buffer |= (PM8901_LDO_TEST_BANK(5)); /* Test Bank 5 */
buffer |= (0x0F); /* Enable XO_EN */
mask = buffer | LDO_TEST_XO_EN_ALL_MASK;
if ((ret = pm8901_test_bank_read(&prev_val,
PM8901_LDO_TEST_BANK(5),
PM8901_LDO_L2_TEST_BANK))) {
return ret;
}
if ((ret = pm8901_vreg_write(&buffer, mask, PM8901_LDO_L2_TEST_BANK,
prev_val))) {
return ret;
}
/* Enable LDO L2 at Max Voltage (should be around 3.3v) */
buffer = (0x1 << PM8901_LDO_CTL_ENABLE__S);
/* Disable Pull Down */
buffer |= (0x0 << PM8901_LDO_CTL_PULL_DOWN__S);
/* Put LDO into normal mode instead of low power mode */
buffer |= (0x0 << PM8901_LDO_CTL_MODE__S);
/* Write a 31 into the Voltage Programming value to obtain 3.3v VREG =
1.75V + X * 100mV */
buffer |= (0x1F);
mask = buffer | LDO_CTL_ENABLE_MASK |
LDO_CTL_PULL_DOWN_MASK |
LDO_CTL_NORMAL_POWER_MODE_MASK | LDO_CTL_VOLTAGE_SET_MASK;
/* Do a normal read here, as to not destroy the value in LDO control */
if ((ret = pm8901_read(&prev_val, 1, PM8901_LDO_L2))) {
return ret;
}
/* Configure the LDO2 for 3.3v */
ret = pm8901_vreg_write(&buffer, mask, PM8901_LDO_L2, prev_val);
return ret;
}
/* Configures the GPIO that are needed to enable LCD.
* This function also configures the PMIC for PWM control of the LCD backlight.
*/
static void lcd_gpio_cfg(uint8_t on)
{
uint32_t func;
uint32_t pull;
uint32_t dir;
uint32_t enable = 0; /* not used in gpio_tlmm_config */
uint32_t drv;
if (on) {
func = 1; /* Configure GPIO for LCDC function */
pull = GPIO_NO_PULL;
dir = 1; /* doesn't matter since it is not configured as
GPIO */
drv = GPIO_16MA;
} else {
/* As discussed in the MSM8660 FFA HW SW Control Doc configure these
GPIO as input and pull down. */
func = 0; /* GPIO */
pull = GPIO_PULL_DOWN;
dir = 0; /* Input */
drv = 0; /* does not matter configured as input */
}
gpio_tlmm_config(0, func, dir, pull, drv, enable); /* lcdc_pclk */
gpio_tlmm_config(1, func, dir, pull, drv, enable); /* lcdc_hsync */
gpio_tlmm_config(2, func, dir, pull, drv, enable); /* lcdc_vsync */
gpio_tlmm_config(3, func, dir, pull, drv, enable); /* lcdc_den */
gpio_tlmm_config(4, func, dir, pull, drv, enable); /* lcdc_red7 */
gpio_tlmm_config(5, func, dir, pull, drv, enable); /* lcdc_red6 */
gpio_tlmm_config(6, func, dir, pull, drv, enable); /* lcdc_red5 */
gpio_tlmm_config(7, func, dir, pull, drv, enable); /* lcdc_red4 */
gpio_tlmm_config(8, func, dir, pull, drv, enable); /* lcdc_red3 */
gpio_tlmm_config(9, func, dir, pull, drv, enable); /* lcdc_red2 */
gpio_tlmm_config(10, func, dir, pull, drv, enable); /* lcdc_red1 */
gpio_tlmm_config(11, func, dir, pull, drv, enable); /* lcdc_red0 */
gpio_tlmm_config(12, func, dir, pull, drv, enable); /* lcdc_rgn7 */
gpio_tlmm_config(13, func, dir, pull, drv, enable); /* lcdc_rgn6 */
gpio_tlmm_config(14, func, dir, pull, drv, enable); /* lcdc_rgn5 */
gpio_tlmm_config(15, func, dir, pull, drv, enable); /* lcdc_rgn4 */
gpio_tlmm_config(16, func, dir, pull, drv, enable); /* lcdc_rgn3 */
gpio_tlmm_config(17, func, dir, pull, drv, enable); /* lcdc_rgn2 */
gpio_tlmm_config(18, func, dir, pull, drv, enable); /* lcdc_rgn1 */
gpio_tlmm_config(19, func, dir, pull, drv, enable); /* lcdc_rgn0 */
gpio_tlmm_config(20, func, dir, pull, drv, enable); /* lcdc_blu7 */
gpio_tlmm_config(21, func, dir, pull, drv, enable); /* lcdc_blu6 */
gpio_tlmm_config(22, func, dir, pull, drv, enable); /* lcdc_blu5 */
gpio_tlmm_config(23, func, dir, pull, drv, enable); /* lcdc_blu4 */
gpio_tlmm_config(24, func, dir, pull, drv, enable); /* lcdc_blu3 */
gpio_tlmm_config(25, func, dir, pull, drv, enable); /* lcdc_blu2 */
gpio_tlmm_config(26, func, dir, pull, drv, enable); /* lcdc_blu1 */
gpio_tlmm_config(27, func, dir, pull, drv, enable); /* lcdc_blu0 */
}
/* Backlight duty cycle init is used to configure the PMIC8058 for
* PWM output and drive those pins.
*/
static void bl_duty_cycle_init(void)
{
/* Disable backlight LPG channels before configuring them and dedicated
PMIC GPIOs */
pm8058_write_one(0x00, LPG_BANK_ENABLE);
/* Configure PM8058 GPIO24 as a PWM driver (LPG ch0) for chain 1 of 6 LEDs */
pm8058_write_one(0x81, GPIO24_GPIO_CNTRL); /* Write, Bank0, VIN0, Mode
selection enabled */
pm8058_write_one(0x98, GPIO24_GPIO_CNTRL); /* Write, Bank1, OutOn/InOff,
CMOS, Don't Invert Output */
pm8058_write_one(0xAA, GPIO24_GPIO_CNTRL); /* Write, Bank2, GPIO no pull */
pm8058_write_one(0xB4, GPIO24_GPIO_CNTRL); /* Write, Bank3, high drv
strength */
pm8058_write_one(0xC6, GPIO24_GPIO_CNTRL); /* Write, Bank4, Src: LPG_DRV1
(Spec. Fnc 2) */
pm8058_write_one(0xD8, GPIO24_GPIO_CNTRL); /* Write, Bank5, Interrupt
polarity noninversion */
/* Configure PM8058 GPIO25 as a PWM driver (LPG ch1) for chain 2 of 5 LEDs */
pm8058_write_one(0x81, GPIO25_GPIO_CNTRL); /* Write, Bank0, VIN0, Mode
selection enabled */
pm8058_write_one(0x98, GPIO25_GPIO_CNTRL); /* Write, Bank1, OutOn/InOff,
CMOS, Don't Invert Output */
pm8058_write_one(0xAA, GPIO25_GPIO_CNTRL); /* Write, Bank2, GPIO no pull */
pm8058_write_one(0xB4, GPIO25_GPIO_CNTRL); /* Write, Bank3, high drv
strength */
pm8058_write_one(0xC6, GPIO25_GPIO_CNTRL); /* Write, Bank4, Src: LPG_DRV2
(Spec. Fnc 2) */
pm8058_write_one(0xD8, GPIO25_GPIO_CNTRL); /* Write, Bank5, Interrupt
polarity noninversion */
/* Configure PM8058 LPG channel 0 as non-LUT PWM for PM8058 GPIO24 */
pm8058_write_one(0x0, LPG_BANK_SEL); /* Select LPG ch0 slice of control
regs */
pm8058_write_one(0x00, LPG_CTL_0); /* Disable PWM, PWM output, and LPG
ramp generator */
pm8058_write_one(0x40, LPG_CTL_1); /* Dont Toggle, Enable user PWM value,
no LUT high value idx */
pm8058_write_one(0x00, LPG_CTL_2); /* Dont Loop, no LUT low value index */
pm8058_write_one(0xDE, LPG_CTL_3); /* LS 8 bits of 9-bit PWM user value */
pm8058_write_one(0x7F, LPG_CTL_4); /* MSbit of 9-bit PWM user value,
19.2MHz, Dev 6, Expo M = 7 */
pm8058_write_one(0x01, LPG_CTL_5); /* PWM = 9bit, disable pause at high
value LUT index */
pm8058_write_one(0x00, LPG_CTL_6); /* Disable pause at low value LUT index
*/
pm8058_write_one(0x0C, LPG_CTL_0); /* Enable PWM and PWM output, LPG ramp
generator remains disabled */
/* Configure PM8058 LPG chan 1 as PWM for PM8058 GPIO25 */
pm8058_write_one(0x1, LPG_BANK_SEL); /* Select LPG ch1 slice of control
regs */
pm8058_write_one(0x00, LPG_CTL_0); /* Disable PWM, PWM output, and LPG
ramp generator */
pm8058_write_one(0x40, LPG_CTL_1); /* Dont Toggle, Enable user PWM value,
no LUT high value idx */
pm8058_write_one(0x00, LPG_CTL_2); /* Dont Loop, no LUT low value index */
pm8058_write_one(0x00, LPG_CTL_3); /* LS 8 bits of 9-bit PWM user value */
pm8058_write_one(0x7F, LPG_CTL_4); /* MSbit of 9-bit PWM user value,
19.2MHz, Dev 6, Expo M = 7 */
pm8058_write_one(0x01, LPG_CTL_5); /* PWM = 9bit, disable pause at high
value LUT index */
pm8058_write_one(0x00, LPG_CTL_6); /* Disable pause at low value LUT index
*/
pm8058_write_one(0x0C, LPG_CTL_0); /* Enable PWM and PWM output, LPG ramp
generator remains disabled */
/* Enable both LPG channels to enable backlight driver */
pm8058_write_one(0x03, LPG_BANK_ENABLE); /* Enable LPG ch0 (GPIO24) &
ch1 (GPIO25) */
}
void board_lcd_enable(void)
{
dev = qup_i2c_init(GSBI8_BASE, 100000, 24000000);
/* Make sure dev is created and initialized properly */
if (!dev) {
while (1) ;
return;
}
/* Store current value of these registers as to not destroy their previous
state. */
uint8_t open_drain_a = expander_read(GPIO_EXPANDER_REG_OPEN_DRAIN_A);
uint8_t dir_b = expander_read(GPIO_EXPANDER_REG_DIR_B);
uint8_t dir_a = expander_read(GPIO_EXPANDER_REG_DIR_A);
uint8_t data_b = expander_read(GPIO_EXPANDER_REG_DATA_B);
uint8_t data_a = expander_read(GPIO_EXPANDER_REG_DATA_A);
/* Set the LVDS_SHUTDOWN_N to open drain and output low. */
dprintf(INFO, "Enable lvds_shutdown_n line for Open Drain.\n");
expander_write(GPIO_EXPANDER_REG_OPEN_DRAIN_A, 0x04 | open_drain_a);
dprintf(INFO, "Enable lvds_shutdown_n line for output.\n");
expander_write(GPIO_EXPANDER_REG_DIR_A, ~0x04 & dir_a);
dprintf(INFO, "Drive the LVDS_SHUTDOWN_N pin high here.\n");
expander_write(GPIO_EXPANDER_REG_DATA_A, 0x04 | data_a);
/* Turn on the VREG_L2B to 3.3V. */
/* Power on the appropiate PMIC LDO power rails */
if (lcd_power_on())
return;
/* Enable the GPIO as LCDC mode LCD. */
lcd_gpio_cfg(1);
/* Arbitrary delay */
udelay(20000);
/* Set the backlight duty cycle via the PM8058 LPG_DRV1 and LPG_DRV2 */
bl_duty_cycle_init();
dprintf(INFO, "Enable BACKLIGHT_EN line for output.\n");
expander_write(GPIO_EXPANDER_REG_DIR_B, ~0x10 & dir_b);
dprintf(INFO, "Drive BACKLIGHT_EN to high\n");
expander_write(GPIO_EXPANDER_REG_DATA_B, 0x10 | data_b);
}
void mdp_clock_init(void)
{
/* Set the MDP_AXI_CLK to 165MHz, use MX0 for now */
config_mdp_axi_clk(0);
/* Turn on the PLL2, to ramp up the MDP clock to max (200MHz) */
nt_pll_enable(PLL_2, 1);
config_mdp_clk(MDP_NS_VAL, MDP_MD_VAL,
MDP_CC_VAL, MDP_NS_REG, MDP_MD_REG, MDP_CC_REG);
config_pixel_clk(PIXEL_NS_VAL, PIXEL_MD_VAL,
PIXEL_CC_VAL, LCD_PIXEL_NS_REG,
LCD_PIXEL_MD_REG, LCD_PIXEL_CC_REG);
}
void lcdc_on(void)
{
board_lcd_enable();
}