static void lcd_wrdata(uint8_t data)
{
/* Make sure that the LCD is available */
lcd_waitbusy();
/* Select DB0-15 as outputs (only DB-0-7 are actually used) */
putreg16(0, PIC32MX_IOPORTE_TRIS);
/* Set up to write the data */
pic32mx_gpiowrite(GPIO_LCD_RS, true); /* Select data */
pic32mx_gpiowrite(GPIO_LCD_RW, false); /* Select write */
lcd_shortdelay(2);
pic32mx_gpiowrite(GPIO_LCD_E, true); /* Enable transfer */
lcd_shortdelay(1);
/* Write the data to the LCD */
putreg16(data, PIC32MX_IOPORTE_PORT); /* Write the data */
lcd_shortdelay(1);
pic32mx_gpiowrite(GPIO_LCD_E, false);
}
void pic32mx_spi2select(FAR struct spi_dev_s *dev, enum spi_dev_e devid, bool selected)
{
spidbg("devid: %d CS: %s\n", (int)devid, selected ? "assert" : "de-assert");
if (devid == SPIDEV_FLASH)
{
pic32mx_gpiowrite(GPIO_SST25VF032B_CS, !selected);
}
else if (devid == SPIDEV_MUX)
{
pic32mx_gpiowrite(GPIO_PGA117_CS, !selected);
}
}
void up_setleds(FAR const struct led_setting_s *setting)
{
/* LEDs are pulled up so writing a low value (false) illuminates them */
if (setting->led0 != LED_NC)
{
pic32mx_gpiowrite(GPIO_LED_0, setting->led0 == LED_ON);
}
if (setting->led1 != LED_NC)
{
pic32mx_gpiowrite(GPIO_LED_1, setting->led1 == LED_ON);
}
}
void pic32mx_setled(int led, bool ledon)
{
if ((unsigned)led < PIC32MX_STARTERKIT_NLEDS)
{
pic32mx_gpiowrite(g_ledpincfg[led], ledon);
}
}
void board_userled(int led, bool ledon)
{
if ((unsigned)led < PIC32MX_UBW32_NLEDS)
{
pic32mx_gpiowrite(g_ledpincfg[led], ledon);
}
}
void up_setleds(FAR const struct led_setting_s *setting)
{
if (setting->led1 != LED_NC)
{
pic32mx_gpiowrite(GPIO_LED_1, setting->led1 == LED_ON);
}
if (setting->led2 != LED_NC)
{
pic32mx_gpiowrite(GPIO_LED_2, setting->led2 == LED_ON);
}
if (setting->led3 != LED_NC)
{
pic32mx_gpiowrite(GPIO_LED_3, setting->led3 == LED_ON);
}
}
void pic32mx_spi1select(FAR struct spi_dev_s *dev, enum spi_dev_e devid, bool selected)
{
spidbg("devid: %d CS: %s\n", (int)devid, selected ? "assert" : "de-assert");
if (devid == SPIDEV_MMCSD)
{
pic32mx_gpiowrite(GPIO_SD_CS, !selected);
}
}
void pic32mx_setled(int led, bool ledon)
{
/* LEDs are pulled up so writing a low value (false) illuminates them */
if ((unsigned)led < PIC32MX_MIRTOO_NLEDS)
{
pic32mx_gpiowrite(g_ledpincfg[led], ledon);
}
}
void board_userled(int led, bool ledon)
{
/* LEDs are pulled up so writing a low value (false) illuminates them */
if ((unsigned)led < PIC32MX_PIC32MX7MMB_NLEDS)
{
pic32mx_gpiowrite(g_ledpincfg[led], !ledon);
}
}
void pic32mx_spi2select(FAR struct spi_dev_s *dev, enum spi_dev_e devid, bool selected)
{
spivdbg("devid: %d CS: %s\n", (int)devid, selected ? "assert" : "de-assert");
/* The SD card chip select is pulled high and active low */
#ifdef PIC32_HAVE_SD
if (devid == SPIDEV_MMCSD)
{
pic32mx_gpiowrite(GPIO_SD_CS, !selected);
}
#endif
#ifdef PIC32_HAVE_SOIC
if (devid == SPIDEV_FLASH)
{
pic32mx_gpiowrite(GPIO_SOIC_CS, !selected);
}
#endif
}
static void lcd_brightness(uint8_t brightness)
{
/* The LIGHT and COMP pins are label PWM1 and PWM2 and so are obviously
* intended to support modulated outputs. However, here for simplicity,
* they are just treated as on/off discretes outputs.
*/
if (brightness > 0)
{
/* Turn the LCD light on */
pic32mx_gpiowrite(GPIO_LCD_LIGHT, true);
NOP;NOP;NOP;
pic32mx_gpiowrite(GPIO_LCD_COMP, true);
NOP;NOP;
pic32mx_gpiowrite(GPIO_LCD_PWR, true);
}
else
{
/* Turn the LCD light off */
pic32mx_gpiowrite(GPIO_LCD_PWR, false);
pic32mx_gpiowrite(GPIO_LCD_COMP, false);
pic32mx_gpiowrite(GPIO_LCD_LIGHT, false);
}
g_lcd1602.brightness = brightness;
}
void up_setleds(FAR const struct led_setting_s *setting)
{
if (setting->usb != LED_NC)
{
pic32mx_gpiowrite(GPIO_USB_LED, setting->usb != LED_ON);
}
if (setting->sd != LED_NC)
{
pic32mx_gpiowrite(GPIO_SD_LED, setting->sd != LED_ON);
}
if (setting->flash != LED_NC)
{
pic32mx_gpiowrite(GPIO_FLASH_LED, setting->flash != LED_ON);
}
if (setting->error != LED_NC)
{
pic32mx_gpiowrite(GPIO_ERROR_LED, setting->error != LED_ON);
}
}
static uint8_t lcd_readstatus(void)
{
uint8_t status;
/* Set up to read BUSY/AD information */
putreg16(0xff, PIC32MX_IOPORTE_TRISSET); /* Set DB0-7 as inputs */
pic32mx_gpiowrite(GPIO_LCD_RS, false); /* Select command */
pic32mx_gpiowrite(GPIO_LCD_RW, true); /* Select read */
lcd_shortdelay(2);
pic32mx_gpiowrite(GPIO_LCD_E, true); /* Enable transfer */
lcd_shortdelay(1);
/* Read the status from the LCD */
status = (uint8_t)getreg16(PIC32MX_IOPORTE_PORT);
lcd_shortdelay(1);
pic32mx_gpiowrite(GPIO_LCD_E, false);
return status;
}
static uint8_t lcd_rddata(void)
{
/* Make sure that the LCD is available */
lcd_waitbusy();
/* Setup to read data */
pic32mx_gpiowrite(GPIO_LCD_RS, true); /* Select data */
pic32mx_gpiowrite(GPIO_LCD_RW, true); /* Select read */
lcd_shortdelay(2);
pic32mx_gpiowrite(GPIO_LCD_E, true); /* Enable transfer */
lcd_shortdelay(1);
putreg16(0xff, PIC32MX_IOPORTE_TRISSET); /* Set DB0-7 as inputs */
pic32mx_gpiowrite(GPIO_LCD_E, false); /* Disable transfer */
/* Read the data from the LCD */
return (uint8_t)getreg16(PIC32MX_IOPORTE_PORT);
}
int up_lcd1602_initialize(void)
{
int ret = OK;
/* Only initialize the driver once. */
if (!g_lcd1602.initialized)
{
lcdinfo("Initializing\n");
/* Configure GPIO pins */
putreg16(0, PIC32MX_IOPORTE_TRIS); /* Set DB0-15 as outputs */
pic32mx_configgpio(GPIO_LCD_RS); /* RS: Selects commnand or data */
pic32mx_configgpio(GPIO_LCD_RW); /* RW: Selects read or write */
pic32mx_configgpio(GPIO_LCD_E); /* E: Starts transfer */
/* Configure LCD power in the OFF state */
pic32mx_configgpio(GPIO_LCD_LIGHT); /* K */
pic32mx_configgpio(GPIO_LCD_COMP); /* Vo */
pic32mx_configgpio(GPIO_LCD_PWR); /* Vbuson/AN5/RB5 controls +5V USB */
g_lcd1602.brightness = 0; /* Remember tht the light is off */
/* A small delay is necessary between when GPIO_LCD_E was set up as an
* output with initial value of 0 and this operation. That delay should
* be well covered by the intervening GPIO configurations.
*/
pic32mx_gpiowrite(GPIO_LCD_E, true); /* Enable transfer */
/* Configure and enable the LCD */
/* Delay for 4.1MS or more */
up_mdelay(5);
/* Select the 8-bit interface. BF cannot be checked before this command.
* This needs to be done a few times with some magic delays.
*
* Function set: 5x7 Style | N=2R | DL=8D
*/
lcd_wrcommand(HD4478OU_FUNC | HD4478OU_FUNC_F5x7 | HD4478OU_FUNC_N1 | HD4478OU_FUNC_DL8D);
up_udelay(100); /* Delay more than 100uS */
lcd_wrcommand(HD4478OU_FUNC | HD4478OU_FUNC_F5x7 | HD4478OU_FUNC_N1 | HD4478OU_FUNC_DL8D);
up_udelay(40); /* Delay more than 40uS */
lcd_wrcommand(HD4478OU_FUNC | HD4478OU_FUNC_F5x7 | HD4478OU_FUNC_N1 | HD4478OU_FUNC_DL8D);
lcd_waitbusy();
lcd_wrcommand(HD4478OU_FUNC | HD4478OU_FUNC_F5x7 | HD4478OU_FUNC_N1 | HD4478OU_FUNC_DL8D);
lcd_waitbusy();
/* Display ON, cursor OFF, blink OFF */
lcd_wrcommand(HD4478OU_DISPLAY | HD4478OU_DISPLAY_ON);
lcd_waitbusy();
/* Clear the display and home the cursor */
lcd_wrcommand(HD4478OU_CLEAR); /* Clear display */
lcd_waitbusy();
lcd_wrcommand(HD4478OU_RETURN); /* Return home: AC=0 */
lcd_waitbusy();
/* Entry Mode Set:
*
* - Increment address by one,
* - Shift cursor to right (display is not shifted)
*/
lcd_wrcommand(HD4478OU_INPUT | HD4478OU_INPUT_INCR);
/* Register the LCD device driver */
ret = register_driver("/dev/lcd1602", &g_lcdops, 0644, &g_lcd1602);
g_lcd1602.initialized = true;
}
return ret;
}
