test
A library with drivers for different peripherals on the LPC4088 QuickStart Board or related add-on boards.
Dependencies: FATFileSystem
Fork of
EALib
by 
EmbeddedArtists AB
EaLcdBoard.cpp
- Committer:
- embeddedartists
- Date:
- 2013-09-27
- Revision:
- 2:1c6134c80dc5
- Parent:
- 0:0fdadbc3d852
- Child:
- 4:b32cf4ef45c5
File content as of revision 2:1c6134c80dc5:
#include "mbed.h"
#include "EaLcdBoard.h"
#define LCDB_MAGIC 0xEA01CDAE
#define LCDB_PCA9532_I2C_ADDR (0x64 << 1)
/* PCA9532 registers*/
#define LCDB_PCA9532_INPUT0 0x00
#define LCDB_PCA9532_INPUT1 0x01
#define LCDB_PCA9532_PSC0 0x02
#define LCDB_PCA9532_PWM0 0x03
#define LCDB_PCA9532_PSC1 0x04
#define LCDB_PCA9532_PWM1 0x05
#define LCDB_PCA9532_LS0 0x06
#define LCDB_PCA9532_LS1 0x07
#define LCDB_PCA9532_LS2 0x08
#define LCDB_PCA9532_LS3 0x09
#define LCDB_PCA9532_AUTO_INC 0x10
#define LCDB_LS_MODE_ON 0x01
#define LCDB_LS_MODE_BLINK0 0x02
#define LCDB_LS_MODE_BLINK1 0x03
#define LCDB_CTRL_3V3 0x0001
#define LCDB_CTRL_5V 0x0002
#define LCDB_CTRL_DISP_EN 0x0010
#define LCDB_CTRL_BL_EN 0x0080
#define LCDB_CTRL_BL_C 0x0100
#define LCDB_EEPROM_WP 0x8000
#define LCDB_EEPROM_I2C_ADDR (0x56 << 1)
#define LCDB_EEPROM_PAGE_SIZE 32
#define LCDB_EEPROM_TOTAL_SIZE 8192
/*
* Set which sequence string version that is supported
*/
#define LCDB_SEQ_VER 1
#ifndef MIN
#define MIN(x, y) (((x)<(y))?(x):(y))
#endif
#define EA_LCD_TMP_BUFFER_SZ 256
static char* eaLcdTmpBuffer[EA_LCD_TMP_BUFFER_SZ];
/* Structure containing the parameters for the LCD panel as stored on LCD Board */
/* LCD display types */
typedef enum {
TFT = 0, /* standard TFT */
ADTFT, /* advanced TFT */
HRTFT, /* highly reflective TFT */
MONO_4BIT, /* 4-bit mono */
MONO_8BIT, /* 8-bit mono */
CSTN /* color STN */
} nxp_lcd_panel_t;
typedef struct {
uint8_t h_back_porch; /* Horizontal back porch in clocks */
uint8_t h_front_porch; /* Horizontal front porch in clocks */
uint8_t h_sync_pulse_width; /* HSYNC pulse width in clocks */
uint16_t pixels_per_line; /* Pixels per line (horizontal resolution) */
uint8_t v_back_porch; /* Vertical back porch in clocks */
uint8_t v_front_porch; /* Vertical front porch in clocks */
uint8_t v_sync_pulse_width; /* VSYNC pulse width in clocks */
uint16_t lines_per_panel; /* Lines per panel (vertical resolution) */
uint8_t invert_output_enable; /* Invert output enable, 1 = invert*/
uint8_t invert_panel_clock; /* Invert panel clock, 1 = invert*/
uint8_t invert_hsync; /* Invert HSYNC, 1 = invert */
uint8_t invert_vsync; /* Invert VSYNC, 1 = invert */
uint8_t ac_bias_frequency; /* AC bias frequency in clocks */
uint8_t bits_per_pixel; /* Maximum bits per pixel the display supports */
uint32_t optimal_clock; /* Optimal clock rate (Hz) */
nxp_lcd_panel_t lcd_panel_type; /* LCD panel type */
uint8_t dual_panel; /* Dual panel, 1 = dual panel display */
} nxp_lcd_param_t;
static uint32_t str_to_uint(char* str, uint32_t len);
EaLcdBoard::EaLcdBoard(PinName sda, PinName scl) : _i2c(sda, scl) {
_blink0Shadow = 0;
_blink1Shadow = 0;
_ledStateShadow = 0;
_lcdPwrOn = false;
}
EaLcdBoard::Result EaLcdBoard::open(LcdController::Config* cfg, char* initSeq) {
EaLcdBoard::Result result = Ok;
// load LCD configuration from storage
if (cfg == NULL) {
result = getLcdConfig(&_cfg);
cfg = &_cfg;
}
// load init sequence from storage
if (result == Ok && initSeq == NULL) {
result = getInitSeq((char*)eaLcdTmpBuffer, EA_LCD_TMP_BUFFER_SZ);
initSeq = (char*)eaLcdTmpBuffer;
}
if (result != Ok) {
return result;
}
return parseInitString(initSeq, cfg);
}
EaLcdBoard::Result EaLcdBoard::close() {
int r = 0;
do {
r = lcdCtrl.setPower(false);
if (r != 0) break;
_lcdPwrOn = false;
r = lcdCtrl.close();
} while(0);
if (r != 0) {
return LcdAccessError;
}
return Ok;
}
EaLcdBoard::Result EaLcdBoard::setFrameBuffer(uint32_t address) {
int r = 0;
do {
// begin by powering on the display
if (!_lcdPwrOn) {
r = lcdCtrl.setPower(true);
if (r != 0) break;
_lcdPwrOn = true;
}
// activate specified frame buffer
r = lcdCtrl.setFrameBuffer(address);
if (r != 0) break;
} while(0);
if (r != 0) {
return LcdAccessError;
}
return Ok;
}
EaLcdBoard::Result EaLcdBoard::getLcdConfig(LcdController::Config* cfg) {
store_t h;
nxp_lcd_param_t lcdParam;
getStore(&h);
if (h.magic != LCDB_MAGIC) {
return InvalidStorage;
}
eepromRead((uint8_t*)&lcdParam, h.lcdParamOff,
(h.initOff-h.lcdParamOff));
cfg->horizontalBackPorch = lcdParam.h_back_porch;
cfg->horizontalFrontPorch = lcdParam.h_front_porch;
cfg->hsync = lcdParam.h_sync_pulse_width;
cfg->width = lcdParam.pixels_per_line;
cfg->verticalBackPorch = lcdParam.v_back_porch;
cfg->verticalFrontPorch = lcdParam.v_front_porch;
cfg->vsync = lcdParam.v_sync_pulse_width;
cfg->height = lcdParam.lines_per_panel;
cfg->invertOutputEnable = (lcdParam.invert_output_enable == 1);
cfg->invertPanelClock = (lcdParam.invert_panel_clock == 1);
cfg->invertHsync = (lcdParam.invert_hsync == 1);
cfg->invertVsync = (lcdParam.invert_vsync == 1);
cfg->acBias = lcdParam.ac_bias_frequency;
cfg->bpp = LcdController::Bpp_16_565;
cfg->optimalClock = lcdParam.optimal_clock;
cfg->panelType = (LcdController::LcdPanel)lcdParam.lcd_panel_type;
cfg->dualPanel = (lcdParam.dual_panel == 1);
return Ok;
}
EaLcdBoard::Result EaLcdBoard::getDisplayName(char* buf, int len) {
store_t h;
getStore(&h);
if (h.magic != LCDB_MAGIC) {
return InvalidStorage;
}
if (len < NameBufferSize) {
return BufferTooSmall;
}
strncpy(buf, (char*)h.lcd_name, NameBufferSize);
return Ok;
}
EaLcdBoard::Result EaLcdBoard::getDisplayMfg(char* buf, int len) {
store_t h;
getStore(&h);
if (h.magic != LCDB_MAGIC) {
return InvalidStorage;
}
if (len < NameBufferSize) {
return BufferTooSmall;
}
strncpy(buf, (char*)h.lcd_mfg, NameBufferSize);
return Ok;
}
EaLcdBoard::Result EaLcdBoard::getInitSeq(char* buf, int len) {
store_t h;
getStore(&h);
if (h.magic != LCDB_MAGIC) {
return InvalidStorage;
}
if ((h.pdOff-h.initOff) > len) {
return BufferTooSmall;
}
eepromRead((uint8_t*)buf, h.initOff,
(h.pdOff-h.initOff));
return Ok;
}
EaLcdBoard::Result EaLcdBoard::getPowerDownSeq(char* buf, int len) {
store_t h;
getStore(&h);
if (h.magic != LCDB_MAGIC) {
return InvalidStorage;
}
if ((h.tsOff-h.pdOff) > len) {
return BufferTooSmall;
}
eepromRead((uint8_t*)buf, h.pdOff,
(h.tsOff-h.pdOff));
return Ok;
}
EaLcdBoard::Result EaLcdBoard::getStore(store_t* store) {
int num = 0;
if (store == NULL) return InvalidArgument;
num = eepromRead((uint8_t*)store, 0, sizeof(store_t));
if (num < (int)sizeof(store_t)) {
return InvalidStorage;
}
return Ok;
}
// ###########################
// An EEPROM is used for persistent storage
// ###########################
int EaLcdBoard::eepromRead(uint8_t* buf, uint16_t offset, uint16_t len) {
int i = 0;
char off[2];
if (len > LCDB_EEPROM_TOTAL_SIZE || offset+len > LCDB_EEPROM_TOTAL_SIZE) {
return -1;
}
off[0] = ((offset >> 8) & 0xff);
off[1] = (offset & 0xff);
_i2c.write(LCDB_EEPROM_I2C_ADDR, (char*)off, 2);
for ( i = 0; i < 0x2000; i++);
_i2c.read(LCDB_EEPROM_I2C_ADDR, (char*)buf, len);
return len;
}
int EaLcdBoard::eepromWrite(uint8_t* buf, uint16_t offset, uint16_t len) {
int16_t written = 0;
uint16_t wLen = 0;
uint16_t off = offset;
uint8_t tmp[LCDB_EEPROM_PAGE_SIZE+2];
if (len > LCDB_EEPROM_TOTAL_SIZE || offset+len > LCDB_EEPROM_TOTAL_SIZE) {
return -1;
}
wLen = LCDB_EEPROM_PAGE_SIZE - (off % LCDB_EEPROM_PAGE_SIZE);
wLen = MIN(wLen, len);
while (len) {
tmp[0] = ((off >> 8) & 0xff);
tmp[1] = (off & 0xff);
memcpy(&tmp[2], (void*)&buf[written], wLen);
_i2c.write(LCDB_EEPROM_I2C_ADDR, (char*)tmp, wLen+2);
// delay to wait for a write cycle
//eepromDelay();
wait_ms(1);
len -= wLen;
written += wLen;
off += wLen;
wLen = MIN(LCDB_EEPROM_PAGE_SIZE, len);
}
return written;
}
// ###########################
// string parsing (initialization and power down strings)
// ###########################
EaLcdBoard::Result EaLcdBoard::parseInitString(char* str, LcdController::Config* cfg) {
char* c = NULL;
uint32_t len = 0;
Result result = Ok;
if (str == NULL) {
return InvalidCommandString;
}
while(*str != '\0') {
// skip whitespaces
while(*str == ' ') {
str++;
}
c = str;
// find end of command
while(*str != ',' && *str != '\0') {
str++;
}
len = (str-c);
if (*str == ',') {
str++;
}
switch (*c++) {
case 'v':
result = checkVersion(c, len-1);
break;
// sequence control command (pca9532)
case 'c':
execSeqCtrl(c, len-1);
break;
// delay
case 'd':
execDelay(c, len-1);
break;
// open lcd (init LCD controller)
case 'o':
if (cfg != NULL) {
if (lcdCtrl.open(cfg) != 0) {
result = LcdAccessError;
}
}
else {
result = InvalidArgument;
}
break;
}
if (result != Ok) {
break;
}
}
return result;
}
EaLcdBoard::Result EaLcdBoard::checkVersion(char* v, uint32_t len) {
uint32_t ver = str_to_uint(v, len);
if (ver > LCDB_SEQ_VER) {
return VersionNotSupported;
}
return Ok;
}
EaLcdBoard::Result EaLcdBoard::execDelay(char* del, uint32_t len) {
wait_ms(str_to_uint(del, len));
return Ok;
}
EaLcdBoard::Result EaLcdBoard::execSeqCtrl(char* cmd, uint32_t len) {
switch (*cmd++) {
// display enable
case 'd':
setDisplayEnableSignal(*cmd == '1');
break;
// backlight contrast
case 'c':
setBacklightContrast(str_to_uint(cmd, len));
break;
// 3v3 enable
case '3':
set3V3Signal(*cmd == '1');
break;
// 5v enable
case '5':
set5VSignal(*cmd == '1');
break;
}
return Ok;
}
// ###########################
// PCA9532 is used as a control inteface to the display.
// voltages can be turned on/off and backlight can be controlled.
// ###########################
// Helper function to set LED states
void EaLcdBoard::setLsStates(uint16_t states, uint8_t* ls, uint8_t mode)
{
#define IS_LED_SET(bit, x) ( ( ((x) & (bit)) != 0 ) ? 1 : 0 )
int i = 0;
for (i = 0; i < 4; i++) {
ls[i] |= ( (IS_LED_SET(0x0001, states)*mode << 0)
| (IS_LED_SET(0x0002, states)*mode << 2)
| (IS_LED_SET(0x0004, states)*mode << 4)
| (IS_LED_SET(0x0008, states)*mode << 6) );
states >>= 4;
}
}
void EaLcdBoard::setLeds(void)
{
uint8_t buf[5];
uint8_t ls[4] = {0,0,0,0};
uint16_t states = _ledStateShadow;
// LEDs in On/Off state
setLsStates(states, ls, LCDB_LS_MODE_ON);
// set the LEDs that should blink
setLsStates(_blink0Shadow, ls, LCDB_LS_MODE_BLINK0);
setLsStates(_blink1Shadow, ls, LCDB_LS_MODE_BLINK1);
buf[0] = LCDB_PCA9532_LS0 | LCDB_PCA9532_AUTO_INC;
buf[1] = ls[0];
buf[2] = ls[1];
buf[3] = ls[2];
buf[4] = ls[3];
_i2c.write(LCDB_PCA9532_I2C_ADDR, (char*)buf, 5);
}
void EaLcdBoard::pca9532_setLeds (uint16_t ledOnMask, uint16_t ledOffMask)
{
// turn off leds
_ledStateShadow &= (~(ledOffMask) & 0xffff);
// ledOnMask has priority over ledOffMask
_ledStateShadow |= ledOnMask;
// turn off blinking
_blink0Shadow &= (~(ledOffMask) & 0xffff);
_blink1Shadow &= (~(ledOffMask) & 0xffff);
setLeds();
}
void EaLcdBoard::pca9532_setBlink0Period(uint8_t period)
{
uint8_t buf[2];
buf[0] = LCDB_PCA9532_PSC0;
buf[1] = period;
_i2c.write(LCDB_PCA9532_I2C_ADDR, (char*)buf, 2);
}
void EaLcdBoard::pca9532_setBlink0Duty(uint8_t duty)
{
uint8_t buf[2];
uint32_t tmp = duty;
if (tmp > 100) {
tmp = 100;
}
tmp = (255 * tmp)/100;
buf[0] = LCDB_PCA9532_PWM0;
buf[1] = tmp;
_i2c.write(LCDB_PCA9532_I2C_ADDR, (char*)buf, 2);
}
void EaLcdBoard::pca9532_setBlink0Leds(uint16_t ledMask)
{
_blink0Shadow |= ledMask;
setLeds();
}
void EaLcdBoard::set3V3Signal(bool enabled) {
if (enabled) {
pca9532_setLeds(LCDB_CTRL_3V3, 0);
} else {
pca9532_setLeds(0, LCDB_CTRL_3V3);
}
}
void EaLcdBoard::set5VSignal(bool enabled) {
if (enabled) {
pca9532_setLeds(LCDB_CTRL_5V, 0);
} else {
pca9532_setLeds(0, LCDB_CTRL_5V);
}
}
void EaLcdBoard::setDisplayEnableSignal(bool enabled) {
if (!enabled) {
pca9532_setLeds(LCDB_CTRL_DISP_EN, 0);
} else {
pca9532_setLeds(0, LCDB_CTRL_DISP_EN);
}
}
void EaLcdBoard::setBacklightContrast(uint32_t value) {
if (value > 100) return;
pca9532_setBlink0Duty(100-value);
pca9532_setBlink0Period(0);
pca9532_setBlink0Leds(LCDB_CTRL_BL_C);
}
// convert string to integer
static uint32_t str_to_uint(char* str, uint32_t len)
{
uint32_t val = 0;
while(len > 0 && *str <= '9' && *str >= '0') {
val = (val * 10) + (*str - '0');
str++;
len--;
}
return val;
}