/* * lcd.c: * Text-based LCD driver. * This is designed to drive the parallel interface LCD drivers * based in the Hitachi HD44780U controller and compatables. * * Copyright (c) 2012 Gordon Henderson. *********************************************************************** * This file is part of wiringPi: * https://projects.drogon.net/raspberry-pi/wiringpi/ * * wiringPi is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * wiringPi is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with wiringPi. If not, see . *********************************************************************** */ #include #include #include #include #include "wiringPi.h" #include "lcd.h" // Commands #define LCD_CLEAR 0x01 #define LCD_HOME 0x02 #define LCD_ENTRY 0x04 #define LCD_ON_OFF 0x08 #define LCD_CDSHIFT 0x10 #define LCD_FUNC 0x20 #define LCD_CGRAM 0x40 #define LCD_DGRAM 0x80 #define LCD_ENTRY_SH 0x01 #define LCD_ENTRY_ID 0x02 #define LCD_ON_OFF_B 0x01 #define LCD_ON_OFF_C 0x02 #define LCD_ON_OFF_D 0x04 #define LCD_FUNC_F 0x04 #define LCD_FUNC_N 0x08 #define LCD_FUNC_DL 0x10 #define LCD_CDSHIFT_RL 0x04 struct lcdDataStruct { uint8_t bits, rows, cols ; uint8_t rsPin, strbPin ; uint8_t dataPins [8] ; } ; struct lcdDataStruct *lcds [MAX_LCDS] ; /* * strobe: * Toggle the strobe (Really the "E") pin to the device. * According to the docs, data is latched on the falling edge. ********************************************************************************* */ static void strobe (struct lcdDataStruct *lcd) { // Note timing changes for new version of delayMicroseconds () digitalWrite (lcd->strbPin, 1) ; delayMicroseconds (50) ; digitalWrite (lcd->strbPin, 0) ; delayMicroseconds (50) ; } /* * sentDataCmd: * Send an data or command byte to the display. ********************************************************************************* */ static void sendDataCmd (struct lcdDataStruct *lcd, uint8_t data) { uint8_t i, d4 ; if (lcd->bits == 4) { d4 = (data >> 4) & 0x0F; for (i = 0 ; i < 4 ; ++i) { digitalWrite (lcd->dataPins [i], (d4 & 1)) ; d4 >>= 1 ; } strobe (lcd) ; d4 = data & 0x0F ; for (i = 0 ; i < 4 ; ++i) { digitalWrite (lcd->dataPins [i], (d4 & 1)) ; d4 >>= 1 ; } } else { for (i = 0 ; i < 8 ; ++i) { digitalWrite (lcd->dataPins [i], (data & 1)) ; data >>= 1 ; } } strobe (lcd) ; } /* * putCommand: * Send a command byte to the display ********************************************************************************* */ static void putCommand (struct lcdDataStruct *lcd, uint8_t command) { digitalWrite (lcd->rsPin, 0) ; sendDataCmd (lcd, command) ; } static void put4Command (struct lcdDataStruct *lcd, uint8_t command) { uint8_t i ; digitalWrite (lcd->rsPin, 0) ; for (i = 0 ; i < 4 ; ++i) { digitalWrite (lcd->dataPins [i], (command & 1)) ; command >>= 1 ; } strobe (lcd) ; } /* ********************************************************************************* * User Code below here ********************************************************************************* */ /* * lcdHome: lcdClear: * Home the cursor or clear the screen. ********************************************************************************* */ void lcdHome (int fd) { struct lcdDataStruct *lcd = lcds [fd] ; putCommand (lcd, LCD_HOME) ; } void lcdClear (int fd) { struct lcdDataStruct *lcd = lcds [fd] ; putCommand (lcd, LCD_CLEAR) ; } /* * lcdPosition: * Update the position of the cursor on the display ********************************************************************************* */ void lcdPosition (int fd, int x, int y) { static uint8_t rowOff [4] = { 0x00, 0x40, 0x14, 0x54 } ; struct lcdDataStruct *lcd = lcds [fd] ; putCommand (lcd, x + (LCD_DGRAM | rowOff [y])) ; } /* * lcdPutchar: * Send a data byte to be displayed on the display ********************************************************************************* */ void lcdPutchar (int fd, uint8_t data) { struct lcdDataStruct *lcd = lcds [fd] ; digitalWrite (lcd->rsPin, 1) ; sendDataCmd (lcd, data) ; } /* * lcdPuts: * Send a string to be displayed on the display ********************************************************************************* */ void lcdPuts (int fd, char *string) { while (*string) lcdPutchar (fd, *string++) ; } /* * lcdPrintf: * Printf to an LCD display ********************************************************************************* */ void lcdPrintf (int fd, char *message, ...) { va_list argp ; char buffer [1024] ; va_start (argp, message) ; vsnprintf (buffer, 1023, message, argp) ; va_end (argp) ; lcdPuts (fd, buffer) ; } /* * lcdInit: * Take a lot of parameters and initialise the LCD, and return a handle to * that LCD, or -1 if any error. ********************************************************************************* */ int lcdInit (int rows, int cols, int bits, int rs, int strb, int d0, int d1, int d2, int d3, int d4, int d5, int d6, int d7) { static int initialised = 0 ; uint8_t func ; int i ; int lcdFd = -1 ; struct lcdDataStruct *lcd ; if (initialised == 0) { initialised = 1 ; for (i = 0 ; i < MAX_LCDS ; ++i) lcds [i] = NULL ; } // Simple sanity checks if (! ((bits == 4) || (bits == 8))) return -1 ; if ((rows < 0) || (rows > 20)) return -1 ; if ((cols < 0) || (cols > 20)) return -1 ; // Create a new LCD: for (i = 0 ; i < MAX_LCDS ; ++i) { if (lcds [i] == NULL) { lcdFd = i ; break ; } } if (lcdFd == -1) return -1 ; lcd = malloc (sizeof (struct lcdDataStruct)) ; if (lcd == NULL) return -1 ; lcd->rsPin = rs ; lcd->strbPin = strb ; lcd->bits = 8 ; // For now - we'll set it properly later. lcd->rows = rows ; lcd->cols = cols ; lcd->dataPins [0] = d0 ; lcd->dataPins [1] = d1 ; lcd->dataPins [2] = d2 ; lcd->dataPins [3] = d3 ; lcd->dataPins [4] = d4 ; lcd->dataPins [5] = d5 ; lcd->dataPins [6] = d6 ; lcd->dataPins [7] = d7 ; lcds [lcdFd] = lcd ; digitalWrite (lcd->rsPin, 0) ; pinMode (lcd->rsPin, OUTPUT) ; digitalWrite (lcd->strbPin, 0) ; pinMode (lcd->strbPin, OUTPUT) ; for (i = 0 ; i < bits ; ++i) { digitalWrite (lcd->dataPins [i], 0) ; pinMode (lcd->dataPins [i], OUTPUT) ; } delay (35) ; // mS // 4-bit mode? // OK. This is a PIG and it's not at all obvious from the documentation I had, // so I guess some others have worked through either with better documentation // or more trial and error... Anyway here goes: // // It seems that the controller needs to see the FUNC command at least 3 times // consecutively - in 8-bit mode. If you're only using 8-bit mode, then it appears // that you can get away with one func-set, however I'd not rely on it... // // So to set 4-bit mode, you need to send the commands one nibble at a time, // the same three times, but send the command to set it into 8-bit mode those // three times, then send a final 4th command to set it into 4-bit mode, and only // then can you flip the switch for the rest of the library to work in 4-bit // mode which sends the commands as 2 x 4-bit values. if (bits == 4) { func = LCD_FUNC | LCD_FUNC_DL ; // Set 8-bit mode 3 times put4Command (lcd, func >> 4) ; delay (35) ; put4Command (lcd, func >> 4) ; delay (35) ; put4Command (lcd, func >> 4) ; delay (35) ; func = LCD_FUNC ; // 4th set: 4-bit mode put4Command (lcd, func >> 4) ; delay (35) ; lcd->bits = 4 ; } else { func = LCD_FUNC | LCD_FUNC_DL ; putCommand (lcd, func ) ; delay (35) ; putCommand (lcd, func ) ; delay (35) ; putCommand (lcd, func ) ; delay (35) ; } if (lcd->rows > 1) { func |= LCD_FUNC_N ; putCommand (lcd, func) ; delay (35) ; } // Rest of the initialisation sequence putCommand (lcd, LCD_ON_OFF | LCD_ON_OFF_D) ; delay (2) ; putCommand (lcd, LCD_ENTRY | LCD_ENTRY_ID) ; delay (2) ; putCommand (lcd, LCD_CDSHIFT | LCD_CDSHIFT_RL) ; delay (2) ; putCommand (lcd, LCD_CLEAR) ; delay (5) ; return lcdFd ; }