CCS C Software and Maintenance Offers
FAQFAQ   FAQForum Help   FAQOfficial CCS Support   SearchSearch  RegisterRegister 

ProfileProfile   Log in to check your private messagesLog in to check your private messages   Log inLog in 

CCS does not monitor this forum on a regular basis.

Please do not post bug reports on this forum. Send them to CCS Technical Support

PIC16F887 + 128x160 LCD

 
Post new topic   Reply to topic    CCS Forum Index -> General CCS C Discussion
View previous topic :: View next topic  
Author Message
Alison



Joined: 30 Aug 2011
Posts: 5
Location: France

View user's profile Send private message MSN Messenger

PIC16F887 + 128x160 LCD
PostPosted: Tue Aug 30, 2011 4:46 am     Reply with quote

Hello guys, I use the PIC16F887 and a 128x160 LCD http://www.newhavendisplay.com/index.php?main_page=product_info&cPath=1_589&products_id=2214

I found the LCD's program on the constructor website :
Code:
/*****************************************************/
/*
NHD-1-8-128160ZF.c
Program for writing to Newhaven Display 1.8" TFT

(c)2009 Curt Lagerstam - Newhaven Display International, Inc.

    This program is free software; you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation; either version 2 of the License, or
   (at your option) any later version.

   This program 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 General Public License for more details.
*/
/*****************************************************/
#include <REG52.H>
#include "picture.h"
/*****************************************************/
#define CS  PIN_B0                     //Chip select
#define RS  PIN_B1                     //Data/Instruction Register select
#define WR1  PIN_B2                  //Write
#define RD1  PIN_B3                 //Read
#define RESET  PIN_B4                  //Reset
/*****************************************************/
void delay(unsigned int n)            //Delay subroutine
{
   unsigned int i,j;
   for (i=0;i<n;i++)
        for (j=0;j<350;j++)
           {;}
}
/*****************************************************/
void data_out(unsigned char i) //Data Output 8-bit Bus Interface
{
   output_high(RS);                    //Data register
   output_high(RD1);                     //Read disable
   output_low(WR1);                     //Write enable
   P1  = i;                     //put byte on port 1
   //nop
   output_high(WR1);                     //Clock in data
}
void comm_out(unsigned char j) //Command Output 8-bit Bus Interface
{
   output_low(RS);                     //Instruction register
   output_high(RD1);                     //Read disable
   output_low(WR1);                    //Write enable
   P1 = j;                        //put byte on port 1
   //nop
   output_high(WR1);                     //Clock in data
}

/*****************************************************/
void Fulldisplay(unsigned char d1,unsigned char d2)//Fill display with RGB color
{
   int i,j;
   output_high(RS);                         //Data register
   for(i=0;i<160;i++)                //160 lines
    {
       for(j=0;j<128;j++)            //128pixels/line
          {
              P1 = d1;            //high 8bits
                   output_low(WR1);
            //nop
            output_high(WR1);            //clock in data
            P1 = d2;            //low 8 bits
                   output_low(WR1);
            //nop
            output_high(WR1);            //clock in data
          }
    }
}
/*****************************************************/
void dispPic(unsigned char *lcd_string)   //show 16bpp bitmap, 128x107pixels
{
   int i,j;
   output_high(RS);                         //Data register

    for(i=0;i<26;i++)                 //MAY REMOVE THIS LOOP - write 26 lines of black pixels
    {
       for(j=0;j<256;j++)             //256bytes = 128pixels/line
          {
                   P1 = 0x00;
            output_low(WR1);
            //nop
            output_high(WR1);
          }
    }
   for(i=0;i<107;i++)                 //MAY CHANGE TO i<160 - write 107 lines of picture data
         {
      lcd_string += (112);         //MAY REMOVE -
                              //my picture data is for 240pixels/line, skip first 56bytes
           for(j=0;j<128;j++)            //Write 128pixels/line
               {
                  P1 = *lcd_string;//put high 8bits on port 1
                  output_low(WR1);
                  //nop     
                  output_high(WR1);      //Clock in data
                  P1 = *(++lcd_string);//put low 8bits on port 1
                  output_low(WR1);
                  //nop     
                  output_high(WR1);      //Clock in data
                  lcd_string++;   //point to next byte of picture data
              }
      lcd_string += (112);         //MAY REMOVE -
                              //my picture data is for 240pixels/line, skip last 56bytes also
         }
   for(i=0;i<27;i++)                 //MAY REMOVE THIS LOOP - write 27 lines of black pixels
    {
       for(j=0;j<256;j++)             //256bytes = 128pixels/line
          {
                   P1 = 0x00;
            output_low(WR1);
            //nop
            output_high(WR1);
          }
    }
}
/****************************************************/
void displayQuads()   //split the display into quadrants of different colors
{
   int i,j;
   output_high(RS);                         //Data register
    for(i=0;i<80;i++){               //80 lines tall               
    for(j=0;j<64;j++){               //64 pixels wide
       P1 = 0x00;
      output_low(WR1);
      //nop
      output_high(WR1);
      P1 = 0x1F;                  //0x00,0x1F = Blue
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    for(j=0;j<64;j++){                 //64 pixels wide
       P1 = 0xF8;
      output_low(WR1);
      //nop
      output_high(WR1);
      P1 = 0x00;                  //0xF8,0x00 = Red
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    }
   for(i=0;i<80;i++){               //80 lines tall
    for(j=0;j<64;j++){               //64 pixels wide
       P1 = 0xFF;
      output_low(WR1);
      //nop
      output_high(WR1);
      P1 = 0xE0;                  //0xFF,0xE0 = Yellow
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    for(j=0;j<64;j++){                  //64 pixels wide
       P1 = 0x07;
      output_low(WR1);
      //nop
      output_high(WR1);
      P1 = 0xE0;                  //0x07,0xE0 = Green
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    }
}
/****************************************************
*           Initialization For ILI9163              *
*****************************************************/
void resetLCD()
{
   output_low(RESET);
   delay(100);
   output_high(RESET);
   delay(100);
}
void init_LCD()
{
output_low(CS);                              //Chip Select = Active
comm_out(0x11);                      //exit sleep mode
delay(100);
comm_out(0x26); data_out(0x04);            //set gamma curve 3
comm_out(0xF2); data_out(0x00);            //gamma adjustment enabled
comm_out(0xB1); data_out(0x0A);   data_out(0x14);   //frame rate
comm_out(0xC0); data_out(0x0A);   data_out(0x00);   //power control 1
comm_out(0xC1); data_out(0x02);            //power control 2
comm_out(0xC5); data_out(0x2F);   data_out(0x3E);   //VCOM control 1
comm_out(0xC7); data_out(0x40);            //VCOM offset control
comm_out(0x2A);                        //column address set
data_out(0x00);   
data_out(0x00);                        //start column 0x0000
data_out(0x00);
data_out(0x7F);                        //end column 0x007F = 127
comm_out(0x2B);                        //page address set
data_out(0x00);
data_out(0x00);                        //start line 0x0000
data_out(0x00);
data_out(0x9F);                      //end line 0x009F = 159
comm_out(0x36); data_out(0xC0);            //Memory access control
comm_out(0x3A); data_out(0xC5);            //Pixel format = 16bit/pixel
comm_out(0x29);                        //display on
comm_out(0x2C);            //write to frame memory(begin writing data)
}
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
int main(void)
{
P1 = 0;
resetLCD();
init_LCD();
while(1)                         //continue
{
   displayQuads();                     //color quadrants
   delay(2000);
   Fulldisplay(0xF8,0x00);              //Red
   delay(1500);
   Fulldisplay(0x07,0xE0);            //Green
   delay(1500);
   Fulldisplay(0x00,0x1F);            //Blue
   delay(1500);
   Fulldisplay(0xFF,0xFF);            //White
   delay(1500);
   Fulldisplay(0x00,0x00);            //Black
   delay(1500);
   dispPic(picture);                  //16bpp bitmap
   delay(2000);
}
}


But I don't understand some instructions :
Code:
#include <REG52.H>
#include "picture.h"

and
Code:
P1 = j;                        //put byte on port 1
P1 = d1;            //high 8bits
P1 = 0xF8;

I need your help to translate this piece of code to CCS code
Thanks
temtronic



Joined: 01 Jul 2010
Posts: 9241
Location: Greensville,Ontario

View user's profile Send private message

PostPosted: Tue Aug 30, 2011 5:05 am     Reply with quote

ok...
#include <REG52.H>
#include "picture.h"

these are 'header' files. They contain specific code that is required for the 'main program to run.Typically it will contain the I/O pin designations(what pin does what),data specific to this PIC,default varibles(true=1, flase=0),etc.
I suspect the second one to be a test picture to confirm the program is running correctly, the first may contain setup details.
***

P1 = j; //put byte on port 1
P1 = d1; //high 8bits
P1 = 0xF8;

These statements send 8 bit data to PORTA of the PIC, IF we assume that P1 has been defined as being memory location 0x05! If P1 was defined as 6, all data would go to PORT B.
If j was equal to 0xF0 then bits 7,6,5,4 would be high, bits 3,2,1,0 would be set low.

If you insert this line near the beginning of the program..say just after the 'defines' section

#byte P1 = 5

then
P1=J;

would send the data held in variable J to the PIC port A.

hth
jay
Alison



Joined: 30 Aug 2011
Posts: 5
Location: France

View user's profile Send private message MSN Messenger

PostPosted: Tue Aug 30, 2011 6:29 am     Reply with quote

Thank you for your answer temtronic, you helped me a lot !

But I have one more problem : The header file #include <REG52.H> isn't in the CCS library so, I searched on the web and I found that : http://www.keil.com/dd/docs/c51/reg52.h

Unfortunately I don't understand this programming language...
Is anybody knows where I can find this header file in CCS language?
RF_Developer



Joined: 07 Feb 2011
Posts: 839

View user's profile Send private message

PostPosted: Tue Aug 30, 2011 8:40 am     Reply with quote

Alison wrote:
But I have one more problem : The header file #include <REG52.H> isn't in the CCS library so, I searched on the web and I found that : http://www.keil.com/dd/docs/c51/reg52.h
...Is anybody knows where I can find this header file in CCS language?


That file is a processor specific header for the Intel 80C52/80C32 8051 derived microcontrollers. The equivalent in CCS is the 16F887.h file that's already included in your code. REG52.h does explain the
Code:
P1 = j;                        //put byte on port 1
P1 = d1;            //high 8bits
P1 = 0xF8;"

code. P1 is a port defined in the file. You have to replace "P1" and everything like it in the code, i.e. those defined as sfr, with the ports you are using in your hardware. The sbit definitions map individual bits of the ports. You will have to translate these into the equivalent on your hardware.

I notice you, or someone else, has commented out all the nops in the code. These nops would have added no-operation instructions to ensure correct timing of the hardware signals. Depending on the speed of your PIC and the speed at which the original processor will have run, you may need to carefully modify these timing critical delays to match the display hardware. Look at the data sheets very carefully! No operations may not do "anything" but what they actually do is stall the processor for one instruction period, giving a short but known time delay.

RF Developer
Alison



Joined: 30 Aug 2011
Posts: 5
Location: France

View user's profile Send private message MSN Messenger

PostPosted: Wed Aug 31, 2011 4:07 am     Reply with quote

HI!
This code is the original program that I found on the constructor's website :
Code:
#include <REG52.H>
#include "picture.h"
/*****************************************************/
sbit CS = P3^0;                     //Chip select
sbit RS = P3^7;                     //Data/Instruction Register select
sbit WR1 = P3^4;                  //Write
sbit RD1 = P3^6;                  //Read
sbit RESET = P3^1;                  //Reset
/*****************************************************/
void delay(unsigned int n)            //Delay subroutine
{
   unsigned int i,j;
   for (i=0;i<n;i++)
        for (j=0;j<350;j++)
           {;}
}
/*****************************************************/
void data_out(unsigned char i) //Data Output 8-bit Bus Interface
{
   RS  = 1;                     //Data register
   RD1  = 1;                     //Read disable
   WR1  = 0;                     //Write enable
   P1  = i;                     //put byte on port 1
   //nop
   WR1  = 1;                     //Clock in data
}
void comm_out(unsigned char j) //Command Output 8-bit Bus Interface
{
   RS  = 0;                     //Instruction register
   RD1  = 1;                     //Read disable
   WR1  = 0;                     //Write enable
   P1 = j;                        //put byte on port 1
   //nop
   WR1  = 1;                     //Clock in data
}

/*****************************************************/
void Fulldisplay(unsigned char d1,unsigned char d2)//Fill display with RGB color
{
   int i,j;
   RS = 1;                         //Data register
   for(i=0;i<160;i++)                //160 lines
    {
       for(j=0;j<128;j++)            //128pixels/line
          {
              P1 = d1;            //high 8bits
                   WR1 = 0;
            //nop
            WR1 = 1;            //clock in data
            P1 = d2;            //low 8 bits
                   WR1 = 0;
            //nop
            WR1 = 1;            //clock in data
          }
    }
}
/*****************************************************/
void dispPic(unsigned char *lcd_string)   //show 16bpp bitmap, 128x107pixels
{
   int i,j;
   RS = 1;                         //Data register

    for(i=0;i<26;i++)                 //MAY REMOVE THIS LOOP - write 26 lines of black pixels
    {
       for(j=0;j<256;j++)             //256bytes = 128pixels/line
          {
                   P1 = 0x00;
            WR1 = 0;
            //nop
            WR1 = 1;
          }
    }
   for(i=0;i<107;i++)                 //MAY CHANGE TO i<160 - write 107 lines of picture data
         {
      lcd_string += (112);         //MAY REMOVE -
                              //my picture data is for 240pixels/line, skip first 56bytes
           for(j=0;j<128;j++)            //Write 128pixels/line
               {
                  P1 = *lcd_string;//put high 8bits on port 1
                  WR1 = 0;
                  //nop      
                  WR1 = 1;      //Clock in data
                  P1 = *(++lcd_string);//put low 8bits on port 1
                  WR1 = 0;
                  //nop      
                  WR1 = 1;      //Clock in data
                  lcd_string++;   //point to next byte of picture data
              }
      lcd_string += (112);         //MAY REMOVE -
                              //my picture data is for 240pixels/line, skip last 56bytes also
         }
   for(i=0;i<27;i++)                 //MAY REMOVE THIS LOOP - write 27 lines of black pixels
    {
       for(j=0;j<256;j++)             //256bytes = 128pixels/line
          {
                   P1 = 0x00;
            WR1 = 0;
            //nop
            WR1 = 1;
          }
    }
}
/****************************************************/
void displayQuads()   //split the display into quadrants of different colors
{
   int i,j;
   RS = 1;                         //Data register
    for(i=0;i<80;i++){               //80 lines tall               
    for(j=0;j<64;j++){               //64 pixels wide
       P1 = 0x00;
      WR1 = 0;
      //nop
      WR1 = 1;
      P1 = 0x1F;                  //0x00,0x1F = Blue
      WR1 = 0;
      //nop
      WR1 = 1;
    }
    for(j=0;j<64;j++){                 //64 pixels wide
       P1 = 0xF8;
      WR1 = 0;
      //nop
      WR1 = 1;
      P1 = 0x00;                  //0xF8,0x00 = Red
      WR1 = 0;
      //nop
      WR1 = 1;
    }
    }
   for(i=0;i<80;i++){               //80 lines tall
    for(j=0;j<64;j++){               //64 pixels wide
       P1 = 0xFF;
      WR1 = 0;
      //nop
      WR1 = 1;
      P1 = 0xE0;                  //0xFF,0xE0 = Yellow
      WR1 = 0;
      //nop
      WR1 = 1;
    }
    for(j=0;j<64;j++){                  //64 pixels wide
       P1 = 0x07;
      WR1 = 0;
      //nop
      WR1 = 1;
      P1 = 0xE0;                  //0x07,0xE0 = Green
      WR1 = 0;
      //nop
      WR1 = 1;
    }
    }
}
/****************************************************
*           Initialization For ILI9163              *
*****************************************************/
void resetLCD()
{
   RESET = 0;
   delay(100);
   RESET = 1;
   delay(100);
}
void init_LCD()
{
CS = 0;                              //Chip Select = Active
comm_out(0x11);                      //exit sleep mode
delay(100);
comm_out(0x26); data_out(0x04);            //set gamma curve 3
comm_out(0xF2); data_out(0x00);            //gamma adjustment enabled
comm_out(0xB1); data_out(0x0A);   data_out(0x14);   //frame rate
comm_out(0xC0); data_out(0x0A);   data_out(0x00);   //power control 1
comm_out(0xC1); data_out(0x02);            //power control 2
comm_out(0xC5); data_out(0x2F);   data_out(0x3E);   //VCOM control 1
comm_out(0xC7); data_out(0x40);            //VCOM offset control
comm_out(0x2A);                        //column address set
data_out(0x00);   
data_out(0x00);                        //start column 0x0000
data_out(0x00);
data_out(0x7F);                        //end column 0x007F = 127
comm_out(0x2B);                        //page address set
data_out(0x00);
data_out(0x00);                        //start line 0x0000
data_out(0x00);
data_out(0x9F);                      //end line 0x009F = 159
comm_out(0x36); data_out(0xC0);            //Memory access control
comm_out(0x3A); data_out(0xC5);            //Pixel format = 16bit/pixel
comm_out(0x29);                        //display on
comm_out(0x2C);            //write to frame memory(begin writing data)
}
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
int main(void)
{
P1 = 0;
resetLCD();
init_LCD();
while(1)                         //continue
{
   displayQuads();                     //color quadrants
   delay(2000);
   Fulldisplay(0xF8,0x00);              //Red
   delay(1500);
   Fulldisplay(0x07,0xE0);            //Green
   delay(1500);
   Fulldisplay(0x00,0x1F);            //Blue
   delay(1500);
   Fulldisplay(0xFF,0xFF);            //White
   delay(1500);
   Fulldisplay(0x00,0x00);            //Black
   delay(1500);
   dispPic(picture);                  //16bpp bitmap
   delay(2000);
}
}





And this code is the program that I made thanks to you :

Code:
#include <16F887.h>
#FUSES HS,NOWDT
#use delay (clock=8000000)
#include <picture.h>

#define CS   PIN_A0                  //Chip select
#define RS   PIN_A1                  //Data/Instruction Register select
#define WR1  PIN_A2                  //Write
#define RD1  PIN_A3                  //Read
#define RESET  PIN_A4                //Reset

/*****************************************************/
void delay(unsigned int n)            //Delay subroutine
{
   unsigned int i,j;
   for (i=0;i<n;i++)
        for (j=0;j<350;j++)
           {;}
}
/*****************************************************/
void data_out(unsigned char i) //Data Output 8-bit Bus Interface
{
   output_high(RS);                    //Data register
   output_high(RD1);                     //Read disable
   output_low(WR1);                     //Write enable
   output_B(i);                     //put byte on port 1
   //nop
   output_high(WR1);                     //Clock in data
}
void comm_out(unsigned char j) //Command Output 8-bit Bus Interface
{
   output_low(RS);                     //Instruction register
   output_high(RD1);                     //Read disable
   output_low(WR1);                    //Write enable
   output_B(j);                        //put byte on port 1
   //nop
   output_high(WR1);                     //Clock in data
}

/*****************************************************/
void Fulldisplay(unsigned char d1,unsigned char d2)//Fill display with RGB color
{
   int i,j;
   output_high(RS);                         //Data register
   for(i=0;i<160;i++)                //160 lines
    {
       for(j=0;j<128;j++)            //128pixels/line
          {
              output_B(d1);            //high 8bits
                   output_low(WR1);
            //nop
            output_high(WR1);            //clock in data
            output_B(d2);            //low 8 bits
                   output_low(WR1);
            //nop
            output_high(WR1);            //clock in data
          }
    }
}
/*****************************************************/
void dispPic(unsigned char *lcd_string)   //show 16bpp bitmap, 128x107pixels
{
   int i,j;
   output_high(RS);                         //Data register

    for(i=0;i<26;i++)                 //MAY REMOVE THIS LOOP - write 26 lines of black pixels
    {
       for(j=0;j<256;j++)             //256bytes = 128pixels/line
          {
                   output_B(0x00);
            output_low(WR1);
            //nop
            output_high(WR1);
          }
    }
   for(i=0;i<107;i++)                 //MAY CHANGE TO i<160 - write 107 lines of picture data
         {
      lcd_string += (112);         //MAY REMOVE -
                              //my picture data is for 240pixels/line, skip first 56bytes
           for(j=0;j<128;j++)            //Write 128pixels/line
               {
//                  P1 = *lcd_string;//put high 8bits on port 1
                  output_low(WR1);
                  //nop     
                  output_high(WR1);      //Clock in data
 //                 P1 = *(++lcd_string);//put low 8bits on port 1
                  output_low(WR1);
                  //nop     
                  output_high(WR1);      //Clock in data
                  lcd_string++;   //point to next byte of picture data
              }
      lcd_string += (112);         //MAY REMOVE -
                              //my picture data is for 240pixels/line, skip last 56bytes also
         }
   for(i=0;i<27;i++)                 //MAY REMOVE THIS LOOP - write 27 lines of black pixels
    {
       for(j=0;j<256;j++)             //256bytes = 128pixels/line
          {
                   output_B(0x00);
            output_low(WR1);
            //nop
            output_high(WR1);
          }
    }
}
/****************************************************/
void displayQuads()   //split the display into quadrants of different colors
{
   int i,j;
   output_high(RS);                         //Data register
    for(i=0;i<80;i++){               //80 lines tall               
    for(j=0;j<64;j++){               //64 pixels wide
       output_B(0x00);
      output_low(WR1);
      //nop
      output_high(WR1);
      output_B(0x1F);                  //0x00,0x1F = Blue
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    for(j=0;j<64;j++){                 //64 pixels wide
       output_B(0xF8);
      output_low(WR1);
      //nop
      output_high(WR1);
      output_B(0x00);                  //0xF8,0x00 = Red
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    }
   for(i=0;i<80;i++){               //80 lines tall
    for(j=0;j<64;j++){               //64 pixels wide
       output_B(0xFF);
      output_low(WR1);
      //nop
      output_high(WR1);
      output_B(0xE0);                  //0xFF,0xE0 = Yellow
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    for(j=0;j<64;j++){                  //64 pixels wide
       output_B(0x07);
      output_low(WR1);
      //nop
      output_high(WR1);
      output_B(0xE0);                  //0x07,0xE0 = Green
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    }
}
/****************************************************
*           Initialization For ILI9163              *
*****************************************************/
void resetLCD()
{
   output_low(RESET);
   delay(100);
   output_high(RESET);
   delay(100);
}
void init_LCD()
{
output_low(CS);                              //Chip Select = Active
comm_out(0x11);                      //exit sleep mode
delay(100);
comm_out(0x26); data_out(0x04);            //set gamma curve 3
comm_out(0xF2); data_out(0x00);            //gamma adjustment enabled
comm_out(0xB1); data_out(0x0A);   data_out(0x14);   //frame rate
comm_out(0xC0); data_out(0x0A);   data_out(0x00);   //power control 1
comm_out(0xC1); data_out(0x02);            //power control 2
comm_out(0xC5); data_out(0x2F);   data_out(0x3E);   //VCOM control 1
comm_out(0xC7); data_out(0x40);            //VCOM offset control
comm_out(0x2A);                        //column address set
data_out(0x00);   
data_out(0x00);                        //start column 0x0000
data_out(0x00);
data_out(0x7F);                        //end column 0x007F = 127
comm_out(0x2B);                        //page address set
data_out(0x00);
data_out(0x00);                        //start line 0x0000
data_out(0x00);
data_out(0x9F);                      //end line 0x009F = 159
comm_out(0x36); data_out(0xC0);            //Memory access control
comm_out(0x3A); data_out(0xC5);            //Pixel format = 16bit/pixel
comm_out(0x29);                        //display on
comm_out(0x2C);            //write to frame memory(begin writing data)
}
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
int main(void)
{
output_B(0x00);
resetLCD();
init_LCD();
while(1)                         //continue
{
   displayQuads();                     //color quadrants
   delay(2000);
   Fulldisplay(0xF8,0x00);              //Red
   delay(1500);
   Fulldisplay(0x07,0xE0);            //Green
   delay(1500);
   Fulldisplay(0x00,0x1F);            //Blue
   delay(1500);
   Fulldisplay(0xFF,0xFF);            //White
   delay(1500);
   Fulldisplay(0x00,0x00);            //Black
   delay(1500);
   dispPic(picture);                  //16bpp bitmap
   delay(2000);
}
}



When I compile the second code with CCS, I have 5 Warnings :
>>> Warning 203 "main.c" Line 17(1,1): Condition always TRUE
>>> Warning 203 "main.c" Line 68(1,1): Condition always TRUE
>>> Warning 203 "main.c" Line 97(1,1): Condition always TRUE
>>> Warning 203 "main.c" Line 205(1,1): Condition always TRUE
>>> Warning 208 "main.c" Line 199(5,9): Function not void and does not return a value MAIN

And 2 errors because of this lines :
Code:
P1 = *lcd_string;//put high 8bits on port 1
P1 = *(++lcd_string);//put low 8bits on port 1


Could you help me again to solve that?
RF_Developer



Joined: 07 Feb 2011
Posts: 839

View user's profile Send private message

PostPosted: Wed Aug 31, 2011 4:37 am     Reply with quote

Code:

void delay(unsigned int n)            //Delay subroutine
{
   unsigned int i,j;
   for (i=0;i<n;i++)
        for (j=0;j<350;j++)         
           {;}
}

The first error is here. In CCS C ints are 8 bit and unsigned by default. So, i and j can hold values from 0 to 255. 350 is more than an unsigned int can hold in CCS C, that's why the condition, j < 350;, is always true as it cannot ever be above 255, let alone 350. The same goes for any ints. This explains most of the warnings. To count to greater than 255 use int16 rather than int.

The final warning tell you that CCS C expects main() not to return any result, i.e. it should be declared as void Main(void).

Also this code may optimise away as it does "nothing", it merely counts. To give delays in CCS C use delay_us(n), delay_ms(n) or delay_cycles(n).

You should use the function output_X(value), where you should replace the X with the port you are actually using. You haven't actually defined what P1 is yet, and that is why you are getting the error.

All this is pretty basic CCS C and if you don't know this stuff then you really need to read the manual carefully! Certainly you cannot expect to get such an interface to hardware going properly unless you understand both the hardware and the firmware environment reasonably well.

RF Developer
Alison



Joined: 30 Aug 2011
Posts: 5
Location: France

View user's profile Send private message MSN Messenger

PostPosted: Thu Sep 01, 2011 8:21 am     Reply with quote

I don't understand why but the program doesn't work correctly. The brightness change for each of this lines :
Code:
   displayQuads();                     //color quadrants
   Fulldisplay(0xF8,0x00);              //Red
   Fulldisplay(0x07,0xE0);            //Green
   Fulldisplay(0x00,0x1F);            //Blue
   Fulldisplay(0xFF,0xFF);            //White
   Fulldisplay(0x00,0x00);            //Black


But there is none colour and no picture on the TFT.
http://mitchhodges.webs.com/Usingatft.html

Code:
#include <16F887.h>
#FUSES HS,NOWDT, NOPROTECT
#use delay (clock=8000000)

#define CS   PIN_A0                  //Chip select
#define RS   PIN_A1                  //Data/Instruction Register select
#define WR1  PIN_A2                  //Write
#define RD1  PIN_A3                  //Read
#define RESET  PIN_A4                //Reset

#include <picture.h>

/*****************************************************/
void delay(unsigned int n)            //Delay subroutine
{
   unsigned int16 i,j;
   for (i=0;i<n;i++)
        for (j=0;j<350;j++)
           {;}
}
/*****************************************************/
void data_out(unsigned char i) //Data Output 8-bit Bus Interface
{
   output_high(RS);                    //Data register
   output_high(RD1);                     //Read disable
   output_low(WR1);                     //Write enable
   output_B(i);                     //put byte on port 1
   //nop
   output_high(WR1);                     //Clock in data
}
void comm_out(unsigned char j) //Command Output 8-bit Bus Interface
{
   output_low(RS);                     //Instruction register
   output_high(RD1);                     //Read disable
   output_low(WR1);                    //Write enable
   output_B(j);                        //put byte on port 1
   //nop
   output_high(WR1);                     //Clock in data
}

/*****************************************************/
void Fulldisplay(unsigned char d1,unsigned char d2)//Fill display with RGB color
{
   int i,j;
   output_high(RS);                         //Data register
   for(i=0;i<160;i++)                //160 lines
    {
       for(j=0;j<128;j++)            //128pixels/line
          {
              output_B(d1);            //high 8bits
                   output_low(WR1);
            //nop
            output_high(WR1);            //clock in data
            output_B(d2);            //low 8 bits
                   output_low(WR1);
            //nop
            output_high(WR1);            //clock in data
          }
    }
}
/*****************************************************/
void dispPic(unsigned char *lcd_string)   //show 16bpp bitmap, 128x107pixels
{
   int16 i,j;
   output_high(RS);                         //Data register

    for(i=0;i<26;i++)                 //MAY REMOVE THIS LOOP - write 26 lines of black pixels
    {
       for(j=0;j<256;j++)             //256bytes = 128pixels/line
          {
            output_B(0x00);
            output_low(WR1);
            //nop
            output_high(WR1);
          }
    }
   for(i=0;i<107;i++)                 //MAY CHANGE TO i<160 - write 107 lines of picture data
         {
      lcd_string += (112);         //MAY REMOVE -
                              //my picture data is for 240pixels/line, skip first 56bytes
           for(j=0;j<128;j++)            //Write 128pixels/line
               {
                 output_B(*lcd_string);//put high 8bits on port 1
                  output_low(WR1);
                  //nop     
                  output_high(WR1);      //Clock in data
                 output_B(*(++lcd_string));//put low 8bits on port 1
                  output_low(WR1);
                  //nop     
                  output_high(WR1);      //Clock in data
                  lcd_string++;   //point to next byte of picture data
              }
      lcd_string += (112);         //MAY REMOVE -
                              //my picture data is for 240pixels/line, skip last 56bytes also
         }
   for(i=0;i<27;i++)                 //MAY REMOVE THIS LOOP - write 27 lines of black pixels
    {
       for(j=0;j<256;j++)             //256bytes = 128pixels/line
          {
                   output_B(0x00);
            output_low(WR1);
            //nop
            output_high(WR1);
          }
    }
}
/****************************************************/
void displayQuads()   //split the display into quadrants of different colors
{
   int i,j;
   output_high(RS);                         //Data register
    for(i=0;i<80;i++){               //80 lines tall               
    for(j=0;j<64;j++){               //64 pixels wide
       output_B(0x00);
      output_low(WR1);
      //nop
      output_high(WR1);
      output_B(0x1F);                  //0x00,0x1F = Blue
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    for(j=0;j<64;j++){                 //64 pixels wide
       output_B(0xF8);
      output_low(WR1);
      //nop
      output_high(WR1);
      output_B(0x00);                  //0xF8,0x00 = Red
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    }
   for(i=0;i<80;i++){               //80 lines tall
    for(j=0;j<64;j++){               //64 pixels wide
       output_B(0xFF);
      output_low(WR1);
      //nop
      output_high(WR1);
      output_B(0xE0);                  //0xFF,0xE0 = Yellow
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    for(j=0;j<64;j++){                  //64 pixels wide
       output_B(0x07);
      output_low(WR1);
      //nop
      output_high(WR1);
      output_B(0xE0);                  //0x07,0xE0 = Green
      output_low(WR1);
      //nop
      output_high(WR1);
    }
    }
}
/****************************************************
*           Initialization For ILI9163              *
*****************************************************/
void resetLCD()
{
   output_low(RESET);
   delay_us(100);    ////////////////////////////////////
   output_high(RESET);
   delay_ms(130); ///////////////////////////100
}
void init_LCD()
{
output_low(CS);                              //Chip Select = Active
comm_out(0x11);                      //exit sleep mode
delay_ms(100);
comm_out(0x26); data_out(0x04);            //set gamma curve 3
comm_out(0xF2); data_out(0x00);            //gamma adjustment enabled
comm_out(0xB1); data_out(0x0A);   data_out(0x14);   //frame rate
comm_out(0xC0); data_out(0x0A);   data_out(0x00);   //power control 1
comm_out(0xC1); data_out(0x02);            //power control 2
comm_out(0xC5); data_out(0x2F);   data_out(0x3E);   //VCOM control 1
comm_out(0xC7); data_out(0x40);            //VCOM offset control
comm_out(0x2A);                        //column address set
data_out(0x00);   
data_out(0x00);                        //start column 0x0000
data_out(0x00);
data_out(0x7F);                        //end column 0x007F = 127
comm_out(0x2B);                        //page address set
data_out(0x00);
data_out(0x00);                        //start line 0x0000
data_out(0x00);
data_out(0x9F);                      //end line 0x009F = 159
comm_out(0x36); data_out(0xC0);            //Memory access control
comm_out(0x3A); data_out(0xC5);            //Pixel format = 16bit/pixel
comm_out(0x29);                        //display on
comm_out(0x2C);            //write to frame memory(begin writing data)
}
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
/*****************************************************/
void main(void)
{
output_B(0x00);
resetLCD();
init_LCD();
while(1)                         //continue
{
   displayQuads();                     //color quadrants
   delay_us(2000);
   Fulldisplay(0xF8,0x00);              //Red
   delay_us(1500);
   Fulldisplay(0x07,0xE0);            //Green
   delay_us(1500);
   Fulldisplay(0x00,0x1F);            //Blue
   delay_us(1500);
   Fulldisplay(0xFF,0xFF);            //White
   delay_us(1500);
   Fulldisplay(0x00,0x00);            //Black
   delay_us(1500);
   dispPic(picture);                  //16bpp bitmap
   delay_us(2000);
}
}
Display posts from previous:   
Post new topic   Reply to topic    CCS Forum Index -> General CCS C Discussion All times are GMT - 6 Hours
Page 1 of 1

 
Jump to:  
You cannot post new topics in this forum
You cannot reply to topics in this forum
You cannot edit your posts in this forum
You cannot delete your posts in this forum
You cannot vote in polls in this forum


Powered by phpBB © 2001, 2005 phpBB Group