Difference between revisions of "Template:LCD Module FBCP Transplant"
Line 44: | Line 44: | ||
sudo reboot | sudo reboot | ||
− | ===Compile and Run=== | + | ====Compile and Run==== |
<pre> | <pre> | ||
mkdir build | mkdir build |
Revision as of 02:01, 17 May 2022
FBCP Transplant
Framebuffer uses a video output device to drive a video display device from a memory buffer containing complete frame data. Simply put, a memory area is used to store the display content, and the display content can be changed by changing the data in the memory.
There is an open source project on github: fbcp-ili9341. Compared with other fbcp projects, this project uses partial refresh and DMA to achieve a speed of up to 60fps
Download
sudo apt-get install cmake -y cd ~ wget https://www.waveshare.net/w/upload/1/18/Waveshare_fbcp.zip unzip Waveshare_fbcp.zip cd Waveshare_fbcp/ sudo chmod +x ./shell/*
Method one:use a script (recommended)
Here we have written several scripts that allow users to quickly use fbcp and run corresponding commands according to their own screen
If you use a script, you can ignore the following if you don't need to modify it
Note: The script will replace the corresponding /boot/config.txt and /etc/rc.local and restart, if the user needs, please back up the relevant files in advance
#0.96inch LCD Module sudo ./shell/waveshare-0inch96 #1.14inch LCD Module sudo ./shell/waveshare-1inch14 #1.3inch LCD Module sudo ./shell/waveshare-1inch3 #1.44inch LCD Module sudo ./shell/waveshare-1inch44 #1.54inch LCD Module sudo ./shell/waveshare-1inch54 #1.8inch LCD Module sudo ./shell/waveshare-1inch8 #2inch LCD Module sudo ./shell/waveshare-2inch #2.4inch LCD Module sudo ./shell/waveshare-2inch4
Method 2: Manual configuration
Environment configuration
Raspberry Pi's vc4-kms-v3d will cause fbcp to fail, so we need to close vc4-kms-v3d before installing in fbcp
sudo nano /boot/config.txt
You can block the sentences corresponding to the following figure
Then you need to restart
sudo reboot
Compile and Run
mkdir build cd build cmake [options] .. sudo make -j sudo ./fbcp
Replace the above cmake [options] .. according to the LCD Module you are using.
#0.96inch LCD Module sudo cmake -DSPI_BUS_CLOCK_DIVISOR=20 -DWAVESHARE_0INCH96_LCD=ON -DBACKLIGHT_CONTROL=ON -DSTATISTICS=0 .. #1.14inch LCD Module sudo cmake -DSPI_BUS_CLOCK_DIVISOR=20 -DWAVESHARE_1INCH14_LCD=ON -DBACKLIGHT_CONTROL=ON -DSTATISTICS=0 .. #1.3inch LCD Module sudo cmake -DSPI_BUS_CLOCK_DIVISOR=20 -DWAVESHARE_1INCH3_LCD=ON -DBACKLIGHT_CONTROL=ON -DSTATISTICS=0 .. #1.54inch LCD Module sudo cmake -DSPI_BUS_CLOCK_DIVISOR=20 -DWAVESHARE_1INCH54_LCD=ON -DBACKLIGHT_CONTROL=ON -DSTATISTICS=0 .. #1.8inch LCD Module sudo cmake -DSPI_BUS_CLOCK_DIVISOR=20 -DWAVESHARE_1INCH8_LCD=ON -DBACKLIGHT_CONTROL=ON -DSTATISTICS=0 .. #2inch LCD Module sudo cmake -DSPI_BUS_CLOCK_DIVISOR=20 -DWAVESHARE_2INCH_LCD=ON -DBACKLIGHT_CONTROL=ON -DSTATISTICS=0 .. #2.4inch LCD Module sudo cmake -DSPI_BUS_CLOCK_DIVISOR=20 -DWAVESHARE_2INCH4_LCD=ON -DBACKLIGHT_CONTROL=ON -DSTATISTICS=0 ..
Auto-start when Power on
sudo cp ~/waveshare_fbcp-main/build/fbcp /usr/local/bin/fbcp sudo nano /etc/rc.local
And then add fbcp& before exit 0, Note that you must add "&" to run in the background, otherwise the system may not be able to start. As the picture below.
Set the display resolution
Set the user interface display size in the /boot/config.txt file.
sudo nano /boot/config.txt
Then add the following lines at the end of the config.txt.
hdmi_force_hotplug=1 hdmi_cvt=[options] hdmi_group=2 hdmi_mode=1 hdmi_mode=87 display_rotate=0
Replace the above hdmi_cvt=[options] according to the LCD Module you are using.
#2.4inchinch LCD Module & 2inchinch LCD Module hdmi_cvt=640 480 60 1 0 0 0 #1.8inch LCD Module hdmi_cvt=400 300 60 1 0 0 0 #1.3inch LCD Module & 1.54inch LCD Module hdmi_cvt=300 300 60 1 0 0 0 #1.14inch LCD Module hdmi_cvt=300 170 60 1 0 0 0 #0.96inch LCD Module hdmi_cvt=300 150 60 1 0 0 0
And then reboot the system
sudo reboot
After rebooting the system, the Raspberry Pi OS user interface will be displayed.
Description of C codes (API)
The RaspberryPi series can share a set of programs, because they are all embedded systems, and the compatibility is relatively strong.
The program is divided into bottom-layer hardware interface, middle-layer LCD screen driver, and upper-layer application;
Hardware interface
We have carried out the low-level encapsulation, if you need to know the internal implementation can go to the corresponding directory to check, for the reason that the hardware platform and the internal implementation are different
You can open DEV_Config.c(.h) to see definitions,which in the directory RaspberryPi\c\lib\Config
1.There are three ways for C to drive:BCM2835 library, WiringPi library and Dev library respectively 2.We use Dev libraries by default. If you need to change to BCM2835 or WiringPi libraries ,please open RaspberryPi\c\Makefile and modify lines 13-15 as follows:
- Data type
#define UBYTE uint8_t #define UWORD uint16_t #define UDOUBLE uint32_t
- Module initialization and exit processing.
void DEV_Module_Init(void); void DEV_Module_Exit(void); Note: Here is some GPIO processing before and after using the LCD screen.
- GPIO read and write:
void DEV_Digital_Write(UWORD Pin, UBYTE Value); UBYTE DEV_Digital_Read(UWORD Pin);
- SPI write data
void DEV_SPI_WriteByte(UBYTE Value);
Upper application
If you need to draw pictures, display Chinese and English characters, display pictures, etc., we provide some basic functions here about some graphics processing in the directory RaspberryPi\c\lib\GUI\GUI_Paint.c(.h).
The fonts can be found in RaspberryPi\c\lib\Fonts directory.
- New Image Properties: Create a new image buffer, this property includes the image buffer name, width, height, flip Angle, color.
void Paint_NewImage(UBYTE *image, UWORD Width, UWORD Height, UWORD Rotate, UWORD Color) Parameters: Image: the name of the image buffer, which is actually a pointer to the first address of the image buffer; Width: image buffer Width; Height: the Height of the image buffer; Rotate: Indicates the rotation Angle of an image Color: the initial Color of the image;
- Select image buffer: The purpose of the selection is that you can create multiple image attributes, there can be multiple images buffer, you can select each image you create.
void Paint_SelectImage(UBYTE *image) Parameters: Image: the name of the image buffer, which is actually a pointer to the first address of the image buffer;
- Image Rotation: Set the rotation Angle of the selected image, preferably after Paint_SelectImage(), you can choose to rotate 0, 90, 180, 270.
void Paint_SetRotate(UWORD Rotate) Parameters: Rotate: ROTATE_0, ROTATE_90, ROTATE_180, and ROTATE_270 correspond to 0, 90, 180, and 270 degrees.
- Image mirror flip: Set the mirror flip of the selected image. You can choose no mirror, horizontal mirror, vertical mirror, or image center mirror.
void Paint_SetMirroring(UBYTE mirror) Parameters: Mirror: indicates the image mirroring mode. MIRROR_NONE, MIRROR_HORIZONTAL, MIRROR_VERTICAL, MIRROR_ORIGIN correspond to no mirror, horizontal mirror, vertical mirror, and image center mirror respectively.
- Sets the size of the pixels.
void Paint_SetScale(UBYTE scale) Parameters: scale: the size of pixels, 2: each pixel occupies one bit; 4: Each pixel occupies two bits.
- Set points of the display position and color in the buffer: here is the core GUI function, processing points display position and color in the buffer.
void Paint_SetPixel(UWORD Xpoint, UWORD Ypoint, UWORD Color) Parameters: Xpoint: the X position of a point in the image buffer Ypoint: Y position of a point in the image buffer Color: indicates the Color of the dot
- Image buffer fill color: Fills the image buffer with a color, usually used to flash the screen into blank.
void Paint_Clear(UWORD Color) Parameters: Color: fill Color
- The fill color of a certain window in the image buffer: the image buffer part of the window filled with a certain color, usually used to fresh the screen into blank, often used for time display, fresh the last second of the screen.
void Paint_ClearWindows(UWORD Xstart, UWORD Ystart, UWORD Xend, UWORD Yend, UWORD Color) Parameters: Xstart: the x-starting coordinate of the window Ystart: the y-starting coordinate of the window Xend: the x-end coordinate of the window Yend: the y-end coordinate of the window Color: fill Color
- Draw point: In the image buffer, draw points on (Xpoint, Ypoint), you can choose the color, the size of the point, the style of the point.
void Paint_DrawPoint(UWORD Xpoint, UWORD Ypoint, UWORD Color, DOT_PIXEL Dot_Pixel, DOT_STYLE Dot_Style) Parameters: Xpoint: indicates the X coordinate of a point. Ypoint: indicates the Y coordinate of a point. Color: fill Color Dot_Pixel: The size of the dot, the demo provides 8 size pointss by default. typedef enum { DOT_PIXEL_1X1 = 1, // 1 x 1 DOT_PIXEL_2X2 , // 2 X 2 DOT_PIXEL_3X3 , // 3 X 3 DOT_PIXEL_4X4 , // 4 X 4 DOT_PIXEL_5X5 , // 5 X 5 DOT_PIXEL_6X6 , // 6 X 6 DOT_PIXEL_7X7 , // 7 X 7 DOT_PIXEL_8X8 , // 8 X 8 } DOT_PIXEL; Dot_Style: the size of a point that expands from the center of the point or from the bottom left corner of the point to the right and up. typedef enum { DOT_FILL_AROUND = 1, DOT_FILL_RIGHTUP, } DOT_STYLE;
- Draw line: In the image buffer, draw line from (Xstart, Ystart) to (Xend, Yend), you can choose the color, the width and the style of the line.
void Paint_DrawLine(UWORD Xstart, UWORD Ystart, UWORD Xend, UWORD Yend, UWORD Color, LINE_STYLE Line_Style , LINE_STYLE Line_Style) Parameters: Xstart: the x-starting coordinate of a line Ystart: the y-starting coordinate of the a line Xend: the x-end coordinate of a line Yend: the y-end coordinate of a line Color: fill Color Line_width: The width of the line, the demo provides 8 sizes of width by default. typedef enum { DOT_PIXEL_1X1 = 1, // 1 x 1 DOT_PIXEL_2X2 , // 2 X 2 DOT_PIXEL_3X3 , // 3 X 3 DOT_PIXEL_4X4 , // 4 X 4 DOT_PIXEL_5X5 , // 5 X 5 DOT_PIXEL_6X6 , // 6 X 6 DOT_PIXEL_7X7 , // 7 X 7 DOT_PIXEL_8X8 , // 8 X 8 } DOT_PIXEL; Line_Style: line style. Select whether the lines are joined in a straight or dashed way. typedef enum { LINE_STYLE_SOLID = 0, LINE_STYLE_DOTTED, } LINE_STYLE;
- Draw rectangle: In the image buffer, draw a rectangle from (Xstart, Ystart) to (Xend, Yend), you can choose the color, the width of the line, whether to fill the inside of the rectangle.
void Paint_DrawRectangle(UWORD Xstart, UWORD Ystart, UWORD Xend, UWORD Yend, UWORD Color, DOT_PIXEL Line_width, DRAW_FILL Draw_Fill) Parameters: Xstart: the starting X coordinate of the rectangle Ystart: the starting Y coordinate of the rectangle Xend: the x-end coordinate of the rectangle Yend: the y-end coordinate of the rectangle Color: fill Color Line_width: The width of the four sides of a rectangle. And the demo provides 8 sizes of width by default. typedef enum { DOT_PIXEL_1X1 = 1, // 1 x 1 DOT_PIXEL_2X2 , // 2 X 2 DOT_PIXEL_3X3 , // 3 X 3 DOT_PIXEL_4X4 , // 4 X 4 DOT_PIXEL_5X5 , // 5 X 5 DOT_PIXEL_6X6 , // 6 X 6 DOT_PIXEL_7X7 , // 7 X 7 DOT_PIXEL_8X8 , // 8 X 8 } DOT_PIXEL; Draw_Fill: Fill, whether to fill the inside of the rectangle typedef enum { DRAW_FILL_EMPTY = 0, DRAW_FILL_FULL, } DRAW_FILL;
- Draw circle: In the image buffer, draw a circle of Radius with (X_Center Y_Center) as the center. You can choose the color, the width of the line, and whether to fill the inside of the circle.
void Paint_DrawCircle(UWORD X_Center, UWORD Y_Center, UWORD Radius, UWORD Color, DOT_PIXEL Line_width, DRAW_FILL Draw_Fill) Parameters: X_Center: the x-coordinate of the center of the circle Y_Center: the y-coordinate of the center of the circle Radius: indicates the Radius of a circle Color: fill Color Line_width: The width of the arc, with a default of 8 widths typedef enum { DOT_PIXEL_1X1 = 1, // 1 x 1 DOT_PIXEL_2X2 , // 2 X 2 DOT_PIXEL_3X3 , // 3 X 3 DOT_PIXEL_4X4 , // 4 X 4 DOT_PIXEL_5X5 , // 5 X 5 DOT_PIXEL_6X6 , // 6 X 6 DOT_PIXEL_7X7 , // 7 X 7 DOT_PIXEL_8X8 , // 8 X 8 } DOT_PIXEL; Draw_Fill: fill, whether to fill the inside of the circle typedef enum { DRAW_FILL_EMPTY = 0, DRAW_FILL_FULL, } DRAW_FILL;
- Write Ascii character: In the image buffer, use (Xstart Ystart) as the left vertex, write an Ascii character, you can select Ascii visual character library, font foreground color, font background color.
void Paint_DrawChar(UWORD Xstart, UWORD Ystart, const char Ascii_Char, sFONT* Font, UWORD Color_Foreground, UWORD Color_Background) Parameters: Xstart: the x-coordinate of the left vertex of a character Ystart: the Y-coordinate of the left vertex of a character Ascii_Char: indicates the Ascii character Font: Ascii visual character library, in the Fonts folder the demo provides the following Fonts: Font8: 5*8 font Font12: 7*12 font Font16: 11*16 font Font20: 14*20 font Font24: 17*24 font Color_Foreground: Font color Color_Background: indicates the background color
- Write English string: In the image buffer, use (Xstart Ystart) as the left vertex, write a string of English characters, you can choose Ascii visual character library, font foreground color, font background color.
void Paint_DrawString_EN(UWORD Xstart, UWORD Ystart, const char * pString, sFONT* Font, UWORD Color_Foreground, UWORD Color_Background) Parameters: Xstart: the x-coordinate of the left vertex of a character Ystart: the Y coordinate of the font's left vertex PString: string, string is a pointer Font: Ascii visual character library, in the Fonts folder the demo provides the following Fonts: Font8: 5*8 font Font12: 7*12 font Font16: 11*16 font Font20: 14*20 font Font24: 17*24 font Color_Foreground: Font color Color_Background: indicates the background color
- Write Chinese string: in the image buffer, use (Xstart Ystart) as the left vertex, write a string of Chinese characters, you can choose character font, font foreground color, font background color of the GB2312 encoding
void Paint_DrawString_CN(UWORD Xstart, UWORD Ystart, const char * pString, cFONT* font, UWORD Color_Foreground, UWORD Color_Background) Parameters: Xstart: the x-coordinate of the left vertex of a character Ystart: the Y coordinate of the font's left vertex PString: string, string is a pointer Font: GB2312 encoding character Font library, in the Fonts folder the demo provides the following Fonts: Font12CN: ASCII font 11*21, Chinese font 16*21 Font24CN: ASCII font24 *41, Chinese font 32*41 Color_Foreground: Font color Color_Background: indicates the background color
- Write numbers: In the image buffer,use (Xstart Ystart) as the left vertex, write a string of numbers, you can choose Ascii visual character library, font foreground color, font background color.
void Paint_DrawNum(UWORD Xpoint, UWORD Ypoint, double Nummber, sFONT* Font, UWORD Digit, UWORD Color_Foreground, UWORD Color_Background) Parameters: Xpoint: the x-coordinate of the left vertex of a character Ypoint: the Y coordinate of the left vertex of the font Nummber: indicates the number displayed, which can be a decimal Digit: It's a decimal number Font: Ascii visual character library, in the Fonts folder the demo provides the following Fonts: Font8: 5*8 font Font12: 7*12 font Font16: 11*16 font Font20: 14*20 font Font24: 17*24 font Color_Foreground: Font color Color_Background: indicates the background color
- Display time: in the image buffer,use (Xstart Ystart) as the left vertex, display time,you can choose Ascii visual character font, font foreground color, font background color.;
void Paint_DrawTime(UWORD Xstart, UWORD Ystart, PAINT_TIME *pTime, sFONT* Font, UWORD Color_Background, UWORD Color_Foreground) Parameters: Xstart: the x-coordinate of the left vertex of a character Ystart: the Y coordinate of the font's left vertex PTime: display time, A time structure is defined here, as long as the hours, minutes and seconds are passed to the parameters; Font: Ascii visual character library, in the Fonts folder the demo provides the following Fonts: Font8: 5*8 font Font12: 7*12 font Font16: 11*16 font Font20: 14*20 font Font24: 17*24 font Color_Foreground: Font color Color_Background: indicates the background color
- Read the local bmp image and write it to the cache
For Linux operating systems such as Raspberry Pi, you can read and write pictures For Raspberry Pi, in the directory: RaspberryPi\c\lib\GUI\GUI_BMPfile.c(.h)
UBYTE GUI_ReadBmp(const char *path, UWORD Xstart, UWORD Ystart) parameter: path: the relative path of the BMP image Xstart: The X coordinate of the left vertex of the image, generally 0 is passed by default Ystart: The Y coordinate of the left vertex of the picture, generally 0 by default
User test code
The first three chapters introduce the classic linux three-layer code structure, here is a little bit about the user test code For Raspberry Pi, in the directory: RaspberryPi\c\examples, for all the test code;
If you need to run the 0.96inch LCD test program, you need to add 0.96 as a parameter when running the mian program
Re-execute in linux command mode as follows:
make clean make sudo ./main 0.96
Python(for Raspberry Pi)
Works with python and python3
For python, his calls are not as complicated as C
Raspberry Pi: RaspberryPi\python\lib\
lcdconfig.py
- Module initialization and exit processing.
def module_init() def module_exit() Note: 1. Here is some GPIO processing before and after using the LCD screen. 2. The module_init() function is automatically called in the INIT () initializer on the LCD, but the module_exit() function needs to be called by itself
- GPIO read and write:
def digital_write(pin, value) def digital_read(pin)
- SPI write data.
def spi_writebyte(data)
- xxx_LCD_test.py (xxx indicates the size, if it is a 0.96inch LCD, it is 0inch96_LCD_test.py, and so on)
python is in the following directory:
Raspberry Pi: RaspberryPi\python\examples\
If your python version is python2 and you need to run the 0.96inch LCD test program, re-execute it as follows in linux command mode:
sudo python 0inch96_LCD_test.py
If your python version is python3 and you need to run the 0.96inch LCD test program, re-execute the following in linux command mode:
sudo python3 0inch96_LCD_test.py
About Rotation Settings
If you need to set the screen rotation in the python program, you can set it by the statement im_r= image1.rotate(270).
im_r= image1.rotate(270)
GUI functions
Python has an image library PIL official library link, it do not need to write code from the logical layer like C, can directly call to the image library for image processing. The following will take 1.54inch LCD as an example, we provide a brief description for the demo.
- It needs to use the image library and install the library.
sudo apt-get install python3-pil
And then import the library
from PIL import Image,ImageDraw,ImageFont.
Among them, Image is the basic library, ImageDraw is the drawing function, and ImageFont is the text function.
- Define an image cache to facilitate drawing, writing and other functions on the picture
image1 = Image.new("RGB", (disp.width, disp.height), "WHITE")
The first parameter defines the color depth of the image, which is defined as "1" to indicate the bitmap of one-bit depth. The second parameter is a tuple that defines the width and height of the image. The third parameter defines the default color of the buffer, which is defined as "WHITE".
- Create a drawing object based on Image1 on which all drawing operations will be performed on here.
draw = ImageDraw.Draw(image1)
- Draw line.
draw.line([(20, 10),(70, 60)], fill = "RED",width = 1)
The first parameter is a four-element tuple starting at (0, 0) and ending at (127,0). Draw a line. Fill ="0" means the color of the line is white.
- Draw rectangle.
draw.rectangle([(20,10),(70,60)],fill = "WHITE",outline="BLACK")
The first argument is a tuple of four elements. (20,10) is the coordinate value in the upper left corner of the rectangle, and (70,60) is the coordinate value in the lower right corner of the rectangle. Fill =" WHITE" means BLACK inside, and outline="BLACK" means the color of the outline is black.
- Draw circle.
draw.arc((150,15,190,55),0, 360, fill =(0,255,0)
Draw an inscribed circle in the square, the first parameter is a tuple of 4 elements, with (150, 15) as the upper left corner vertex of the square, (190, 55) as the lower right corner vertex of the square, specifying the level median line of the rectangular frame is the angle of 0 degrees, the second parameter indicates the starting angle, the third parameter indicates the ending angle, and fill = 0 indicates that the the color of the line is white. If the figure is not square according to the coordination, you will get an ellipse.
Besides the arc function, you can also use the chord function for drawing solid circle.
draw.ellipse((150,65,190,105), fill = 0)
The first parameter is the coordination of the enclosing rectangle. The second and third parameters are the beginning and end degrees of the circle. The fourth parameter is the fill color of the circle.
- Character.
The ImageFont module needs to be imported and instantiated:
Font1 = ImageFont.truetype("../Font/Font01.ttf",25) Font2 = ImageFont.truetype("../Font/Font01.ttf",35) Font3 = ImageFont.truetype("../Font/Font02.ttf",32)
You can use the fonts of Windows or other fonts which is in ttc format..
Note: Each character library contains different characters; If some characters cannot be displayed, it is recommended that you can refer to the encoding set ro used.
To draw English character, you can directly use the fonts; for Chinese character, you need to add a symbol u:
draw.text((5, 68), 'Hello world', fill = 0, font=Font1) text= u"微雪电子" draw.text((5, 200), text, fill = 0, font=Font3)
The first parameter is a two-element tuple with (5,68) as the left vertex, and use font1, fill is font color, fill = 0 means that the font color is white, and the second sentence shows’微雪电子’, font color is white.
- Read local picture.
image = Image.open('../pic/pic.bmp')
The parameter is the image path.
- Other functions.
Python's image library is very powerful, if you need to implement more, you can learn on the website http://effbot.org/imagingbook pil.