NerdNos-Firmware/lib/TFT_eSPI/Tools/bmp2array4bit/bmp2array4bit.py

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'''
This script takes in a bitmap and outputs a text file that is a
byte array used in Arduino files.
It is loosely based on Spark Fun's bmp2array script.
You'll need python 3.6 (the original use Python 2.7)
usage: python fourbitbmp2array.py [-v] star.bmp [-o myfile.c]
Create the bmp file in Gimp by :
. Remove the alpha channel (if it has one) Layer -> Transparency -> Remove Alpha Channel
. Set the mode to indexed. Image -> Mode -> Indexed...
. Select Generate optimum palette with 16 colors (max)
. Export the file with a .bmp extension. Options are:
. Run-Length Encoded: not selected
. Compatibility Options: "Do not write color space information" not selected
. There are no Advanced Options available with these settings
'''
import sys
import struct
import math
import argparse
import os
debug = None
def debugOut(s):
if debug:
print(s)
# look at arguments
parser = argparse.ArgumentParser(description="Convert bmp file to C array")
parser.add_argument("-v", "--verbose", help="debug output", action="store_true")
parser.add_argument("input", help="input file name")
parser.add_argument("-o", "--output", help="output file name")
args = parser.parse_args()
if not os.path.exists(args.input):
parser.print_help()
print("The input file {} does not exist".format(args.input))
sys.exit(1)
if args.output == None:
output = os.path.basename(args.input).replace(".bmp", ".c")
else:
output = args.output
debug = args.verbose
try:
#Open our input file which is defined by the first commandline argument
#then dump it into a list of bytes
infile = open(args.input,"rb") #b is for binary
contents = bytearray(infile.read())
infile.close()
except:
print("could not read input file {}".format(args.input))
sys.exit(1)
# first two bytes should be "BM"
upto = 2
#Get the size of this image
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
fileSize = struct.unpack("I", bytearray(data))
upto += 4
# four bytes are reserved
upto += 4
debugOut("Size of file: {}".format(fileSize[0]))
#Get the header offset amount
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
offset = struct.unpack("I", bytearray(data))
debugOut("Offset: {}".format(offset[0]))
upto += 4
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
headersize = struct.unpack("I", bytearray(data))
headerLength = headersize[0]
startOfDefinitions = headerLength + upto
debugOut("header size: {}, up to {}, startOfDefinitions {}".format(headersize[0], upto, startOfDefinitions))
upto += 4
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
t = struct.unpack("I", bytearray(data))
debugOut("width: {}".format(t[0]))
width = t[0]
upto += 4
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
t = struct.unpack("I", bytearray(data))
debugOut("height: {}".format(t[0]))
height = t[0]
# 26
upto += 4
data = struct.pack("BB", contents[upto], contents[upto+1])
t = struct.unpack("H", bytearray(data))
debugOut("planes: {}".format(t[0]))
upto = upto + 2
data = struct.pack("BB", contents[upto], contents[upto+1])
t = struct.unpack("H", bytearray(data))
debugOut("bits per pixel: {}".format(t[0]))
bitsPerPixel = t[0]
upto = upto + 2
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
t = struct.unpack("I", bytearray(data))
debugOut("biCompression: {}".format(t[0]))
upto = upto + 4
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
t = struct.unpack("I", bytearray(data))
debugOut("biSizeImage: {}".format(t[0]))
upto = upto + 4
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
t = struct.unpack("I", bytearray(data))
debugOut("biXPelsPerMeter: {}".format(t[0]))
upto = upto + 4
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
t = struct.unpack("I", bytearray(data))
debugOut("biYPelsPerMeter: {}".format(t[0]))
upto = upto + 4
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
t = struct.unpack("I", bytearray(data))
debugOut("biClrUsed: {}".format(t[0]))
colorsUsed = t
upto = upto + 4
data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
t = struct.unpack("I", bytearray(data))
debugOut("biClrImportant: {}".format(t[0]))
upto += 4
debugOut("Upto: {} Number of colors used: {} definitions start at: {}".format(upto, colorsUsed[0], startOfDefinitions))
#Create color definition array and init the array of color values
colorIndex = [] #(colorsUsed[0])
for i in range(colorsUsed[0]):
colorIndex.append(0)
#Assign the colors to the array. upto = 54
# startOfDefinitions = upto
for i in range(colorsUsed[0]):
upto = startOfDefinitions + (i * 4)
blue = contents[upto]
green = contents[upto + 1]
red = contents[upto + 2]
# ignore the alpha channel.
# data = struct.pack("BBBB", contents[upto], contents[upto+1], contents[upto+2], contents[upto+3])
# t = struct.unpack("I", bytearray(data))
# colorIndex[i] = t[0]
colorIndex[i] = (((red & 0xf8)<<8) + ((green & 0xfc)<<3)+(blue>>3))
debugOut("color at index {0} is {1:04x}, (r,g,b,a) = ({2:02x}, {3:02x}, {4:02x}, {5:02x})".format(i, colorIndex[i], red, green, blue, contents[upto+3]))
#debugOut(the color definitions
# for i in range(colorsUsed[0]):
# print hex(colorIndex[i])
# perfect, except upside down.
#Make a string to hold the output of our script
arraySize = (len(contents) - offset[0])
outputString = "/* This was generated using a script based on the SparkFun BMPtoArray python script" + '\n'
outputString += " See https://github.com/sparkfun/BMPtoArray for more info */" + '\n\n'
outputString += "static const uint16_t palette[" + str(colorsUsed[0]) + "] = {";
for i in range(colorsUsed[0]):
# print hexlify(colorIndex[i])
if i % 4 == 0:
outputString += "\n\t"
outputString += "0x{:04x}, ".format(colorIndex[i])
outputString = outputString[:-2]
outputString += "\n};\n\n"
outputString += "// width is " + str(width) + ", height is " + str(height) + "\n"
outputString += "static const uint8_t myGraphic[" + str(arraySize) + "] PROGMEM = {" + '\n'
if bitsPerPixel != 4:
print("Expected 4 bits per pixel; found {}".format(bitsPerPixel))
sys.exit(1)
#Start converting spots to values
#Start at the offset and go to the end of the file
dropLastNumber = True #(width % 4) == 2 or (width % 4) == 1
paddedWidth = int(math.ceil(bitsPerPixel * width / 32.0) * 4)
debugOut("array range is {} {} len(contents) is {} paddedWidth is {} width is {}".format(offset[0], fileSize[0], len(contents), paddedWidth, width))
r = 0
width = int(width / 2)
#for i in range(offset[0], fileSize[0]): # close but image is upside down. Each row is correct but need to swap columns.
#for i in range(fileSize[0], offset[0], -1):
for col in range(height-1, -1, -1):
i = 0
for row in range(width):
colorCode1 = contents[row + col*paddedWidth + offset[0]]
if r > 0 and r % width == 0:
i = 0
outputString += '\n\n'
elif (i + 1) % 12 == 0 :
outputString += '\n'
i = 0
#debugOut("cell ({0}, {1})".format(row, col)
r = r + 1
i = i + 1
outputString += "0x{:02x}, ".format(colorCode1)
#Once we've reached the end of our input string, pull the last two
#characters off (the last comma and space) since we don't need
#them. Top it off with a closing bracket and a semicolon.
outputString = outputString[:-2]
outputString += "};"
try:
#Write the output string to our output file
outfile = open(output, "w")
outfile.write(outputString)
outfile.close()
except:
print("could not write output to file {}".format(output))
sys.exit(1)
debugOut("{} complete".format(output))
debugOut("Copy and paste this array into a image.h or other header file")
if not debug:
print("Completed; the output is in {}".format(output))