Mercurial > code > home > repos > 7key
changeset 0:b0c0a808af2b
start
| author | drewp@bigasterisk.com |
|---|---|
| date | Thu, 11 May 2023 15:05:52 -0700 |
| parents | |
| children | 5a93179ccae9 |
| files | ST7735.py |
| diffstat | 1 files changed, 925 insertions(+), 0 deletions(-) [+] |
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--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/ST7735.py Thu May 11 15:05:52 2023 -0700 @@ -0,0 +1,925 @@ +#driver for Sainsmart 1.8" TFT display ST7735 +#Translated by Guy Carver from the ST7735 sample code. +#Modirfied for micropython-esp32 by boochow + +import machine +import micropython +import time +from math import sqrt + +#TFTRotations and TFTRGB are bits to set +# on MADCTL to control display rotation/color layout +#Looking at display with pins on top. +#00 = upper left printing right +#10 = does nothing (MADCTL_ML) +#20 = upper left printing down (backwards) (Vertical flip) +#40 = upper right printing left (backwards) (X Flip) +#80 = lower left printing right (backwards) (Y Flip) +#04 = (MADCTL_MH) + +#60 = 90 right rotation +#C0 = 180 right rotation +#A0 = 270 right rotation +TFTRotations = [0x00, 0x60, 0xC0, 0xA0] +TFTBGR = 0x08 #When set color is bgr else rgb. +TFTRGB = 0x00 + +#@micropython.native +def clamp( aValue, aMin, aMax ) : + return max(aMin, min(aMax, aValue)) + +#@micropython.native +def TFTColor( aR, aG, aB ) : + '''Create a 16 bit rgb value from the given R,G,B from 0-255. + This assumes rgb 565 layout and will be incorrect for bgr.''' + return ((aR & 0xF8) << 8) | ((aG & 0xFC) << 3) | (aB >> 3) + +ScreenSize = (128, 160) + +class TFT(object) : + """Sainsmart TFT 7735 display driver.""" + + NOP = 0x0 + SWRESET = 0x01 + RDDID = 0x04 + RDDST = 0x09 + + SLPIN = 0x10 + SLPOUT = 0x11 + PTLON = 0x12 + NORON = 0x13 + + INVOFF = 0x20 + INVON = 0x21 + DISPOFF = 0x28 + DISPON = 0x29 + CASET = 0x2A + RASET = 0x2B + RAMWR = 0x2C + RAMRD = 0x2E + + VSCRDEF = 0x33 + VSCSAD = 0x37 + + COLMOD = 0x3A + MADCTL = 0x36 + + FRMCTR1 = 0xB1 + FRMCTR2 = 0xB2 + FRMCTR3 = 0xB3 + INVCTR = 0xB4 + DISSET5 = 0xB6 + + PWCTR1 = 0xC0 + PWCTR2 = 0xC1 + PWCTR3 = 0xC2 + PWCTR4 = 0xC3 + PWCTR5 = 0xC4 + VMCTR1 = 0xC5 + + RDID1 = 0xDA + RDID2 = 0xDB + RDID3 = 0xDC + RDID4 = 0xDD + + PWCTR6 = 0xFC + + GMCTRP1 = 0xE0 + GMCTRN1 = 0xE1 + + BLACK = 0 + RED = TFTColor(0xFF, 0x00, 0x00) + MAROON = TFTColor(0x80, 0x00, 0x00) + GREEN = TFTColor(0x00, 0xFF, 0x00) + FOREST = TFTColor(0x00, 0x80, 0x80) + BLUE = TFTColor(0x00, 0x00, 0xFF) + NAVY = TFTColor(0x00, 0x00, 0x80) + CYAN = TFTColor(0x00, 0xFF, 0xFF) + YELLOW = TFTColor(0xFF, 0xFF, 0x00) + PURPLE = TFTColor(0xFF, 0x00, 0xFF) + WHITE = TFTColor(0xFF, 0xFF, 0xFF) + GRAY = TFTColor(0x80, 0x80, 0x80) + + @staticmethod + def color( aR, aG, aB ) : + '''Create a 565 rgb TFTColor value''' + return TFTColor(aR, aG, aB) + + def __init__( self, spi, aDC, aReset, aCS) : + """aLoc SPI pin location is either 1 for 'X' or 2 for 'Y'. + aDC is the DC pin and aReset is the reset pin.""" + self._size = ScreenSize + self._offset = bytearray([0,0]) + self.rotate = 0 #Vertical with top toward pins. + self._rgb = True #color order of rgb. + self.tfa = 0 #top fixed area + self.bfa = 0 #bottom fixed area + self.dc = machine.Pin(aDC, machine.Pin.OUT, machine.Pin.PULL_DOWN) + self.reset = machine.Pin(aReset, machine.Pin.OUT, machine.Pin.PULL_DOWN) + self.cs = machine.Pin(aCS, machine.Pin.OUT, machine.Pin.PULL_DOWN) + self.cs(1) + self.spi = spi + self.colorData = bytearray(2) + self.windowLocData = bytearray(4) + + def size( self ) : + return self._size + +# @micropython.native + def on( self, aTF = True ) : + '''Turn display on or off.''' + self._writecommand(TFT.DISPON if aTF else TFT.DISPOFF) + +# @micropython.native + def invertcolor( self, aBool ) : + '''Invert the color data IE: Black = White.''' + self._writecommand(TFT.INVON if aBool else TFT.INVOFF) + +# @micropython.native + def rgb( self, aTF = True ) : + '''True = rgb else bgr''' + self._rgb = aTF + self._setMADCTL() + +# @micropython.native + def rotation( self, aRot ) : + '''0 - 3. Starts vertical with top toward pins and rotates 90 deg + clockwise each step.''' + if (0 <= aRot < 4): + rotchange = self.rotate ^ aRot + self.rotate = aRot + #If switching from vertical to horizontal swap x,y + # (indicated by bit 0 changing). + if (rotchange & 1): + self._size =(self._size[1], self._size[0]) + self._setMADCTL() + + @micropython.native + def pixel( self, aPos, aColor ) : + '''Draw a pixel at the given position''' + if 0 <= aPos[0] < self._size[0] and 0 <= aPos[1] < self._size[1]: + self._setwindowpoint(aPos) + self._pushcolor(aColor) + +# @micropython.native + def text( self, aPos, aString, aColor, aFont, aSize = 1, nowrap = False ) : + '''Draw a text at the given position. If the string reaches the end of the + display it is wrapped to aPos[0] on the next line. aSize may be an integer + which will size the font uniformly on w,h or a or any type that may be + indexed with [0] or [1].''' + + if aFont == None: + return + + #Make a size either from single value or 2 elements. + if (type(aSize) == int) or (type(aSize) == float): + wh = (aSize, aSize) + else: + wh = aSize + + px, py = aPos + width = wh[0] * aFont["Width"] + 1 + for c in aString: + self.char((px, py), c, aColor, aFont, wh) + px += width + #We check > rather than >= to let the right (blank) edge of the + # character print off the right of the screen. + if px + width > self._size[0]: + if nowrap: + break + else: + py += aFont["Height"] * wh[1] + 1 + px = aPos[0] + +# @micropython.native + def char( self, aPos, aChar, aColor, aFont, aSizes ) : + '''Draw a character at the given position using the given font and color. + aSizes is a tuple with x, y as integer scales indicating the + # of pixels to draw for each pixel in the character.''' + + if aFont == None: + return + + startchar = aFont['Start'] + endchar = aFont['End'] + + ci = ord(aChar) + if (startchar <= ci <= endchar): + fontw = aFont['Width'] + fonth = aFont['Height'] + ci = (ci - startchar) * fontw + + charA = aFont["Data"][ci:ci + fontw] + px = aPos[0] + if aSizes[0] <= 1 and aSizes[1] <= 1 : + buf = bytearray(2 * fonth * fontw) + for q in range(fontw) : + c = charA[q] + for r in range(fonth) : + if c & 0x01 : + pos = 2 * (r * fontw + q) + buf[pos] = aColor >> 8 + buf[pos + 1] = aColor & 0xff + c >>= 1 + self.image(aPos[0], aPos[1], aPos[0] + fontw - 1, aPos[1] + fonth - 1, buf) + else: + for c in charA : + py = aPos[1] + for r in range(fonth) : + if c & 0x01 : + self.fillrect((px, py), aSizes, aColor) + py += aSizes[1] + c >>= 1 + px += aSizes[0] + +# @micropython.native + def line( self, aStart, aEnd, aColor ) : + '''Draws a line from aStart to aEnd in the given color. Vertical or horizontal + lines are forwarded to vline and hline.''' + if aStart[0] == aEnd[0]: + #Make sure we use the smallest y. + pnt = aEnd if (aEnd[1] < aStart[1]) else aStart + self.vline(pnt, abs(aEnd[1] - aStart[1]) + 1, aColor) + elif aStart[1] == aEnd[1]: + #Make sure we use the smallest x. + pnt = aEnd if aEnd[0] < aStart[0] else aStart + self.hline(pnt, abs(aEnd[0] - aStart[0]) + 1, aColor) + else: + px, py = aStart + ex, ey = aEnd + dx = ex - px + dy = ey - py + inx = 1 if dx > 0 else -1 + iny = 1 if dy > 0 else -1 + + dx = abs(dx) + dy = abs(dy) + if (dx >= dy): + dy <<= 1 + e = dy - dx + dx <<= 1 + while (px != ex): + self.pixel((px, py), aColor) + if (e >= 0): + py += iny + e -= dx + e += dy + px += inx + else: + dx <<= 1 + e = dx - dy + dy <<= 1 + while (py != ey): + self.pixel((px, py), aColor) + if (e >= 0): + px += inx + e -= dy + e += dx + py += iny + +# @micropython.native + def vline( self, aStart, aLen, aColor ) : + '''Draw a vertical line from aStart for aLen. aLen may be negative.''' + start = (clamp(aStart[0], 0, self._size[0]), clamp(aStart[1], 0, self._size[1])) + stop = (start[0], clamp(start[1] + aLen, 0, self._size[1])) + #Make sure smallest y 1st. + if (stop[1] < start[1]): + start, stop = stop, start + self._setwindowloc(start, stop) + self._setColor(aColor) + self._draw(aLen) + +# @micropython.native + def hline( self, aStart, aLen, aColor ) : + '''Draw a horizontal line from aStart for aLen. aLen may be negative.''' + start = (clamp(aStart[0], 0, self._size[0]), clamp(aStart[1], 0, self._size[1])) + stop = (clamp(start[0] + aLen, 0, self._size[0]), start[1]) + #Make sure smallest x 1st. + if (stop[0] < start[0]): + start, stop = stop, start + self._setwindowloc(start, stop) + self._setColor(aColor) + self._draw(aLen) + +# @micropython.native + def rect( self, aStart, aSize, aColor ) : + '''Draw a hollow rectangle. aStart is the smallest coordinate corner + and aSize is a tuple indicating width, height.''' + self.hline(aStart, aSize[0], aColor) + self.hline((aStart[0], aStart[1] + aSize[1] - 1), aSize[0], aColor) + self.vline(aStart, aSize[1], aColor) + self.vline((aStart[0] + aSize[0] - 1, aStart[1]), aSize[1], aColor) + +# @micropython.native + def fillrect( self, aStart, aSize, aColor ) : + '''Draw a filled rectangle. aStart is the smallest coordinate corner + and aSize is a tuple indicating width, height.''' + start = (clamp(aStart[0], 0, self._size[0]), clamp(aStart[1], 0, self._size[1])) + end = (clamp(start[0] + aSize[0] - 1, 0, self._size[0]), clamp(start[1] + aSize[1] - 1, 0, self._size[1])) + + if (end[0] < start[0]): + tmp = end[0] + end = (start[0], end[1]) + start = (tmp, start[1]) + if (end[1] < start[1]): + tmp = end[1] + end = (end[0], start[1]) + start = (start[0], tmp) + + self._setwindowloc(start, end) + numPixels = (end[0] - start[0] + 1) * (end[1] - start[1] + 1) + self._setColor(aColor) + self._draw(numPixels) + +# @micropython.native + def circle( self, aPos, aRadius, aColor ) : + '''Draw a hollow circle with the given radius and color with aPos as center.''' + self.colorData[0] = aColor >> 8 + self.colorData[1] = aColor + xend = int(0.7071 * aRadius) + 1 + rsq = aRadius * aRadius + for x in range(xend) : + y = int(sqrt(rsq - x * x)) + xp = aPos[0] + x + yp = aPos[1] + y + xn = aPos[0] - x + yn = aPos[1] - y + xyp = aPos[0] + y + yxp = aPos[1] + x + xyn = aPos[0] - y + yxn = aPos[1] - x + + self._setwindowpoint((xp, yp)) + self._writedata(self.colorData) + self._setwindowpoint((xp, yn)) + self._writedata(self.colorData) + self._setwindowpoint((xn, yp)) + self._writedata(self.colorData) + self._setwindowpoint((xn, yn)) + self._writedata(self.colorData) + self._setwindowpoint((xyp, yxp)) + self._writedata(self.colorData) + self._setwindowpoint((xyp, yxn)) + self._writedata(self.colorData) + self._setwindowpoint((xyn, yxp)) + self._writedata(self.colorData) + self._setwindowpoint((xyn, yxn)) + self._writedata(self.colorData) + +# @micropython.native + def fillcircle( self, aPos, aRadius, aColor ) : + '''Draw a filled circle with given radius and color with aPos as center''' + rsq = aRadius * aRadius + for x in range(aRadius) : + y = int(sqrt(rsq - x * x)) + y0 = aPos[1] - y + ey = y0 + y * 2 + y0 = clamp(y0, 0, self._size[1]) + ln = abs(ey - y0) + 1; + + self.vline((aPos[0] + x, y0), ln, aColor) + self.vline((aPos[0] - x, y0), ln, aColor) + + def fill( self, aColor = BLACK ) : + '''Fill screen with the given color.''' + self.fillrect((0, 0), self._size, aColor) + + def image( self, x0, y0, x1, y1, data ) : + self._setwindowloc((x0, y0), (x1, y1)) + self._writedata(data) + + def setvscroll(self, tfa, bfa) : + ''' set vertical scroll area ''' + self._writecommand(TFT.VSCRDEF) + data2 = bytearray([0, tfa]) + self._writedata(data2) + data2[1] = 162 - tfa - bfa + self._writedata(data2) + data2[1] = bfa + self._writedata(data2) + self.tfa = tfa + self.bfa = bfa + + def vscroll(self, value) : + a = value + self.tfa + if (a + self.bfa > 162) : + a = 162 - self.bfa + self._vscrolladdr(a) + + def _vscrolladdr(self, addr) : + self._writecommand(TFT.VSCSAD) + data2 = bytearray([addr >> 8, addr & 0xff]) + self._writedata(data2) + +# @micropython.native + def _setColor( self, aColor ) : + self.colorData[0] = aColor >> 8 + self.colorData[1] = aColor + self.buf = bytes(self.colorData) * 32 + +# @micropython.native + def _draw( self, aPixels ) : + '''Send given color to the device aPixels times.''' + + self.dc(1) + self.cs(0) + for i in range(aPixels//32): + self.spi.write(self.buf) + rest = (int(aPixels) % 32) + if rest > 0: + buf2 = bytes(self.colorData) * rest + self.spi.write(buf2) + self.cs(1) + +# @micropython.native + def _setwindowpoint( self, aPos ) : + '''Set a single point for drawing a color to.''' + x = self._offset[0] + int(aPos[0]) + y = self._offset[1] + int(aPos[1]) + self._writecommand(TFT.CASET) #Column address set. + self.windowLocData[0] = self._offset[0] + self.windowLocData[1] = x + self.windowLocData[2] = self._offset[0] + self.windowLocData[3] = x + self._writedata(self.windowLocData) + + self._writecommand(TFT.RASET) #Row address set. + self.windowLocData[0] = self._offset[1] + self.windowLocData[1] = y + self.windowLocData[2] = self._offset[1] + self.windowLocData[3] = y + self._writedata(self.windowLocData) + self._writecommand(TFT.RAMWR) #Write to RAM. + +# @micropython.native + def _setwindowloc( self, aPos0, aPos1 ) : + '''Set a rectangular area for drawing a color to.''' + self._writecommand(TFT.CASET) #Column address set. + self.windowLocData[0] = self._offset[0] + self.windowLocData[1] = self._offset[0] + int(aPos0[0]) + self.windowLocData[2] = self._offset[0] + self.windowLocData[3] = self._offset[0] + int(aPos1[0]) + self._writedata(self.windowLocData) + + self._writecommand(TFT.RASET) #Row address set. + self.windowLocData[0] = self._offset[1] + self.windowLocData[1] = self._offset[1] + int(aPos0[1]) + self.windowLocData[2] = self._offset[1] + self.windowLocData[3] = self._offset[1] + int(aPos1[1]) + self._writedata(self.windowLocData) + + self._writecommand(TFT.RAMWR) #Write to RAM. + + #@micropython.native + def _writecommand( self, aCommand ) : + '''Write given command to the device.''' + self.dc(0) + self.cs(0) + self.spi.write(bytearray([aCommand])) + self.cs(1) + + #@micropython.native + def _writedata( self, aData ) : + '''Write given data to the device. This may be + either a single int or a bytearray of values.''' + self.dc(1) + self.cs(0) + self.spi.write(aData) + self.cs(1) + + #@micropython.native + def _pushcolor( self, aColor ) : + '''Push given color to the device.''' + self.colorData[0] = aColor >> 8 + self.colorData[1] = aColor + self._writedata(self.colorData) + + #@micropython.native + def _setMADCTL( self ) : + '''Set screen rotation and RGB/BGR format.''' + self._writecommand(TFT.MADCTL) + rgb = TFTRGB if self._rgb else TFTBGR + self._writedata(bytearray([TFTRotations[self.rotate] | rgb])) + + #@micropython.native + def _reset( self ) : + '''Reset the device.''' + self.dc(0) + self.reset(1) + time.sleep_us(500) + self.reset(0) + time.sleep_us(500) + self.reset(1) + time.sleep_us(500) + + def initb( self ) : + '''Initialize blue tab version.''' + self._size = (ScreenSize[0] + 2, ScreenSize[1] + 1) + self._reset() + self._writecommand(TFT.SWRESET) #Software reset. + time.sleep_us(50) + self._writecommand(TFT.SLPOUT) #out of sleep mode. + time.sleep_us(500) + + data1 = bytearray(1) + self._writecommand(TFT.COLMOD) #Set color mode. + data1[0] = 0x05 #16 bit color. + self._writedata(data1) + time.sleep_us(10) + + data3 = bytearray([0x00, 0x06, 0x03]) #fastest refresh, 6 lines front, 3 lines back. + self._writecommand(TFT.FRMCTR1) #Frame rate control. + self._writedata(data3) + time.sleep_us(10) + + self._writecommand(TFT.MADCTL) + data1[0] = 0x08 #row address/col address, bottom to top refresh + self._writedata(data1) + + data2 = bytearray(2) + self._writecommand(TFT.DISSET5) #Display settings + data2[0] = 0x15 #1 clock cycle nonoverlap, 2 cycle gate rise, 3 cycle oscil, equalize + data2[1] = 0x02 #fix on VTL + self._writedata(data2) + + self._writecommand(TFT.INVCTR) #Display inversion control + data1[0] = 0x00 #Line inversion. + self._writedata(data1) + + self._writecommand(TFT.PWCTR1) #Power control + data2[0] = 0x02 #GVDD = 4.7V + data2[1] = 0x70 #1.0uA + self._writedata(data2) + time.sleep_us(10) + + self._writecommand(TFT.PWCTR2) #Power control + data1[0] = 0x05 #VGH = 14.7V, VGL = -7.35V + self._writedata(data1) + + self._writecommand(TFT.PWCTR3) #Power control + data2[0] = 0x01 #Opamp current small + data2[1] = 0x02 #Boost frequency + self._writedata(data2) + + self._writecommand(TFT.VMCTR1) #Power control + data2[0] = 0x3C #VCOMH = 4V + data2[1] = 0x38 #VCOML = -1.1V + self._writedata(data2) + time.sleep_us(10) + + self._writecommand(TFT.PWCTR6) #Power control + data2[0] = 0x11 + data2[1] = 0x15 + self._writedata(data2) + + #These different values don't seem to make a difference. +# dataGMCTRP = bytearray([0x0f, 0x1a, 0x0f, 0x18, 0x2f, 0x28, 0x20, 0x22, 0x1f, +# 0x1b, 0x23, 0x37, 0x00, 0x07, 0x02, 0x10]) + dataGMCTRP = bytearray([0x02, 0x1c, 0x07, 0x12, 0x37, 0x32, 0x29, 0x2d, 0x29, + 0x25, 0x2b, 0x39, 0x00, 0x01, 0x03, 0x10]) + self._writecommand(TFT.GMCTRP1) + self._writedata(dataGMCTRP) + +# dataGMCTRN = bytearray([0x0f, 0x1b, 0x0f, 0x17, 0x33, 0x2c, 0x29, 0x2e, 0x30, +# 0x30, 0x39, 0x3f, 0x00, 0x07, 0x03, 0x10]) + dataGMCTRN = bytearray([0x03, 0x1d, 0x07, 0x06, 0x2e, 0x2c, 0x29, 0x2d, 0x2e, + 0x2e, 0x37, 0x3f, 0x00, 0x00, 0x02, 0x10]) + self._writecommand(TFT.GMCTRN1) + self._writedata(dataGMCTRN) + time.sleep_us(10) + + self._writecommand(TFT.CASET) #Column address set. + self.windowLocData[0] = 0x00 + self.windowLocData[1] = 2 #Start at column 2 + self.windowLocData[2] = 0x00 + self.windowLocData[3] = self._size[0] - 1 + self._writedata(self.windowLocData) + + self._writecommand(TFT.RASET) #Row address set. + self.windowLocData[1] = 1 #Start at row 2. + self.windowLocData[3] = self._size[1] - 1 + self._writedata(self.windowLocData) + + self._writecommand(TFT.NORON) #Normal display on. + time.sleep_us(10) + + self._writecommand(TFT.RAMWR) + time.sleep_us(500) + + self._writecommand(TFT.DISPON) + self.cs(1) + time.sleep_us(500) + + def initr( self ) : + '''Initialize a red tab version.''' + self._reset() + + self._writecommand(TFT.SWRESET) #Software reset. + time.sleep_us(150) + self._writecommand(TFT.SLPOUT) #out of sleep mode. + time.sleep_us(500) + + data3 = bytearray([0x01, 0x2C, 0x2D]) #fastest refresh, 6 lines front, 3 lines back. + self._writecommand(TFT.FRMCTR1) #Frame rate control. + self._writedata(data3) + + self._writecommand(TFT.FRMCTR2) #Frame rate control. + self._writedata(data3) + + data6 = bytearray([0x01, 0x2c, 0x2d, 0x01, 0x2c, 0x2d]) + self._writecommand(TFT.FRMCTR3) #Frame rate control. + self._writedata(data6) + time.sleep_us(10) + + data1 = bytearray(1) + self._writecommand(TFT.INVCTR) #Display inversion control + data1[0] = 0x07 #Line inversion. + self._writedata(data1) + + self._writecommand(TFT.PWCTR1) #Power control + data3[0] = 0xA2 + data3[1] = 0x02 + data3[2] = 0x84 + self._writedata(data3) + + self._writecommand(TFT.PWCTR2) #Power control + data1[0] = 0xC5 #VGH = 14.7V, VGL = -7.35V + self._writedata(data1) + + data2 = bytearray(2) + self._writecommand(TFT.PWCTR3) #Power control + data2[0] = 0x0A #Opamp current small + data2[1] = 0x00 #Boost frequency + self._writedata(data2) + + self._writecommand(TFT.PWCTR4) #Power control + data2[0] = 0x8A #Opamp current small + data2[1] = 0x2A #Boost frequency + self._writedata(data2) + + self._writecommand(TFT.PWCTR5) #Power control + data2[0] = 0x8A #Opamp current small + data2[1] = 0xEE #Boost frequency + self._writedata(data2) + + self._writecommand(TFT.VMCTR1) #Power control + data1[0] = 0x0E + self._writedata(data1) + + self._writecommand(TFT.INVOFF) + + self._writecommand(TFT.MADCTL) #Power control + data1[0] = 0xC8 + self._writedata(data1) + + self._writecommand(TFT.COLMOD) + data1[0] = 0x05 + self._writedata(data1) + + self._writecommand(TFT.CASET) #Column address set. + self.windowLocData[0] = 0x00 + self.windowLocData[1] = 0x00 + self.windowLocData[2] = 0x00 + self.windowLocData[3] = self._size[0] - 1 + self._writedata(self.windowLocData) + + self._writecommand(TFT.RASET) #Row address set. + self.windowLocData[3] = self._size[1] - 1 + self._writedata(self.windowLocData) + + dataGMCTRP = bytearray([0x0f, 0x1a, 0x0f, 0x18, 0x2f, 0x28, 0x20, 0x22, 0x1f, + 0x1b, 0x23, 0x37, 0x00, 0x07, 0x02, 0x10]) + self._writecommand(TFT.GMCTRP1) + self._writedata(dataGMCTRP) + + dataGMCTRN = bytearray([0x0f, 0x1b, 0x0f, 0x17, 0x33, 0x2c, 0x29, 0x2e, 0x30, + 0x30, 0x39, 0x3f, 0x00, 0x07, 0x03, 0x10]) + self._writecommand(TFT.GMCTRN1) + self._writedata(dataGMCTRN) + time.sleep_us(10) + + self._writecommand(TFT.DISPON) + time.sleep_us(100) + + self._writecommand(TFT.NORON) #Normal display on. + time.sleep_us(10) + + self.cs(1) + + def initb2( self ) : + '''Initialize another blue tab version.''' + self._size = (ScreenSize[0] + 2, ScreenSize[1] + 1) + self._offset[0] = 2 + self._offset[1] = 1 + self._reset() + self._writecommand(TFT.SWRESET) #Software reset. + time.sleep_us(50) + self._writecommand(TFT.SLPOUT) #out of sleep mode. + time.sleep_us(500) + + data3 = bytearray([0x01, 0x2C, 0x2D]) # + self._writecommand(TFT.FRMCTR1) #Frame rate control. + self._writedata(data3) + time.sleep_us(10) + + self._writecommand(TFT.FRMCTR2) #Frame rate control. + self._writedata(data3) + time.sleep_us(10) + + self._writecommand(TFT.FRMCTR3) #Frame rate control. + self._writedata(data3) + time.sleep_us(10) + + self._writecommand(TFT.INVCTR) #Display inversion control + data1 = bytearray(1) # + data1[0] = 0x07 + self._writedata(data1) + + self._writecommand(TFT.PWCTR1) #Power control + data3[0] = 0xA2 # + data3[1] = 0x02 # + data3[2] = 0x84 # + self._writedata(data3) + time.sleep_us(10) + + self._writecommand(TFT.PWCTR2) #Power control + data1[0] = 0xC5 # + self._writedata(data1) + + self._writecommand(TFT.PWCTR3) #Power control + data2 = bytearray(2) + data2[0] = 0x0A # + data2[1] = 0x00 # + self._writedata(data2) + + self._writecommand(TFT.PWCTR4) #Power control + data2[0] = 0x8A # + data2[1] = 0x2A # + self._writedata(data2) + + self._writecommand(TFT.PWCTR5) #Power control + data2[0] = 0x8A # + data2[1] = 0xEE # + self._writedata(data2) + + self._writecommand(TFT.VMCTR1) #Power control + data1[0] = 0x0E # + self._writedata(data1) + time.sleep_us(10) + + self._writecommand(TFT.MADCTL) + data1[0] = 0xC8 #row address/col address, bottom to top refresh + self._writedata(data1) + +#These different values don't seem to make a difference. +# dataGMCTRP = bytearray([0x0f, 0x1a, 0x0f, 0x18, 0x2f, 0x28, 0x20, 0x22, 0x1f, +# 0x1b, 0x23, 0x37, 0x00, 0x07, 0x02, 0x10]) + dataGMCTRP = bytearray([0x02, 0x1c, 0x07, 0x12, 0x37, 0x32, 0x29, 0x2d, 0x29, + 0x25, 0x2b, 0x39, 0x00, 0x01, 0x03, 0x10]) + self._writecommand(TFT.GMCTRP1) + self._writedata(dataGMCTRP) + +# dataGMCTRN = bytearray([0x0f, 0x1b, 0x0f, 0x17, 0x33, 0x2c, 0x29, 0x2e, 0x30, +# 0x30, 0x39, 0x3f, 0x00, 0x07, 0x03, 0x10]) + dataGMCTRN = bytearray([0x03, 0x1d, 0x07, 0x06, 0x2e, 0x2c, 0x29, 0x2d, 0x2e, + 0x2e, 0x37, 0x3f, 0x00, 0x00, 0x02, 0x10]) + self._writecommand(TFT.GMCTRN1) + self._writedata(dataGMCTRN) + time.sleep_us(10) + + self._writecommand(TFT.CASET) #Column address set. + self.windowLocData[0] = 0x00 + self.windowLocData[1] = 0x02 #Start at column 2 + self.windowLocData[2] = 0x00 + self.windowLocData[3] = self._size[0] - 1 + self._writedata(self.windowLocData) + + self._writecommand(TFT.RASET) #Row address set. + self.windowLocData[1] = 0x01 #Start at row 2. + self.windowLocData[3] = self._size[1] - 1 + self._writedata(self.windowLocData) + + data1 = bytearray(1) + self._writecommand(TFT.COLMOD) #Set color mode. + data1[0] = 0x05 #16 bit color. + self._writedata(data1) + time.sleep_us(10) + + self._writecommand(TFT.NORON) #Normal display on. + time.sleep_us(10) + + self._writecommand(TFT.RAMWR) + time.sleep_us(500) + + self._writecommand(TFT.DISPON) + self.cs(1) + time.sleep_us(500) + + #@micropython.native + def initg( self ) : + '''Initialize a green tab version.''' + self._reset() + + self._writecommand(TFT.SWRESET) #Software reset. + time.sleep_us(150) + self._writecommand(TFT.SLPOUT) #out of sleep mode. + time.sleep_us(255) + + data3 = bytearray([0x01, 0x2C, 0x2D]) #fastest refresh, 6 lines front, 3 lines back. + self._writecommand(TFT.FRMCTR1) #Frame rate control. + self._writedata(data3) + + self._writecommand(TFT.FRMCTR2) #Frame rate control. + self._writedata(data3) + + data6 = bytearray([0x01, 0x2c, 0x2d, 0x01, 0x2c, 0x2d]) + self._writecommand(TFT.FRMCTR3) #Frame rate control. + self._writedata(data6) + time.sleep_us(10) + + self._writecommand(TFT.INVCTR) #Display inversion control + self._writedata(bytearray([0x07])) + self._writecommand(TFT.PWCTR1) #Power control + data3[0] = 0xA2 + data3[1] = 0x02 + data3[2] = 0x84 + self._writedata(data3) + + self._writecommand(TFT.PWCTR2) #Power control + self._writedata(bytearray([0xC5])) + + data2 = bytearray(2) + self._writecommand(TFT.PWCTR3) #Power control + data2[0] = 0x0A #Opamp current small + data2[1] = 0x00 #Boost frequency + self._writedata(data2) + + self._writecommand(TFT.PWCTR4) #Power control + data2[0] = 0x8A #Opamp current small + data2[1] = 0x2A #Boost frequency + self._writedata(data2) + + self._writecommand(TFT.PWCTR5) #Power control + data2[0] = 0x8A #Opamp current small + data2[1] = 0xEE #Boost frequency + self._writedata(data2) + + self._writecommand(TFT.VMCTR1) #Power control + self._writedata(bytearray([0x0E])) + + self._writecommand(TFT.INVOFF) + + self._setMADCTL() + + self._writecommand(TFT.COLMOD) + self._writedata(bytearray([0x05])) + + self._writecommand(TFT.CASET) #Column address set. + self.windowLocData[0] = 0x00 + self.windowLocData[1] = 0x01 #Start at row/column 1. + self.windowLocData[2] = 0x00 + self.windowLocData[3] = self._size[0] - 1 + self._writedata(self.windowLocData) + + self._writecommand(TFT.RASET) #Row address set. + self.windowLocData[3] = self._size[1] - 1 + self._writedata(self.windowLocData) + + dataGMCTRP = bytearray([0x02, 0x1c, 0x07, 0x12, 0x37, 0x32, 0x29, 0x2d, 0x29, + 0x25, 0x2b, 0x39, 0x00, 0x01, 0x03, 0x10]) + self._writecommand(TFT.GMCTRP1) + self._writedata(dataGMCTRP) + + dataGMCTRN = bytearray([0x03, 0x1d, 0x07, 0x06, 0x2e, 0x2c, 0x29, 0x2d, 0x2e, + 0x2e, 0x37, 0x3f, 0x00, 0x00, 0x02, 0x10]) + self._writecommand(TFT.GMCTRN1) + self._writedata(dataGMCTRN) + + self._writecommand(TFT.NORON) #Normal display on. + time.sleep_us(10) + + self._writecommand(TFT.DISPON) + time.sleep_us(100) + + self.cs(1) + +def maker( ) : + t = TFT(1, "X1", "X2") + print("Initializing") + t.initr() + t.fill(0) + return t + +def makeb( ) : + t = TFT(1, "X1", "X2") + print("Initializing") + t.initb() + t.fill(0) + return t + +def makeg( ) : + t = TFT(1, "X1", "X2") + print("Initializing") + t.initg() + t.fill(0) + return t \ No newline at end of file