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Adafruit_Thermal.py
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Adafruit_Thermal.py
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#*************************************************************************
# This is a Python library for the Adafruit Thermal Printer.
# Pick one up at --> http://www.adafruit.com/products/597
# These printers use TTL serial to communicate, 2 pins are required.
# IMPORTANT: On 3.3V systems (e.g. Raspberry Pi), use a 10K resistor on
# the RX pin (TX on the printer, green wire), or simply leave unconnected.
#
# Adafruit invests time and resources providing this open source code.
# Please support Adafruit and open-source hardware by purchasing products
# from Adafruit!
#
# Written by Limor Fried/Ladyada for Adafruit Industries.
# Python port by Phil Burgess for Adafruit Industries.
# MIT license, all text above must be included in any redistribution.
#*************************************************************************
# This is pretty much a 1:1 direct Python port of the Adafruit_Thermal
# library for Arduino. All methods use the same naming conventions as the
# Arduino library, with only slight changes in parameter behavior where
# needed. This should simplify porting existing Adafruit_Thermal-based
# printer projects to Raspberry Pi, BeagleBone, etc. See printertest.py
# for an example.
#
# One significant change is the addition of the printImage() function,
# which ties this to the Python Imaging Library and opens the door to a
# lot of cool graphical stuff!
#
# TO DO:
# - Might use standard ConfigParser library to put thermal calibration
# settings in a global configuration file (rather than in the library).
# - Make this use proper Python library installation procedure.
# - Trap errors properly. Some stuff just falls through right now.
# - Add docstrings throughout!
from serial import Serial
import time
import sys
import math
class Adafruit_Thermal(Serial):
resumeTime = 0.0
byteTime = 0.0
dotPrintTime = 0.0
dotFeedTime = 0.0
prevByte = '\n'
column = 0
maxColumn = 32
charHeight = 24
lineSpacing = 8
barcodeHeight = 50
printMode = 0
defaultHeatTime = 120
firmwareVersion = 268
writeToStdout = False
def __init__(self, *args, **kwargs):
# NEW BEHAVIOR: if no parameters given, output is written
# to stdout, to be piped through 'lp -o raw' (old behavior
# was to use default port & baud rate).
baudrate = 19200
if len(args) == 0:
self.writeToStdout = True
if len(args) == 1:
# If only port is passed, use default baud rate.
args = [ args[0], baudrate ]
elif len(args) == 2:
# If both passed, use those values.
baudrate = args[1]
# Firmware is assumed version 2.68. Can override this
# with the 'firmware=X' argument, where X is the major
# version number * 100 + the minor version number (e.g.
# pass "firmware=264" for version 2.64.
self.firmwareVersion = kwargs.get('firmware', 268)
if self.writeToStdout is False:
# Calculate time to issue one byte to the printer.
# 11 bits (not 8) to accommodate idle, start and
# stop bits. Idle time might be unnecessary, but
# erring on side of caution here.
self.byteTime = 11.0 / float(baudrate)
Serial.__init__(self, *args, **kwargs)
# Remainder of this method was previously in begin()
# The printer can't start receiving data immediately
# upon power up -- it needs a moment to cold boot
# and initialize. Allow at least 1/2 sec of uptime
# before printer can receive data.
self.timeoutSet(0.5)
self.wake()
self.reset()
# Description of print settings from p. 23 of manual:
# ESC 7 n1 n2 n3 Setting Control Parameter Command
# Decimal: 27 55 n1 n2 n3
# max heating dots, heating time, heating interval
# n1 = 0-255 Max heat dots, Unit (8dots), Default: 7 (64 dots)
# n2 = 3-255 Heating time, Unit (10us), Default: 80 (800us)
# n3 = 0-255 Heating interval, Unit (10us), Default: 2 (20us)
# The more max heating dots, the more peak current
# will cost when printing, the faster printing speed.
# The max heating dots is 8*(n1+1). The more heating
# time, the more density, but the slower printing
# speed. If heating time is too short, blank page
# may occur. The more heating interval, the more
# clear, but the slower printing speed.
heatTime = kwargs.get('heattime', self.defaultHeatTime)
self.writeBytes(
27, # Esc
55, # 7 (print settings)
11, # Heat dots
heatTime, # Lib default
40) # Heat interval
# Description of print density from p. 23 of manual:
# DC2 # n Set printing density
# Decimal: 18 35 n
# D4..D0 of n is used to set the printing density.
# Density is 50% + 5% * n(D4-D0) printing density.
# D7..D5 of n is used to set the printing break time.
# Break time is n(D7-D5)*250us.
# (Unsure of default values -- not documented)
printDensity = 10 # 100%
printBreakTime = 2 # 500 uS
self.writeBytes(
18, # DC2
35, # Print density
(printBreakTime << 5) | printDensity)
self.dotPrintTime = 0.03
self.dotFeedTime = 0.0021
else:
self.reset() # Inits some vars
# Because there's no flow control between the printer and computer,
# special care must be taken to avoid overrunning the printer's
# buffer. Serial output is throttled based on serial speed as well
# as an estimate of the device's print and feed rates (relatively
# slow, being bound to moving parts and physical reality). After
# an operation is issued to the printer (e.g. bitmap print), a
# timeout is set before which any other printer operations will be
# suspended. This is generally more efficient than using a delay
# in that it allows the calling code to continue with other duties
# (e.g. receiving or decoding an image) while the printer
# physically completes the task.
# Sets estimated completion time for a just-issued task.
def timeoutSet(self, x):
self.resumeTime = time.time() + x
# Waits (if necessary) for the prior task to complete.
def timeoutWait(self):
if self.writeToStdout is False:
while (time.time() - self.resumeTime) < 0: pass
# Printer performance may vary based on the power supply voltage,
# thickness of paper, phase of the moon and other seemingly random
# variables. This method sets the times (in microseconds) for the
# paper to advance one vertical 'dot' when printing and feeding.
# For example, in the default initialized state, normal-sized text
# is 24 dots tall and the line spacing is 32 dots, so the time for
# one line to be issued is approximately 24 * print time + 8 * feed
# time. The default print and feed times are based on a random
# test unit, but as stated above your reality may be influenced by
# many factors. This lets you tweak the timing to avoid excessive
# delays and/or overrunning the printer buffer.
def setTimes(self, p, f):
# Units are in microseconds for
# compatibility with Arduino library
self.dotPrintTime = p / 1000000.0
self.dotFeedTime = f / 1000000.0
# 'Raw' byte-writing method
def writeBytes(self, *args):
if self.writeToStdout:
for arg in args:
sys.stdout.write(bytes([arg]))
else:
for arg in args:
self.timeoutWait()
self.timeoutSet(len(args) * self.byteTime)
super(Adafruit_Thermal, self).write(bytes([arg]))
# Override write() method to keep track of paper feed.
def write(self, *data):
for i in range(len(data)):
c = data[i]
if self.writeToStdout:
sys.stdout.write(c)
continue
if c != 0x13:
self.timeoutWait()
super(Adafruit_Thermal, self).write(c)
d = self.byteTime
if ((c == '\n') or
(self.column == self.maxColumn)):
# Newline or wrap
if self.prevByte == '\n':
# Feed line (blank)
d += ((self.charHeight +
self.lineSpacing) *
self.dotFeedTime)
else:
# Text line
d += ((self.charHeight *
self.dotPrintTime) +
(self.lineSpacing *
self.dotFeedTime))
self.column = 0
# Treat wrap as newline
# on next pass
c = '\n'
else:
self.column += 1
self.timeoutSet(d)
self.prevByte = c
# The bulk of this method was moved into __init__,
# but this is left here for compatibility with older
# code that might get ported directly from Arduino.
def begin(self, heatTime=defaultHeatTime):
self.writeBytes(
27, # Esc
55, # 7 (print settings)
11, # Heat dots
heatTime,
40) # Heat interval
def reset(self):
self.writeBytes(27, 64) # Esc @ = init command
self.prevByte = '\n' # Treat as if prior line is blank
self.column = 0
self.maxColumn = 32
self.charHeight = 24
self.lineSpacing = 6
self.barcodeHeight = 50
if self.firmwareVersion >= 264:
# Configure tab stops on recent printers
self.writeBytes(27, 68) # Set tab stops
self.writeBytes( 4, 8, 12, 16) # every 4 columns,
self.writeBytes(20, 24, 28, 0) # 0 is end-of-list.
# Reset text formatting parameters.
def setDefault(self):
self.online()
self.justify('L')
self.inverseOff()
self.doubleHeightOff()
self.setLineHeight(30)
self.boldOff()
self.underlineOff()
self.setBarcodeHeight(50)
self.setSize('s')
self.setCharset()
self.setCodePage()
def test(self):
self.write("Hello world!".encode('cp437', 'ignore'))
self.feed(2)
def testPage(self):
self.writeBytes(18, 84)
self.timeoutSet(
self.dotPrintTime * 24 * 26 +
self.dotFeedTime * (6 * 26 + 30))
def setBarcodeHeight(self, val=50):
if val < 1: val = 1
self.barcodeHeight = val
self.writeBytes(29, 104, val)
UPC_A = 0
UPC_E = 1
EAN13 = 2
EAN8 = 3
CODE39 = 4
I25 = 5
CODEBAR = 6
CODE93 = 7
CODE128 = 8
CODE11 = 9
MSI = 10
ITF = 11
CODABAR = 12
def printBarcode(self, text, type):
newDict = { # UPC codes & values for firmwareVersion >= 264
self.UPC_A : 65,
self.UPC_E : 66,
self.EAN13 : 67,
self.EAN8 : 68,
self.CODE39 : 69,
self.ITF : 70,
self.CODABAR : 71,
self.CODE93 : 72,
self.CODE128 : 73,
self.I25 : -1, # NOT IN NEW FIRMWARE
self.CODEBAR : -1,
self.CODE11 : -1,
self.MSI : -1
}
oldDict = { # UPC codes & values for firmwareVersion < 264
self.UPC_A : 0,
self.UPC_E : 1,
self.EAN13 : 2,
self.EAN8 : 3,
self.CODE39 : 4,
self.I25 : 5,
self.CODEBAR : 6,
self.CODE93 : 7,
self.CODE128 : 8,
self.CODE11 : 9,
self.MSI : 10,
self.ITF : -1, # NOT IN OLD FIRMWARE
self.CODABAR : -1
}
if self.firmwareVersion >= 264:
n = newDict[type]
else:
n = oldDict[type]
if n == -1: return
self.feed(1) # Recent firmware requires this?
self.writeBytes(
29, 72, 2, # Print label below barcode
29, 119, 3, # Barcode width
29, 107, n) # Barcode type
self.timeoutWait()
self.timeoutSet((self.barcodeHeight + 40) * self.dotPrintTime)
# Print string
if self.firmwareVersion >= 264:
# Recent firmware: write length byte + string sans NUL
n = len(text)
if n > 255: n = 255
if self.writeToStdout:
sys.stdout.write((chr(n)).encode('cp437', 'ignore'))
for i in range(n):
sys.stdout.write(text[i].encode('utf-8', 'ignore'))
else:
super(Adafruit_Thermal, self).write((chr(n)).encode('utf-8', 'ignore'))
for i in range(n):
super(Adafruit_Thermal,
self).write(text[i].encode('utf-8', 'ignore'))
else:
# Older firmware: write string + NUL
if self.writeToStdout:
sys.stdout.write(text.encode('utf-8', 'ignore'))
else:
super(Adafruit_Thermal, self).write(text.encode('utf-8', 'ignore'))
self.prevByte = '\n'
# === Character commands ===
INVERSE_MASK = (1 << 1) # Not in 2.6.8 firmware (see inverseOn())
UPDOWN_MASK = (1 << 2)
BOLD_MASK = (1 << 3)
DOUBLE_HEIGHT_MASK = (1 << 4)
DOUBLE_WIDTH_MASK = (1 << 5)
STRIKE_MASK = (1 << 6)
def setPrintMode(self, mask):
self.printMode |= mask
self.writePrintMode()
if self.printMode & self.DOUBLE_HEIGHT_MASK:
self.charHeight = 48
else:
self.charHeight = 24
if self.printMode & self.DOUBLE_WIDTH_MASK:
self.maxColumn = 16
else:
self.maxColumn = 32
def unsetPrintMode(self, mask):
self.printMode &= ~mask
self.writePrintMode()
if self.printMode & self.DOUBLE_HEIGHT_MASK:
self.charHeight = 48
else:
self.charHeight = 24
if self.printMode & self.DOUBLE_WIDTH_MASK:
self.maxColumn = 16
else:
self.maxColumn = 32
def writePrintMode(self):
self.writeBytes(27, 33, self.printMode)
def normal(self):
self.printMode = 0
self.writePrintMode()
def inverseOn(self):
if self.firmwareVersion >= 268:
self.writeBytes(29, 66, 1)
else:
self.setPrintMode(self.INVERSE_MASK)
def inverseOff(self):
if self.firmwareVersion >= 268:
self.writeBytes(29, 66, 0)
else:
self.unsetPrintMode(self.INVERSE_MASK)
def upsideDownOn(self):
self.setPrintMode(self.UPDOWN_MASK)
def upsideDownOff(self):
self.unsetPrintMode(self.UPDOWN_MASK)
def doubleHeightOn(self):
self.setPrintMode(self.DOUBLE_HEIGHT_MASK)
def doubleHeightOff(self):
self.unsetPrintMode(self.DOUBLE_HEIGHT_MASK)
def doubleWidthOn(self):
self.setPrintMode(self.DOUBLE_WIDTH_MASK)
def doubleWidthOff(self):
self.unsetPrintMode(self.DOUBLE_WIDTH_MASK)
def strikeOn(self):
self.setPrintMode(self.STRIKE_MASK)
def strikeOff(self):
self.unsetPrintMode(self.STRIKE_MASK)
def boldOn(self):
self.setPrintMode(self.BOLD_MASK)
def boldOff(self):
self.unsetPrintMode(self.BOLD_MASK)
def justify(self, value):
c = value.upper()
if c == 'C':
pos = 1
elif c == 'R':
pos = 2
else:
pos = 0
self.writeBytes(0x1B, 0x61, pos)
# Feeds by the specified number of lines
def feed(self, x=1):
if self.firmwareVersion >= 264:
self.writeBytes(27, 100, x)
self.timeoutSet(self.dotFeedTime * self.charHeight)
self.prevByte = '\n'
self.column = 0
else:
# datasheet claims sending bytes 27, 100, <x> works,
# but it feeds much more than that. So, manually:
while x > 0:
self.write('\n'.encode('cp437', 'ignore'))
x -= 1
# Feeds by the specified number of individual pixel rows
def feedRows(self, rows):
self.writeBytes(27, 74, rows)
self.timeoutSet(rows * dotFeedTime)
self.prevByte = '\n'
self.column = 0
def flush(self):
self.writeBytes(12) # ASCII FF
def setSize(self, value):
c = value.upper()
if c == 'L': # Large: double width and height
size = 0x11
self.charHeight = 48
self.maxColumn = 16
elif c == 'M': # Medium: double height
size = 0x01
self.charHeight = 48
self.maxColumn = 32
else: # Small: standard width and height
size = 0x00
self.charHeight = 24
self.maxColumn = 32
self.writeBytes(29, 33, size)
prevByte = '\n' # Setting the size adds a linefeed
# Underlines of different weights can be produced:
# 0 - no underline
# 1 - normal underline
# 2 - thick underline
def underlineOn(self, weight=1):
if weight > 2: weight = 2
self.writeBytes(27, 45, weight)
def underlineOff(self):
self.writeBytes(27, 45, 0)
def printBitmap(self, w, h, bitmap, LaaT=False):
rowBytes = math.floor((w + 7) / 8) # Round up to next byte boundary
if rowBytes >= 48:
rowBytesClipped = 48 # 384 pixels max width
else:
rowBytesClipped = rowBytes
# if LaaT (line-at-a-time) is True, print bitmaps
# scanline-at-a-time (rather than in chunks).
# This tends to make for much cleaner printing
# (no feed gaps) on large images...but has the
# opposite effect on small images that would fit
# in a single 'chunk', so use carefully!
if LaaT: maxChunkHeight = 1
else: maxChunkHeight = 255
i = 0
for rowStart in range(0, h, maxChunkHeight):
chunkHeight = h - rowStart
if chunkHeight > maxChunkHeight:
chunkHeight = maxChunkHeight
# Timeout wait happens here
self.writeBytes(18, 42, chunkHeight, rowBytesClipped)
for y in range(chunkHeight):
for x in range(rowBytesClipped):
if self.writeToStdout:
sys.stdout.write(bytes([bitmap[i]]))
else:
super(Adafruit_Thermal,
self).write(bytes([bitmap[i]]))
i += 1
i += rowBytes - rowBytesClipped
self.timeoutSet(chunkHeight * self.dotPrintTime)
self.prevByte = '\n'
# Print Image. Requires Python Imaging Library. This is
# specific to the Python port and not present in the Arduino
# library. Image will be cropped to 384 pixels width if
# necessary, and converted to 1-bit w/diffusion dithering.
# For any other behavior (scale, B&W threshold, etc.), use
# the Imaging Library to perform such operations before
# passing the result to this function.
def printImage(self, image_file, LaaT=False):
from PIL import Image
# image = Image.open(image_file)
image = image_file
if image.mode != '1':
image = image.convert('1')
width = image.size[0]
height = image.size[1]
if width > 384:
width = 384
rowBytes = math.floor((width + 7) / 8)
bitmap = bytearray(rowBytes * height)
pixels = image.load()
for y in range(height):
n = y * rowBytes
x = 0
for b in range(rowBytes):
sum = 0
bit = 128
while bit > 0:
if x >= width: break
if pixels[x, y] == 0:
sum |= bit
x += 1
bit >>= 1
bitmap[n + b] = sum
self.printBitmap(width, height, bitmap, LaaT)
# Take the printer offline. Print commands sent after this
# will be ignored until 'online' is called.
def offline(self):
self.writeBytes(27, 61, 0)
# Take the printer online. Subsequent print commands will be obeyed.
def online(self):
self.writeBytes(27, 61, 1)
# Put the printer into a low-energy state immediately.
def sleep(self):
self.sleepAfter(1) # Can't be 0, that means "don't sleep"
# Put the printer into a low-energy state after
# the given number of seconds.
def sleepAfter(self, seconds):
if self.firmwareVersion >= 264:
self.writeBytes(27, 56, seconds & 0xFF, seconds >> 8)
else:
self.writeBytes(27, 56, seconds)
def wake(self):
self.timeoutSet(0)
self.writeBytes(255)
if self.firmwareVersion >= 264:
time.sleep(0.05) # 50 ms
self.writeBytes(27, 118, 0) # Sleep off (important!)
else:
for i in range(10):
self.writeBytes(27)
self.timeoutSet(0.1)
# Empty method, included for compatibility
# with existing code ported from Arduino.
def listen(self):
pass
# Check the status of the paper using the printers self reporting
# ability. Doesn't match the datasheet...
# Returns True for paper, False for no paper.
def hasPaper(self):
if self.firmwareVersion >= 264:
self.writeBytes(27, 118, 0)
else:
self.writeBytes(29, 114, 0)
# Bit 2 of response seems to be paper status
stat = ord(self.read(1)) & 0b00000100
# If set, we have paper; if clear, no paper
return stat == 0
def setLineHeight(self, val=32):
if val < 24: val = 24
self.lineSpacing = val - 24
# The printer doesn't take into account the current text
# height when setting line height, making this more akin
# to inter-line spacing. Default line spacing is 32
# (char height of 24, line spacing of 8).
self.writeBytes(27, 51, val)
CHARSET_USA = 0
CHARSET_FRANCE = 1
CHARSET_GERMANY = 2
CHARSET_UK = 3
CHARSET_DENMARK1 = 4
CHARSET_SWEDEN = 5
CHARSET_ITALY = 6
CHARSET_SPAIN1 = 7
CHARSET_JAPAN = 8
CHARSET_NORWAY = 9
CHARSET_DENMARK2 = 10
CHARSET_SPAIN2 = 11
CHARSET_LATINAMERICA = 12
CHARSET_KOREA = 13
CHARSET_SLOVENIA = 14
CHARSET_CROATIA = 14
CHARSET_CHINA = 15
# Alters some chars in ASCII 0x23-0x7E range; see datasheet
def setCharset(self, val=0):
if val > 15: val = 15
self.writeBytes(27, 82, val)
CODEPAGE_CP437 = 0 # USA, Standard Europe
CODEPAGE_KATAKANA = 1
CODEPAGE_CP850 = 2 # Multilingual
CODEPAGE_CP860 = 3 # Portuguese
CODEPAGE_CP863 = 4 # Canadian-French
CODEPAGE_CP865 = 5 # Nordic
CODEPAGE_WCP1251 = 6 # Cyrillic
CODEPAGE_CP866 = 7 # Cyrillic #2
CODEPAGE_MIK = 8 # Cyrillic/Bulgarian
CODEPAGE_CP755 = 9 # East Europe, Latvian 2
CODEPAGE_IRAN = 10
CODEPAGE_CP862 = 15 # Hebrew
CODEPAGE_WCP1252 = 16 # Latin 1
CODEPAGE_WCP1253 = 17 # Greek
CODEPAGE_CP852 = 18 # Latin 2
CODEPAGE_CP858 = 19 # Multilingual Latin 1 + Euro
CODEPAGE_IRAN2 = 20
CODEPAGE_LATVIAN = 21
CODEPAGE_CP864 = 22 # Arabic
CODEPAGE_ISO_8859_1 = 23 # West Europe
CODEPAGE_CP737 = 24 # Greek
CODEPAGE_WCP1257 = 25 # Baltic
CODEPAGE_THAI = 26
CODEPAGE_CP720 = 27 # Arabic
CODEPAGE_CP855 = 28
CODEPAGE_CP857 = 29 # Turkish
CODEPAGE_WCP1250 = 30 # Central Europe
CODEPAGE_CP775 = 31
CODEPAGE_WCP1254 = 32 # Turkish
CODEPAGE_WCP1255 = 33 # Hebrew
CODEPAGE_WCP1256 = 34 # Arabic
CODEPAGE_WCP1258 = 35 # Vietnam
CODEPAGE_ISO_8859_2 = 36 # Latin 2
CODEPAGE_ISO_8859_3 = 37 # Latin 3
CODEPAGE_ISO_8859_4 = 38 # Baltic
CODEPAGE_ISO_8859_5 = 39 # Cyrillic
CODEPAGE_ISO_8859_6 = 40 # Arabic
CODEPAGE_ISO_8859_7 = 41 # Greek
CODEPAGE_ISO_8859_8 = 42 # Hebrew
CODEPAGE_ISO_8859_9 = 43 # Turkish
CODEPAGE_ISO_8859_15 = 44 # Latin 3
CODEPAGE_THAI2 = 45
CODEPAGE_CP856 = 46
CODEPAGE_CP874 = 47
# Selects alt symbols for 'upper' ASCII values 0x80-0xFF
def setCodePage(self, val=0):
if val > 47: val = 47
self.writeBytes(27, 116, val)
# Copied from Arduino lib for parity; may not work on all printers
def tab(self):
self.writeBytes(9)
self.column = (self.column + 4) & 0xFC
# Copied from Arduino lib for parity; may not work on all printers
def setCharSpacing(self, spacing):
self.writeBytes(27, 32, spacing)
# Overloading print() in Python pre-3.0 is dirty pool,
# but these are here to provide more direct compatibility
# with existing code written for the Arduino library.
def print(self, *args, **kwargs):
for arg in args:
self.write((str(arg)).encode('cp437', 'ignore'))
# For Arduino code compatibility again
def println(self, *args, **kwargs):
for arg in args:
self.write((str(arg)).encode('cp437', 'ignore'))
self.write('\n'.encode('cp437', 'ignore'))