#!/usr/bin/env python # coding=utf-8 # # Copyright (C) 2009 Kazuhiko Arase (http://www.d-project.com/) # 2010 Bulia Byak # 2018 Kirill Okhotnikov # # 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. # # You should have received a copy of the GNU General Public License # along with this program; if not, write to the Free Software # Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110, USA. # """ Provide the QR Code rendering. """ from __future__ import print_function from itertools import product import inkex from inkex import Group, Rectangle, Use, PathElement from inkex.localization import inkex_gettext as _ class QRLengthError(Exception): def __init__(self, message): self.message = message class QRCode(object): PAD0 = 0xEC PAD1 = 0x11 def __init__(self, correction): self.typeNumber = 1 self.errorCorrectLevel = correction self.qrDataList = [] self.modules = [] self.moduleCount = 0 def getTypeNumber(self): return self.typeNumber def setTypeNumber(self, typeNumber): self.typeNumber = typeNumber def clearData(self): self.qrDataList = [] def addData(self, data): self.qrDataList.append(data) def getDataCount(self): return len(self.qrDataList) def getData(self, index): return self.qrDataList[index] def isDark(self, row, col): return self.modules[row][col] if self.modules[row][col] is not None else False def getModuleCount(self): return self.moduleCount def make(self): self._make(False, self._getBestMaskPattern()) def _getBestMaskPattern(self): minLostPoint = 0 pattern = 0 for i in range(8): self._make(True, i) lostPoint = QRUtil.getLostPoint(self) if i == 0 or minLostPoint > lostPoint: minLostPoint = lostPoint pattern = i return pattern def _make(self, test, maskPattern): self.moduleCount = self.typeNumber * 4 + 17 self.modules = [[None] * self.moduleCount for i in range(self.moduleCount)] self._setupPositionProbePattern(0, 0) self._setupPositionProbePattern(self.moduleCount - 7, 0) self._setupPositionProbePattern(0, self.moduleCount - 7) self._setupPositionAdjustPattern() self._setupTimingPattern() self._setupTypeInfo(test, maskPattern) if self.typeNumber >= 7: self._setupTypeNumber(test) data = QRCode._createData( self.typeNumber, self.errorCorrectLevel, self.qrDataList ) self._mapData(data, maskPattern) def _mapData(self, data, maskPattern): rows = list(range(self.moduleCount)) cols = [ col - 1 if col <= 6 else col for col in range(self.moduleCount - 1, 0, -2) ] maskFunc = QRUtil.getMaskFunction(maskPattern) byteIndex = 0 bitIndex = 7 for col in cols: rows.reverse() for row in rows: for c in range(2): if self.modules[row][col - c] is None: dark = False if byteIndex < len(data): dark = ((data[byteIndex] >> bitIndex) & 1) == 1 if maskFunc(row, col - c): dark = not dark self.modules[row][col - c] = dark bitIndex -= 1 if bitIndex == -1: byteIndex += 1 bitIndex = 7 def _setupPositionAdjustPattern(self): pos = QRUtil.getPatternPosition(self.typeNumber) for row in pos: for col in pos: if self.modules[row][col] is not None: continue for r in range(-2, 3): for c in range(-2, 3): self.modules[row + r][col + c] = ( r == -2 or r == 2 or c == -2 or c == 2 or (r == 0 and c == 0) ) def _setupPositionProbePattern(self, row, col): for r in range(-1, 8): for c in range(-1, 8): if ( row + r <= -1 or self.moduleCount <= row + r or col + c <= -1 or self.moduleCount <= col + c ): continue self.modules[row + r][col + c] = ( (0 <= r <= 6 and (c == 0 or c == 6)) or (0 <= c <= 6 and (r == 0 or r == 6)) or (2 <= r <= 4 and 2 <= c <= 4) ) def _setupTimingPattern(self): for r in range(8, self.moduleCount - 8): if self.modules[r][6] is not None: continue self.modules[r][6] = r % 2 == 0 for c in range(8, self.moduleCount - 8): if self.modules[6][c] is not None: continue self.modules[6][c] = c % 2 == 0 def _setupTypeNumber(self, test): bits = QRUtil.getBCHTypeNumber(self.typeNumber) for i in range(18): self.modules[i // 3][i % 3 + self.moduleCount - 8 - 3] = ( not test and ((bits >> i) & 1) == 1 ) for i in range(18): self.modules[i % 3 + self.moduleCount - 8 - 3][i // 3] = ( not test and ((bits >> i) & 1) == 1 ) def _setupTypeInfo(self, test, maskPattern): data = (self.errorCorrectLevel << 3) | maskPattern bits = QRUtil.getBCHTypeInfo(data) # vertical for i in range(15): mod = not test and ((bits >> i) & 1) == 1 if i < 6: self.modules[i][8] = mod elif i < 8: self.modules[i + 1][8] = mod else: self.modules[self.moduleCount - 15 + i][8] = mod # horizontal for i in range(15): mod = not test and ((bits >> i) & 1) == 1 if i < 8: self.modules[8][self.moduleCount - i - 1] = mod elif i < 9: self.modules[8][15 - i - 1 + 1] = mod else: self.modules[8][15 - i - 1] = mod # fixed self.modules[self.moduleCount - 8][8] = not test @staticmethod def _createData(typeNumber, errorCorrectLevel, dataArray): rsBlocks = RSBlock.getRSBlocks(typeNumber, errorCorrectLevel) buffer = BitBuffer() for data in dataArray: buffer.put(data.getMode(), 4) buffer.put(data.getLength(), data.getLengthInBits(typeNumber)) data.write(buffer) totalDataCount = sum(rsBlock.getDataCount() for rsBlock in rsBlocks) if buffer.getLengthInBits() > totalDataCount * 8: raise QRLengthError( "code length overflow. (%s>%s)" % (buffer.getLengthInBits(), totalDataCount * 8) ) # end code if buffer.getLengthInBits() + 4 <= totalDataCount * 8: buffer.put(0, 4) # padding while buffer.getLengthInBits() % 8 != 0: buffer.put(False, 1) # padding while True: if buffer.getLengthInBits() >= totalDataCount * 8: break buffer.put(QRCode.PAD0, 8) if buffer.getLengthInBits() >= totalDataCount * 8: break buffer.put(QRCode.PAD1, 8) return QRCode._createBytes(buffer, rsBlocks) @staticmethod def _createBytes(buffer, rsBlocks): offset = 0 maxDcCount = 0 maxEcCount = 0 dcdata = [None] * len(rsBlocks) ecdata = [None] * len(rsBlocks) for r in range(len(rsBlocks)): dcCount = rsBlocks[r].getDataCount() ecCount = rsBlocks[r].getTotalCount() - dcCount maxDcCount = max(maxDcCount, dcCount) maxEcCount = max(maxEcCount, ecCount) dcdata[r] = [0] * dcCount for i in range(len(dcdata[r])): dcdata[r][i] = 0xFF & buffer.getBuffer()[i + offset] offset += dcCount rsPoly = QRUtil.getErrorCorrectPolynomial(ecCount) rawPoly = Polynomial(dcdata[r], rsPoly.getLength() - 1) modPoly = rawPoly.mod(rsPoly) ecdata[r] = [0] * (rsPoly.getLength() - 1) for i in range(len(ecdata[r])): modIndex = i + modPoly.getLength() - len(ecdata[r]) ecdata[r][i] = modPoly.get(modIndex) if modIndex >= 0 else 0 totalCodeCount = sum(rsBlock.getTotalCount() for rsBlock in rsBlocks) data = [0] * totalCodeCount index = 0 for i in range(maxDcCount): for r in range(len(rsBlocks)): if i < len(dcdata[r]): data[index] = dcdata[r][i] index += 1 for i in range(maxEcCount): for r in range(len(rsBlocks)): if i < len(ecdata[r]): data[index] = ecdata[r][i] index += 1 return data @staticmethod def getMinimumQRCode(data, errorCorrectLevel): qr = QRCode(correction=errorCorrectLevel) qr.addData(data) lv = 1 rv = 40 while rv - lv > 0: mid = (3 * lv + rv) // 4 qr.setTypeNumber(mid) try: qr.make() except QRLengthError: if mid == 40: raise inkex.AbortExtension( _("The string is too large to represent as QR code") ) lv = mid + 1 else: rv = mid qr.setTypeNumber(rv) qr.make() return qr class Mode(object): MODE_NUMBER = 1 << 0 MODE_ALPHA_NUM = 1 << 1 MODE_8BIT_BYTE = 1 << 2 MODE_KANJI = 1 << 3 class MaskPattern(object): PATTERN000 = 0 PATTERN001 = 1 PATTERN010 = 2 PATTERN011 = 3 PATTERN100 = 4 PATTERN101 = 5 PATTERN110 = 6 PATTERN111 = 7 class QRUtil(object): @staticmethod def getPatternPosition(typeNumber): return QRUtil.PATTERN_POSITION_TABLE[typeNumber - 1] PATTERN_POSITION_TABLE = [ [], [6, 18], [6, 22], [6, 26], [6, 30], [6, 34], [6, 22, 38], [6, 24, 42], [6, 26, 46], [6, 28, 50], [6, 30, 54], [6, 32, 58], [6, 34, 62], [6, 26, 46, 66], [6, 26, 48, 70], [6, 26, 50, 74], [6, 30, 54, 78], [6, 30, 56, 82], [6, 30, 58, 86], [6, 34, 62, 90], [6, 28, 50, 72, 94], [6, 26, 50, 74, 98], [6, 30, 54, 78, 102], [6, 28, 54, 80, 106], [6, 32, 58, 84, 110], [6, 30, 58, 86, 114], [6, 34, 62, 90, 118], [6, 26, 50, 74, 98, 122], [6, 30, 54, 78, 102, 126], [6, 26, 52, 78, 104, 130], [6, 30, 56, 82, 108, 134], [6, 34, 60, 86, 112, 138], [6, 30, 58, 86, 114, 142], [6, 34, 62, 90, 118, 146], [6, 30, 54, 78, 102, 126, 150], [6, 24, 50, 76, 102, 128, 154], [6, 28, 54, 80, 106, 132, 158], [6, 32, 58, 84, 110, 136, 162], [6, 26, 54, 82, 110, 138, 166], [6, 30, 58, 86, 114, 142, 170], ] @staticmethod def getErrorCorrectPolynomial(errorCorrectLength): a = Polynomial([1]) for i in range(errorCorrectLength): a = a.multiply(Polynomial([1, QRMath.gexp(i)])) return a @staticmethod def getMaskFunction(maskPattern): return { MaskPattern.PATTERN000: lambda i, j: (i + j) % 2 == 0, MaskPattern.PATTERN001: lambda i, j: i % 2 == 0, MaskPattern.PATTERN010: lambda i, j: j % 3 == 0, MaskPattern.PATTERN011: lambda i, j: (i + j) % 3 == 0, MaskPattern.PATTERN100: lambda i, j: (i // 2 + j // 3) % 2 == 0, MaskPattern.PATTERN101: lambda i, j: (i * j) % 2 + (i * j) % 3 == 0, MaskPattern.PATTERN110: lambda i, j: ((i * j) % 2 + (i * j) % 3) % 2 == 0, MaskPattern.PATTERN111: lambda i, j: ((i * j) % 3 + (i + j) % 2) % 2 == 0, }[maskPattern] @staticmethod def getLostPoint(qrcode): moduleCount = qrcode.getModuleCount() lostPoint = 0 # LEVEL1 for row in range(moduleCount): for col in range(moduleCount): sameCount = 0 dark = qrcode.isDark(row, col) for r in range(-1, 2): if row + r < 0 or moduleCount <= row + r: continue for c in range(-1, 2): if col + c < 0 or moduleCount <= col + c: continue if r == 0 and c == 0: continue if dark == qrcode.isDark(row + r, col + c): sameCount += 1 if sameCount > 5: lostPoint += 3 + sameCount - 5 # LEVEL2 for row in range(moduleCount - 1): for col in range(moduleCount - 1): count = 0 if qrcode.isDark(row, col): count += 1 if qrcode.isDark(row + 1, col): count += 1 if qrcode.isDark(row, col + 1): count += 1 if qrcode.isDark(row + 1, col + 1): count += 1 if count == 0 or count == 4: lostPoint += 3 # LEVEL3 for row in range(moduleCount): for col in range(moduleCount - 6): if ( qrcode.isDark(row, col) and not qrcode.isDark(row, col + 1) and qrcode.isDark(row, col + 2) and qrcode.isDark(row, col + 3) and qrcode.isDark(row, col + 4) and not qrcode.isDark(row, col + 5) and qrcode.isDark(row, col + 6) ): lostPoint += 40 for col in range(moduleCount): for row in range(moduleCount - 6): if ( qrcode.isDark(row, col) and not qrcode.isDark(row + 1, col) and qrcode.isDark(row + 2, col) and qrcode.isDark(row + 3, col) and qrcode.isDark(row + 4, col) and not qrcode.isDark(row + 5, col) and qrcode.isDark(row + 6, col) ): lostPoint += 40 # LEVEL4 darkCount = 0 for col in range(moduleCount): for row in range(moduleCount): if qrcode.isDark(row, col): darkCount += 1 ratio = abs(100 * darkCount // moduleCount // moduleCount - 50) // 5 lostPoint += ratio * 10 return lostPoint G15 = (1 << 10) | (1 << 8) | (1 << 5) | (1 << 4) | (1 << 2) | (1 << 1) | (1 << 0) G18 = ( (1 << 12) | (1 << 11) | (1 << 10) | (1 << 9) | (1 << 8) | (1 << 5) | (1 << 2) | (1 << 0) ) G15_MASK = (1 << 14) | (1 << 12) | (1 << 10) | (1 << 4) | (1 << 1) @staticmethod def getBCHTypeInfo(data): d = data << 10 while QRUtil.getBCHDigit(d) - QRUtil.getBCHDigit(QRUtil.G15) >= 0: d ^= QRUtil.G15 << (QRUtil.getBCHDigit(d) - QRUtil.getBCHDigit(QRUtil.G15)) return ((data << 10) | d) ^ QRUtil.G15_MASK @staticmethod def getBCHTypeNumber(data): d = data << 12 while QRUtil.getBCHDigit(d) - QRUtil.getBCHDigit(QRUtil.G18) >= 0: d ^= QRUtil.G18 << (QRUtil.getBCHDigit(d) - QRUtil.getBCHDigit(QRUtil.G18)) return (data << 12) | d @staticmethod def getBCHDigit(data): digit = 0 while data != 0: digit += 1 data >>= 1 return digit class QRData(object): def __init__(self, mode, data): self._mode = mode self.data = data def getMode(self): return self._mode def getData(self): return self.data def getLength(self): return len(self.data) # @abstractmethod def write(self, buffer): pass def getLengthInBits(self, type): if 1 <= type < 10: # 1 - 9 return { Mode.MODE_NUMBER: 10, Mode.MODE_ALPHA_NUM: 9, Mode.MODE_8BIT_BYTE: 8, Mode.MODE_KANJI: 8, }[self._mode] elif type < 27: # 10 - 26 return { Mode.MODE_NUMBER: 12, Mode.MODE_ALPHA_NUM: 11, Mode.MODE_8BIT_BYTE: 16, Mode.MODE_KANJI: 10, }[self._mode] elif type < 41: # 27 - 40 return { Mode.MODE_NUMBER: 14, Mode.MODE_ALPHA_NUM: 13, Mode.MODE_8BIT_BYTE: 16, Mode.MODE_KANJI: 12, }[self._mode] else: raise Exception("type:%s" % type) class QR8BitByte(QRData): def __init__(self, data): super(QR8BitByte, self).__init__(Mode.MODE_8BIT_BYTE, data) if isinstance(data, str): data = data.encode("ascii", "ignore") if not isinstance(data, bytes): raise ValueError("Data must be in bytes!") def write(self, buffer): for d in self.data: buffer.put(ord(d), 8) class QRAlphaNum(QRData): def __init__(self, data): super(QRAlphaNum, self).__init__(Mode.MODE_ALPHA_NUM, data) def write(self, buffer): i = 0 while i + 1 < len(self.data): buffer.put( QRAlphaNum._getCode(self.data[i]) * 45 + QRAlphaNum._getCode(self.data[i + 1]), 11, ) i += 2 if i < len(self.data): buffer.put(QRAlphaNum._getCode(self.data[i]), 6) @staticmethod def _getCode(c): if "0" <= c and c <= "9": return ord(c) - ord("0") elif "A" <= c and c <= "Z": return ord(c) - ord("A") + 10 else: dct = { " ": 36, "$": 37, "%": 38, "*": 39, "+": 40, "-": 41, ".": 42, "/": 43, ":": 44, } if c in dct.keys(): return dct[c] else: raise inkex.AbortExtension( _( "Wrong symbol '{}' in alphanumeric representation: Should be [A-Z, 0-9] or {}" ).format(c, dct.keys()) ) class QRNumber(QRData): def __init__(self, data): super(QRNumber, self).__init__(Mode.MODE_NUMBER, data) def write(self, buffer): i = 0 try: while i + 2 < len(self.data): num = int(self.data[i : i + 3]) buffer.put(num, 10) i += 3 if i < len(self.data): ln = 4 if len(self.data) - i == 1 else 7 buffer.put(int(self.data[i:]), ln) except: raise ValueError("The string '{}' is not a valid number".format(self.data)) class QRKanji(QRData): def __init__(self, data): super(QRKanji, self).__init__(Mode.MODE_KANJI, data) raise RuntimeError("Class QRKanji is not implemented") class QRMath(object): EXP_TABLE = None LOG_TABLE = None @staticmethod def _init(): QRMath.EXP_TABLE = [0] * 256 for i in range(256): QRMath.EXP_TABLE[i] = ( 1 << i if i < 8 else QRMath.EXP_TABLE[i - 4] ^ QRMath.EXP_TABLE[i - 5] ^ QRMath.EXP_TABLE[i - 6] ^ QRMath.EXP_TABLE[i - 8] ) QRMath.LOG_TABLE = [0] * 256 for i in range(255): QRMath.LOG_TABLE[QRMath.EXP_TABLE[i]] = i @staticmethod def glog(n): if n < 1: raise Exception("log(%s)" % n) return QRMath.LOG_TABLE[n] @staticmethod def gexp(n): while n < 0: n += 255 while n >= 256: n -= 255 return QRMath.EXP_TABLE[n] # initialize statics QRMath._init() class Polynomial(object): def __init__(self, num, shift=0): offset = 0 length = len(num) while offset < length and num[offset] == 0: offset += 1 self.num = num[offset:] + [0] * shift def get(self, index): return self.num[index] def getLength(self): return len(self.num) def __repr__(self): return ",".join([str(self.get(i)) for i in range(self.getLength())]) def toLogString(self): return ",".join( [str(QRMath.glog(self.get(i))) for i in range(self.getLength())] ) def multiply(self, e): num = [0] * (self.getLength() + e.getLength() - 1) for i in range(self.getLength()): for j in range(e.getLength()): num[i + j] ^= QRMath.gexp( QRMath.glog(self.get(i)) + QRMath.glog(e.get(j)) ) return Polynomial(num) def mod(self, e): if self.getLength() - e.getLength() < 0: return self ratio = QRMath.glog(self.get(0)) - QRMath.glog(e.get(0)) num = self.num[:] for i in range(e.getLength()): num[i] ^= QRMath.gexp(QRMath.glog(e.get(i)) + ratio) return Polynomial(num).mod(e) class RSBlock(object): RS_BLOCK_TABLE = [ # L # M # Q # H # 1 [1, 26, 19], [1, 26, 16], [1, 26, 13], [1, 26, 9], # 2 [1, 44, 34], [1, 44, 28], [1, 44, 22], [1, 44, 16], # 3 [1, 70, 55], [1, 70, 44], [2, 35, 17], [2, 35, 13], # 4 [1, 100, 80], [2, 50, 32], [2, 50, 24], [4, 25, 9], # 5 [1, 134, 108], [2, 67, 43], [2, 33, 15, 2, 34, 16], [2, 33, 11, 2, 34, 12], # 6 [2, 86, 68], [4, 43, 27], [4, 43, 19], [4, 43, 15], # 7 [2, 98, 78], [4, 49, 31], [2, 32, 14, 4, 33, 15], [4, 39, 13, 1, 40, 14], # 8 [2, 121, 97], [2, 60, 38, 2, 61, 39], [4, 40, 18, 2, 41, 19], [4, 40, 14, 2, 41, 15], # 9 [2, 146, 116], [3, 58, 36, 2, 59, 37], [4, 36, 16, 4, 37, 17], [4, 36, 12, 4, 37, 13], # 10 [2, 86, 68, 2, 87, 69], [4, 69, 43, 1, 70, 44], [6, 43, 19, 2, 44, 20], [6, 43, 15, 2, 44, 16], # 11 [4, 101, 81], [1, 80, 50, 4, 81, 51], [4, 50, 22, 4, 51, 23], [3, 36, 12, 8, 37, 13], # 12 [2, 116, 92, 2, 117, 93], [6, 58, 36, 2, 59, 37], [4, 46, 20, 6, 47, 21], [7, 42, 14, 4, 43, 15], # 13 [4, 133, 107], [8, 59, 37, 1, 60, 38], [8, 44, 20, 4, 45, 21], [12, 33, 11, 4, 34, 12], # 14 [3, 145, 115, 1, 146, 116], [4, 64, 40, 5, 65, 41], [11, 36, 16, 5, 37, 17], [11, 36, 12, 5, 37, 13], # 15 [5, 109, 87, 1, 110, 88], [5, 65, 41, 5, 66, 42], [5, 54, 24, 7, 55, 25], [11, 36, 12, 7, 37, 13], # 16 [5, 122, 98, 1, 123, 99], [7, 73, 45, 3, 74, 46], [15, 43, 19, 2, 44, 20], [3, 45, 15, 13, 46, 16], # 17 [1, 135, 107, 5, 136, 108], [10, 74, 46, 1, 75, 47], [1, 50, 22, 15, 51, 23], [2, 42, 14, 17, 43, 15], # 18 [5, 150, 120, 1, 151, 121], [9, 69, 43, 4, 70, 44], [17, 50, 22, 1, 51, 23], [2, 42, 14, 19, 43, 15], # 19 [3, 141, 113, 4, 142, 114], [3, 70, 44, 11, 71, 45], [17, 47, 21, 4, 48, 22], [9, 39, 13, 16, 40, 14], # 20 [3, 135, 107, 5, 136, 108], [3, 67, 41, 13, 68, 42], [15, 54, 24, 5, 55, 25], [15, 43, 15, 10, 44, 16], # 21 [4, 144, 116, 4, 145, 117], [17, 68, 42], [17, 50, 22, 6, 51, 23], [19, 46, 16, 6, 47, 17], # 22 [2, 139, 111, 7, 140, 112], [17, 74, 46], [7, 54, 24, 16, 55, 25], [34, 37, 13], # 23 [4, 151, 121, 5, 152, 122], [4, 75, 47, 14, 76, 48], [11, 54, 24, 14, 55, 25], [16, 45, 15, 14, 46, 16], # 24 [6, 147, 117, 4, 148, 118], [6, 73, 45, 14, 74, 46], [11, 54, 24, 16, 55, 25], [30, 46, 16, 2, 47, 17], # 25 [8, 132, 106, 4, 133, 107], [8, 75, 47, 13, 76, 48], [7, 54, 24, 22, 55, 25], [22, 45, 15, 13, 46, 16], # 26 [10, 142, 114, 2, 143, 115], [19, 74, 46, 4, 75, 47], [28, 50, 22, 6, 51, 23], [33, 46, 16, 4, 47, 17], # 27 [8, 152, 122, 4, 153, 123], [22, 73, 45, 3, 74, 46], [8, 53, 23, 26, 54, 24], [12, 45, 15, 28, 46, 16], # 28 [3, 147, 117, 10, 148, 118], [3, 73, 45, 23, 74, 46], [4, 54, 24, 31, 55, 25], [11, 45, 15, 31, 46, 16], # 29 [7, 146, 116, 7, 147, 117], [21, 73, 45, 7, 74, 46], [1, 53, 23, 37, 54, 24], [19, 45, 15, 26, 46, 16], # 30 [5, 145, 115, 10, 146, 116], [19, 75, 47, 10, 76, 48], [15, 54, 24, 25, 55, 25], [23, 45, 15, 25, 46, 16], # 31 [13, 145, 115, 3, 146, 116], [2, 74, 46, 29, 75, 47], [42, 54, 24, 1, 55, 25], [23, 45, 15, 28, 46, 16], # 32 [17, 145, 115], [10, 74, 46, 23, 75, 47], [10, 54, 24, 35, 55, 25], [19, 45, 15, 35, 46, 16], # 33 [17, 145, 115, 1, 146, 116], [14, 74, 46, 21, 75, 47], [29, 54, 24, 19, 55, 25], [11, 45, 15, 46, 46, 16], # 34 [13, 145, 115, 6, 146, 116], [14, 74, 46, 23, 75, 47], [44, 54, 24, 7, 55, 25], [59, 46, 16, 1, 47, 17], # 35 [12, 151, 121, 7, 152, 122], [12, 75, 47, 26, 76, 48], [39, 54, 24, 14, 55, 25], [22, 45, 15, 41, 46, 16], # 36 [6, 151, 121, 14, 152, 122], [6, 75, 47, 34, 76, 48], [46, 54, 24, 10, 55, 25], [2, 45, 15, 64, 46, 16], # 37 [17, 152, 122, 4, 153, 123], [29, 74, 46, 14, 75, 47], [49, 54, 24, 10, 55, 25], [24, 45, 15, 46, 46, 16], # 38 [4, 152, 122, 18, 153, 123], [13, 74, 46, 32, 75, 47], [48, 54, 24, 14, 55, 25], [42, 45, 15, 32, 46, 16], # 39 [20, 147, 117, 4, 148, 118], [40, 75, 47, 7, 76, 48], [43, 54, 24, 22, 55, 25], [10, 45, 15, 67, 46, 16], # 40 [19, 148, 118, 6, 149, 119], [18, 75, 47, 31, 76, 48], [34, 54, 24, 34, 55, 25], [20, 45, 15, 61, 46, 16], ] def __init__(self, totalCount, dataCount): self.totalCount = totalCount self.dataCount = dataCount def getDataCount(self): return self.dataCount def getTotalCount(self): return self.totalCount def __repr__(self): return "(total=%s,data=%s)" % (self.totalCount, self.dataCount) @staticmethod def getRSBlocks(typeNumber, errorCorrectLevel): rsBlock = RSBlock.getRsBlockTable(typeNumber, errorCorrectLevel) length = len(rsBlock) // 3 list = [] for i in range(length): count = rsBlock[i * 3 + 0] totalCount = rsBlock[i * 3 + 1] dataCount = rsBlock[i * 3 + 2] list += [RSBlock(totalCount, dataCount)] * count return list @staticmethod def getRsBlockTable(typeNumber, errorCorrectLevel): return { 1: RSBlock.RS_BLOCK_TABLE[(typeNumber - 1) * 4 + 0], 0: RSBlock.RS_BLOCK_TABLE[(typeNumber - 1) * 4 + 1], 3: RSBlock.RS_BLOCK_TABLE[(typeNumber - 1) * 4 + 2], 2: RSBlock.RS_BLOCK_TABLE[(typeNumber - 1) * 4 + 3], }[errorCorrectLevel] class BitBuffer(object): def __init__(self, inclements=32): self.inclements = inclements self.buffer = [0] * self.inclements self.length = 0 def getBuffer(self): return self.buffer def getLengthInBits(self): return self.length def get(self, index): return ((self.buffer[index // 8] >> (7 - index % 8)) & 1) == 1 def putBit(self, bit): if self.length == len(self.buffer) * 8: self.buffer += [0] * self.inclements if bit: self.buffer[self.length // 8] |= 0x80 >> (self.length % 8) self.length += 1 def put(self, num, length): for i in range(length): self.putBit(((num >> (length - i - 1)) & 1) == 1) def __repr__(self): return "".join( "1" if self.get(i) else "0" for i in range(self.getLengthInBits()) ) class GridDrawer(object): """Mechanism to draw grids of boxes""" def __init__(self, invert_code, smooth_factor): self.invert_code = invert_code self.smoothFactor = smooth_factor self.grid = None def set_grid(self, grid): if len({len(g) for g in grid}) != 1: raise Exception("The array is not rectangular") else: self.grid = grid def row_count(self): return len(self.grid) if self.grid is not None else 0 def col_count(self): return len(self.grid[0]) if self.row_count() > 0 else 0 def isDark(self, col, row): inside = col >= 0 and 0 <= row < self.row_count() and col < self.col_count() return False if not inside else self.grid[row][col] != self.invert_code @staticmethod def moveByDirection(xyd): dm = {0: (1, 0), 1: (0, -1), 2: (-1, 0), 3: (0, 1)} return xyd[0] + dm[xyd[2]][0], xyd[1] + dm[xyd[2]][1] @staticmethod def makeDirectionsTable(): result = [] for cfg in product(range(2), repeat=4): result.append([]) for d in range(4): if cfg[3 - d] == 0 and cfg[3 - (d - 1) % 4] != 0: result[-1].append(d) return result def createVertexesForAdvDrawer(self): dirTable = self.makeDirectionsTable() result = [] # Create vertex for row in range(self.row_count() + 1): for col in range(self.col_count() + 1): indx = ( (2**0 if self.isDark(col - 0, row - 1) else 0) + (2**1 if self.isDark(col - 1, row - 1) else 0) + (2**2 if self.isDark(col - 1, row - 0) else 0) + (2**3 if self.isDark(col - 0, row - 0) else 0) ) for d in dirTable[indx]: result.append((col, row, d, len(dirTable[indx]) > 1)) return result def getSmoothPosition(self, v, extraSmoothFactor=1.0): vn = self.moveByDirection(v) sc = extraSmoothFactor * self.smoothFactor / 2.0 sc1 = 1.0 - sc return (v[0] * sc1 + vn[0] * sc, v[1] * sc1 + vn[1] * sc), ( v[0] * sc + vn[0] * sc1, v[1] * sc + vn[1] * sc1, ) class QrCode(inkex.GenerateExtension): """Generate QR Code Extension""" def add_arguments(self, pars): pars.add_argument("--text", default="https://inkscape.org") pars.add_argument("--typenumber", type=int, default=0) pars.add_argument("--correctionlevel", type=int, default=0) pars.add_argument("--qrmode", type=int, default=0) pars.add_argument("--encoding", default="latin_1") pars.add_argument("--modulesize", type=float, default=4.0) pars.add_argument("--invert", type=inkex.Boolean, default="false") pars.add_argument( "--drawtype", default="smooth", choices=["smooth", "pathpreset", "selection", "symbol"], ) pars.add_argument( "--smoothness", default="neutral", choices=["neutral", "greedy", "proud"] ) pars.add_argument("--pathtype", default="simple", choices=["simple", "circle"]) pars.add_argument("--smoothval", type=float, default=0.2) pars.add_argument("--symbolid", default="") pars.add_argument("--groupid", default="") def generate(self): scale = self.svg.unittouu("1px") # convert to document units opt = self.options if not opt.text: raise inkex.AbortExtension(_("Please enter an input text")) elif opt.drawtype == "symbol" and opt.symbolid == "": raise inkex.AbortExtension(_("Please enter symbol id")) # for Python 3 ugly hack to represent bytes as str for Python2 compatibility text_str = str(opt.text) cmode = [QR8BitByte, QRNumber, QRAlphaNum, QRKanji][opt.qrmode] text_data = cmode(bytes(opt.text, opt.encoding).decode("latin_1")) grp = Group() grp.set("inkscape:label", "QR Code: " + text_str) if opt.groupid: grp.set("id", opt.groupid) pos_x, pos_y = self.svg.namedview.center grp.transform.add_translate(pos_x, pos_y) if scale: grp.transform.add_scale(scale) # GENERATE THE QRCODE if opt.typenumber == 0: # Automatic QR code size` code = QRCode.getMinimumQRCode(text_data, opt.correctionlevel) else: # Manual QR code size code = QRCode(correction=opt.correctionlevel) code.setTypeNumber(int(opt.typenumber)) code.addData(text_data) code.make() self.boxsize = opt.modulesize self.invert_code = opt.invert self.margin = 4 self.draw = GridDrawer(opt.invert, opt.smoothval) self.draw.set_grid(code.modules) self.render_svg(grp, opt.drawtype) return grp def render_adv(self, greedy): verts = self.draw.createVertexesForAdvDrawer() qrPathStr = "" while len(verts) > 0: vertsIndexStart = len(verts) - 1 vertsIndexCur = vertsIndexStart ringIndexes = [] ci = {} for i, v in enumerate(verts): ci.setdefault(v[0], []).append(i) while True: ringIndexes.append(vertsIndexCur) nextPos = self.draw.moveByDirection(verts[vertsIndexCur]) nextIndexes = [i for i in ci[nextPos[0]] if verts[i][1] == nextPos[1]] if len(nextIndexes) == 0 or len(nextIndexes) > 2: raise Exception("Vertex " + str(next_c) + " has no connections") elif len(nextIndexes) == 1: vertsIndexNext = nextIndexes[0] else: if {verts[nextIndexes[0]][2], verts[nextIndexes[1]][2]} != { (verts[vertsIndexCur][2] - 1) % 4, (verts[vertsIndexCur][2] + 1) % 4, }: raise Exception( "Bad next vertex directions " + str(verts[nextIndexes[0]]) + str(verts[nextIndexes[1]]) ) # Greedy - CCW turn, proud and neutral CW turn vertsIndexNext = ( nextIndexes[0] if (greedy == "g") == ( verts[nextIndexes[0]][2] == (verts[vertsIndexCur][2] + 1) % 4 ) else nextIndexes[1] ) if vertsIndexNext == vertsIndexStart: break vertsIndexCur = vertsIndexNext posStart, _ = self.draw.getSmoothPosition(verts[ringIndexes[0]]) qrPathStr += "M %f,%f " % self.get_svg_pos(posStart[0], posStart[1]) for ri in range(len(ringIndexes)): vc = verts[ringIndexes[ri]] vn = verts[ringIndexes[(ri + 1) % len(ringIndexes)]] if vn[2] != vc[2]: if (greedy != "n") or not vn[3]: # Add bezier # Opt length http://spencermortensen.com/articles/bezier-circle/ # c = 0.552284749 ex = 1 - 0.552284749 _, bs = self.draw.getSmoothPosition(vc) _, bp1 = self.draw.getSmoothPosition(vc, ex) bp2, _ = self.draw.getSmoothPosition(vn, ex) bf, _ = self.draw.getSmoothPosition(vn) qrPathStr += "L %f,%f " % self.get_svg_pos(bs[0], bs[1]) qrPathStr += "C %f,%f %f,%f %f,%f " % ( self.get_svg_pos(bp1[0], bp1[1]) + self.get_svg_pos(bp2[0], bp2[1]) + self.get_svg_pos(bf[0], bf[1]) ) else: # Add straight qrPathStr += "L %f,%f " % self.get_svg_pos(vn[0], vn[1]) qrPathStr += "z " # Delete already processed vertex for i in sorted(ringIndexes, reverse=True): del verts[i] path = PathElement() path.set("d", qrPathStr) return path def render_obsolete(self): for row in range(self.draw.row_count()): for col in range(self.draw.col_count()): if self.draw.isDark(col, row): x, y = self.get_svg_pos(col, row) return Rectangle.new(x, y, self.boxsize, self.boxsize) def render_path(self, pointStr): singlePath = self.get_icon_path_str(pointStr) pathStr = "" for row in range(self.draw.row_count()): for col in range(self.draw.col_count()): if self.draw.isDark(col, row): x, y = self.get_svg_pos(col, row) pathStr += "M %f,%f " % (x, y) + singlePath + " z " path = PathElement() path.set("d", pathStr) return path def render_selection(self): if len(self.svg.selection) > 0: self.options.symbolid = self.svg.selection.first().get_id() else: raise inkex.AbortExtension(_("Please select an element to clone")) return self.render_symbol() def render_symbol(self): symbol = self.svg.getElementById(self.options.symbolid) if symbol is None: raise inkex.AbortExtension( _("Can't find symbol {}").format(self.options.symbolid) ) bbox = symbol.path.bounding_box() transform = inkex.Transform( scale=( float(self.boxsize) / bbox.width, float(self.boxsize) / bbox.height, ) ) result = Group() for row in range(self.draw.row_count()): for col in range(self.draw.col_count()): if self.draw.isDark(col, row): x, y = self.get_svg_pos(col, row) # Inkscape doesn't support width/height on use tags result.append( Use.new( symbol, x / transform.a, y / transform.d, transform=transform, ) ) return result def render_pathpreset(self): if self.options.pathtype == "simple": return self.render_path("h 1 v 1 h -1") else: s = ( "m 0.5,0.5 " "c 0.2761423745,0 0.5,0.2238576255 0.5,0.5 " "c 0,0.2761423745 -0.2238576255,0.5 -0.5,0.5 " "c -0.2761423745,0 -0.5,-0.2238576255 -0.5,-0.5 " "c 0,-0.2761423745 0.2238576255,-0.5 0.5,-0.5" ) return self.render_path(s) render_smooth = lambda self: self.render_adv(self.options.smoothness[0]) def render_svg(self, grp, drawtype): """Render to svg""" drawer = getattr(self, f"render_{drawtype}", self.render_obsolete) if drawer is None: raise Exception("Unknown draw type: " + drawtype) canvas_width = (self.draw.col_count() + 2 * self.margin) * self.boxsize canvas_height = (self.draw.row_count() + 2 * self.margin) * self.boxsize # white background providing margin: rect = grp.add(Rectangle.new(0, 0, canvas_width, canvas_height)) rect.style["stroke"] = "none" rect.style["fill"] = "black" if self.invert_code else "white" qrg = grp.add(Group()) qrg.style["stroke"] = "none" qrg.style["fill"] = "white" if self.invert_code else "black" qrg.add(drawer()) def get_svg_pos(self, col, row): return (col + self.margin) * self.boxsize, (row + self.margin) * self.boxsize def get_icon_path_str(self, pointStr): result = "" digBuffer = "" for c in pointStr: if c.isdigit() or c == "-" or c == ".": digBuffer += c else: if len(digBuffer) > 0: result += str(float(digBuffer) * self.boxsize) digBuffer = "" result += c if len(digBuffer) > 0: result += str(float(digBuffer) * self.boxsize) return result if __name__ == "__main__": QrCode().run()