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/*
 * Copyright 2008 ZXing authors
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package com.google.zxing.datamatrix.decoder;

import com.google.zxing.FormatException;
import com.google.zxing.common.BitSource;
import com.google.zxing.common.DecoderResult;

import java.io.UnsupportedEncodingException;
import java.util.ArrayList;
import java.util.Collection;
import java.util.List;

/**
 * 

Data Matrix Codes can encode text as bits in one of several modes, and can use multiple modes * in one Data Matrix Code. This class decodes the bits back into text.

* *

See ISO 16022:2006, 5.2.1 - 5.2.9.2

* * @author [email protected] (Brian Brown) * @author Sean Owen */ final class DecodedBitStreamParser { private enum Mode { PAD_ENCODE, // Not really a mode ASCII_ENCODE, C40_ENCODE, TEXT_ENCODE, ANSIX12_ENCODE, EDIFACT_ENCODE, BASE256_ENCODE } /** * See ISO 16022:2006, Annex C Table C.1 * The C40 Basic Character Set (*'s used for placeholders for the shift values) */ private static final char[] C40_BASIC_SET_CHARS = { '*', '*', '*', ' ', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P', 'Q', 'R', 'S', 'T', 'U', 'V', 'W', 'X', 'Y', 'Z' }; private static final char[] C40_SHIFT2_SET_CHARS = { '!', '"', '#', '$', '%', '&', '\'', '(', ')', '*', '+', ',', '-', '.', '/', ':', ';', '<', '=', '>', '?', '@', '[', '\\', ']', '^', '_' }; /** * See ISO 16022:2006, Annex C Table C.2 * The Text Basic Character Set (*'s used for placeholders for the shift values) */ private static final char[] TEXT_BASIC_SET_CHARS = { '*', '*', '*', ' ', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h', 'i', 'j', 'k', 'l', 'm', 'n', 'o', 'p', 'q', 'r', 's', 't', 'u', 'v', 'w', 'x', 'y', 'z' }; // Shift 2 for Text is the same encoding as C40 private static final char[] TEXT_SHIFT2_SET_CHARS = C40_SHIFT2_SET_CHARS; private static final char[] TEXT_SHIFT3_SET_CHARS = { '`', 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P', 'Q', 'R', 'S', 'T', 'U', 'V', 'W', 'X', 'Y', 'Z', '{', '|', '}', '~', (char) 127 }; private DecodedBitStreamParser() { } static DecoderResult decode(byte[] bytes) throws FormatException { BitSource bits = new BitSource(bytes); StringBuilder result = new StringBuilder(100); StringBuilder resultTrailer = new StringBuilder(0); List byteSegments = new ArrayList<>(1); Mode mode = Mode.ASCII_ENCODE; do { if (mode == Mode.ASCII_ENCODE) { mode = decodeAsciiSegment(bits, result, resultTrailer); } else { switch (mode) { case C40_ENCODE: decodeC40Segment(bits, result); break; case TEXT_ENCODE: decodeTextSegment(bits, result); break; case ANSIX12_ENCODE: decodeAnsiX12Segment(bits, result); break; case EDIFACT_ENCODE: decodeEdifactSegment(bits, result); break; case BASE256_ENCODE: decodeBase256Segment(bits, result, byteSegments); break; default: throw FormatException.getFormatInstance(); } mode = Mode.ASCII_ENCODE; } } while (mode != Mode.PAD_ENCODE && bits.available() > 0); if (resultTrailer.length() > 0) { result.append(resultTrailer); } return new DecoderResult(bytes, result.toString(), byteSegments.isEmpty() ? null : byteSegments, null); } /** * See ISO 16022:2006, 5.2.3 and Annex C, Table C.2 */ private static Mode decodeAsciiSegment(BitSource bits, StringBuilder result, StringBuilder resultTrailer) throws FormatException { boolean upperShift = false; do { int oneByte = bits.readBits(8); if (oneByte == 0) { throw FormatException.getFormatInstance(); } else if (oneByte <= 128) { // ASCII data (ASCII value + 1) if (upperShift) { oneByte += 128; //upperShift = false; } result.append((char) (oneByte - 1)); return Mode.ASCII_ENCODE; } else if (oneByte == 129) { // Pad return Mode.PAD_ENCODE; } else if (oneByte <= 229) { // 2-digit data 00-99 (Numeric Value + 130) int value = oneByte - 130; if (value < 10) { // pad with '0' for single digit values result.append('0'); } result.append(value); } else { switch (oneByte) { case 230: // Latch to C40 encodation return Mode.C40_ENCODE; case 231: // Latch to Base 256 encodation return Mode.BASE256_ENCODE; case 232: // FNC1 result.append((char) 29); // translate as ASCII 29 break; case 233: // Structured Append case 234: // Reader Programming // Ignore these symbols for now //throw ReaderException.getInstance(); break; case 235: // Upper Shift (shift to Extended ASCII) upperShift = true; break; case 236: // 05 Macro result.append("[)>\u001E05\u001D"); resultTrailer.insert(0, "\u001E\u0004"); break; case 237: // 06 Macro result.append("[)>\u001E06\u001D"); resultTrailer.insert(0, "\u001E\u0004"); break; case 238: // Latch to ANSI X12 encodation return Mode.ANSIX12_ENCODE; case 239: // Latch to Text encodation return Mode.TEXT_ENCODE; case 240: // Latch to EDIFACT encodation return Mode.EDIFACT_ENCODE; case 241: // ECI Character // TODO(bbrown): I think we need to support ECI //throw ReaderException.getInstance(); // Ignore this symbol for now break; default: // Not to be used in ASCII encodation // but work around encoders that end with 254, latch back to ASCII if (oneByte != 254 || bits.available() != 0) { throw FormatException.getFormatInstance(); } break; } } } while (bits.available() > 0); return Mode.ASCII_ENCODE; } /** * See ISO 16022:2006, 5.2.5 and Annex C, Table C.1 */ private static void decodeC40Segment(BitSource bits, StringBuilder result) throws FormatException { // Three C40 values are encoded in a 16-bit value as // (1600 * C1) + (40 * C2) + C3 + 1 // TODO(bbrown): The Upper Shift with C40 doesn't work in the 4 value scenario all the time boolean upperShift = false; int[] cValues = new int[3]; int shift = 0; do { // If there is only one byte left then it will be encoded as ASCII if (bits.available() == 8) { return; } int firstByte = bits.readBits(8); if (firstByte == 254) { // Unlatch codeword return; } parseTwoBytes(firstByte, bits.readBits(8), cValues); for (int i = 0; i < 3; i++) { int cValue = cValues[i]; switch (shift) { case 0: if (cValue < 3) { shift = cValue + 1; } else if (cValue < C40_BASIC_SET_CHARS.length) { char c40char = C40_BASIC_SET_CHARS[cValue]; if (upperShift) { result.append((char) (c40char + 128)); upperShift = false; } else { result.append(c40char); } } else { throw FormatException.getFormatInstance(); } break; case 1: if (upperShift) { result.append((char) (cValue + 128)); upperShift = false; } else { result.append((char) cValue); } shift = 0; break; case 2: if (cValue < C40_SHIFT2_SET_CHARS.length) { char c40char = C40_SHIFT2_SET_CHARS[cValue]; if (upperShift) { result.append((char) (c40char + 128)); upperShift = false; } else { result.append(c40char); } } else { switch (cValue) { case 27: // FNC1 result.append((char) 29); // translate as ASCII 29 break; case 30: // Upper Shift upperShift = true; break; default: throw FormatException.getFormatInstance(); } } shift = 0; break; case 3: if (upperShift) { result.append((char) (cValue + 224)); upperShift = false; } else { result.append((char) (cValue + 96)); } shift = 0; break; default: throw FormatException.getFormatInstance(); } } } while (bits.available() > 0); } /** * See ISO 16022:2006, 5.2.6 and Annex C, Table C.2 */ private static void decodeTextSegment(BitSource bits, StringBuilder result) throws FormatException { // Three Text values are encoded in a 16-bit value as // (1600 * C1) + (40 * C2) + C3 + 1 // TODO(bbrown): The Upper Shift with Text doesn't work in the 4 value scenario all the time boolean upperShift = false; int[] cValues = new int[3]; int shift = 0; do { // If there is only one byte left then it will be encoded as ASCII if (bits.available() == 8) { return; } int firstByte = bits.readBits(8); if (firstByte == 254) { // Unlatch codeword return; } parseTwoBytes(firstByte, bits.readBits(8), cValues); for (int i = 0; i < 3; i++) { int cValue = cValues[i]; switch (shift) { case 0: if (cValue < 3) { shift = cValue + 1; } else if (cValue < TEXT_BASIC_SET_CHARS.length) { char textChar = TEXT_BASIC_SET_CHARS[cValue]; if (upperShift) { result.append((char) (textChar + 128)); upperShift = false; } else { result.append(textChar); } } else { throw FormatException.getFormatInstance(); } break; case 1: if (upperShift) { result.append((char) (cValue + 128)); upperShift = false; } else { result.append((char) cValue); } shift = 0; break; case 2: // Shift 2 for Text is the same encoding as C40 if (cValue < TEXT_SHIFT2_SET_CHARS.length) { char textChar = TEXT_SHIFT2_SET_CHARS[cValue]; if (upperShift) { result.append((char) (textChar + 128)); upperShift = false; } else { result.append(textChar); } } else { switch (cValue) { case 27: // FNC1 result.append((char) 29); // translate as ASCII 29 break; case 30: // Upper Shift upperShift = true; break; default: throw FormatException.getFormatInstance(); } } shift = 0; break; case 3: if (cValue < TEXT_SHIFT3_SET_CHARS.length) { char textChar = TEXT_SHIFT3_SET_CHARS[cValue]; if (upperShift) { result.append((char) (textChar + 128)); upperShift = false; } else { result.append(textChar); } shift = 0; } else { throw FormatException.getFormatInstance(); } break; default: throw FormatException.getFormatInstance(); } } } while (bits.available() > 0); } /** * See ISO 16022:2006, 5.2.7 */ private static void decodeAnsiX12Segment(BitSource bits, StringBuilder result) throws FormatException { // Three ANSI X12 values are encoded in a 16-bit value as // (1600 * C1) + (40 * C2) + C3 + 1 int[] cValues = new int[3]; do { // If there is only one byte left then it will be encoded as ASCII if (bits.available() == 8) { return; } int firstByte = bits.readBits(8); if (firstByte == 254) { // Unlatch codeword return; } parseTwoBytes(firstByte, bits.readBits(8), cValues); for (int i = 0; i < 3; i++) { int cValue = cValues[i]; switch (cValue) { case 0: // X12 segment terminator result.append('\r'); break; case 1: // X12 segment separator * result.append('*'); break; case 2: // X12 sub-element separator > result.append('>'); break; case 3: // space result.append(' '); break; default: if (cValue < 14) { // 0 - 9 result.append((char) (cValue + 44)); } else if (cValue < 40) { // A - Z result.append((char) (cValue + 51)); } else { throw FormatException.getFormatInstance(); } break; } } } while (bits.available() > 0); } private static void parseTwoBytes(int firstByte, int secondByte, int[] result) { int fullBitValue = (firstByte << 8) + secondByte - 1; int temp = fullBitValue / 1600; result[0] = temp; fullBitValue -= temp * 1600; temp = fullBitValue / 40; result[1] = temp; result[2] = fullBitValue - temp * 40; } /** * See ISO 16022:2006, 5.2.8 and Annex C Table C.3 */ private static void decodeEdifactSegment(BitSource bits, StringBuilder result) { do { // If there is only two or less bytes left then it will be encoded as ASCII if (bits.available() <= 16) { return; } for (int i = 0; i < 4; i++) { int edifactValue = bits.readBits(6); // Check for the unlatch character if (edifactValue == 0x1F) { // 011111 // Read rest of byte, which should be 0, and stop int bitsLeft = 8 - bits.getBitOffset(); if (bitsLeft != 8) { bits.readBits(bitsLeft); } return; } if ((edifactValue & 0x20) == 0) { // no 1 in the leading (6th) bit edifactValue |= 0x40; // Add a leading 01 to the 6 bit binary value } result.append((char) edifactValue); } } while (bits.available() > 0); } /** * See ISO 16022:2006, 5.2.9 and Annex B, B.2 */ private static void decodeBase256Segment(BitSource bits, StringBuilder result, Collection byteSegments) throws FormatException { // Figure out how long the Base 256 Segment is. int codewordPosition = 1 + bits.getByteOffset(); // position is 1-indexed int d1 = unrandomize255State(bits.readBits(8), codewordPosition++); int count; if (d1 == 0) { // Read the remainder of the symbol count = bits.available() / 8; } else if (d1 < 250) { count = d1; } else { count = 250 * (d1 - 249) + unrandomize255State(bits.readBits(8), codewordPosition++); } // We're seeing NegativeArraySizeException errors from users. if (count < 0) { throw FormatException.getFormatInstance(); } byte[] bytes = new byte[count]; for (int i = 0; i < count; i++) { // Have seen this particular error in the wild, such as at // http://www.bcgen.com/demo/IDAutomationStreamingDataMatrix.aspx?MODE=3&D=Fred&PFMT=3&PT=F&X=0.3&O=0&LM=0.2 if (bits.available() < 8) { throw FormatException.getFormatInstance(); } bytes[i] = (byte) unrandomize255State(bits.readBits(8), codewordPosition++); } byteSegments.add(bytes); try { result.append(new String(bytes, "ISO8859_1")); } catch (UnsupportedEncodingException uee) { throw new IllegalStateException("Platform does not support required encoding: " + uee); } } /** * See ISO 16022:2006, Annex B, B.2 */ private static int unrandomize255State(int randomizedBase256Codeword, int base256CodewordPosition) { int pseudoRandomNumber = ((149 * base256CodewordPosition) % 255) + 1; int tempVariable = randomizedBase256Codeword - pseudoRandomNumber; return tempVariable >= 0 ? tempVariable : tempVariable + 256; } }




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