想起前段时间的物联网的外包开发,经常遇到通过wifi接受的数据,要通过转换成十六进制字符串,或者最后又是十进制数据。都是根据双方的协议来开发的。那么我发送过去的数据也需要,经过特殊转换成byte字节发过去,硬件那边收到不至于乱码的数据。
DataInputStream dis = new DataInputStream(new BufferedInputStream(socket.getInputStream())); byte readBuffer[] = new byte[64]; int count = 0; try { count = dis.read(readBuffer); } catch (IOException e) { continue; }readBuffer收到数据是这样的:104, 56, 56, 104, 0, 114, 120, 85, 52, 18, 67, 35, 1, 7, 0, 0, 0, 0, 12, 19, 120, 86, 52, 18, 12, 59, 120, 52, 18, 12, 38, 120, 86, 52, 18, 11, 89, 69, 35, 0, 2, -3, 23, 0, 0, 22
那么要根据这些数据转换成十六进制的字符串,如果你直接转换成String字符串那肯定乱码了。因为硬件调试发给android这边是十六进制数据。
readBuffer字节数组转后数据十六进制是这样的:68 , 38 , 38 , 68 , 00 , 72 , 78 , 55 , 34 , 12 , 43 , 23 , 01 , 07 , 00 , 00 , 00 , 00 , 0C , 13 , 78 , 56 , 34 , 12 , 0C , 3B , 78 , 34 , 12 , 0C , 26 , 78 , 56 , 34 , 12 , 0B , 59 , 45 , 23 , 00 , 02 , FD , 17 , 00 , 00 , 16
可以看出跟硬件发的是不是一样了。这里面不是十六进制Y,CS就用00填充了。
当然这些都是根据双方收发数据来解析,处理的。
private String mstrRestartSend = "FE FE 68 04 04 68 53 FD 50 00 A0 16"; private byte[] mRestart = null; mRestart = StringUtil.HexCommandtoByte(mstrRestartSend.getBytes()); public class StringUtil { // 十六进制的字符串转换成byte数组 public static byte[] HexCommandtoByte(byte[] data) { if (data == null) { return null; } int nLength = data.length; String strTemString = new String(data, 0, nLength); String[] strings = strTemString.split(" "); nLength = strings.length; data = new byte[nLength]; for (int i = 0; i < nLength; i++) { if (strings[i].length() != 2) { data[i] = 00; continue; } try { data[i] = (byte)Integer.parseInt(strings[i], 16); } catch (Exception e) { data[i] = 00; continue; } } return data; } }那么这样发过去就不会错误或者乱码。
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示例图:
public class DigitalTrans { /** * 数字字符串转ASCII码字符串 * * @param String * 字符串 * @return ASCII字符串 */ public static String StringToAsciiString(String content) { String result = ""; int max = content.length(); for (int i = 0; i < max; i++) { char c = content.charAt(i); String b = Integer.toHexString(c); result = result + b; } return result; } /** * 十六进制转字符串 * * @param hexString * 十六进制字符串 * @param encodeType * 编码类型4:Unicode,2:普通编码 * @return 字符串 */ public static String hexStringToString(String hexString, int encodeType) { String result = ""; int max = hexString.length() / encodeType; for (int i = 0; i < max; i++) { char c = (char) DigitalTrans.hexStringToAlgorism(hexString .substring(i * encodeType, (i + 1) * encodeType)); result += c; } return result; } /** * 十六进制字符串装十进制 * * @param hex * 十六进制字符串 * @return 十进制数值 */ public static int hexStringToAlgorism(String hex) { hex = hex.toUpperCase(); int max = hex.length(); int result = 0; for (int i = max; i > 0; i--) { char c = hex.charAt(i - 1); int algorism = 0; if (c >= '0' && c <= '9') { algorism = c - '0'; } else { algorism = c - 55; } result += Math.pow(16, max - i) * algorism; } return result; } /** * 十六转二进制 * * @param hex * 十六进制字符串 * @return 二进制字符串 */ public static String hexStringToBinary(String hex) { hex = hex.toUpperCase(); String result = ""; int max = hex.length(); for (int i = 0; i < max; i++) { char c = hex.charAt(i); switch (c) { case '0': result += "0000"; break; case '1': result += "0001"; break; case '2': result += "0010"; break; case '3': result += "0011"; break; case '4': result += "0100"; break; case '5': result += "0101"; break; case '6': result += "0110"; break; case '7': result += "0111"; break; case '8': result += "1000"; break; case '9': result += "1001"; break; case 'A': result += "1010"; break; case 'B': result += "1011"; break; case 'C': result += "1100"; break; case 'D': result += "1101"; break; case 'E': result += "1110"; break; case 'F': result += "1111"; break; } } return result; } /** * ASCII码字符串转数字字符串 * * @param String * ASCII字符串 * @return 字符串 */ public static String AsciiStringToString(String content) { String result = ""; int length = content.length() / 2; for (int i = 0; i < length; i++) { String c = content.substring(i * 2, i * 2 + 2); int a = hexStringToAlgorism(c); char b = (char) a; String d = String.valueOf(b); result += d; } return result; } /** * 将十进制转换为指定长度的十六进制字符串 * * @param algorism * int 十进制数字 * @param maxLength * int 转换后的十六进制字符串长度 * @return String 转换后的十六进制字符串 */ public static String algorismToHEXString(int algorism, int maxLength) { String result = ""; result = Integer.toHexString(algorism); if (result.length() % 2 == 1) { result = "0" + result; } return patchHexString(result.toUpperCase(), maxLength); } /** * 字节数组转为普通字符串(ASCII对应的字符) * * @param bytearray * byte[] * @return String */ public static String bytetoString(byte[] bytearray) { String result = ""; char temp; int length = bytearray.length; for (int i = 0; i < length; i++) { temp = (char) bytearray[i]; result += temp; } return result; } /** * 二进制字符串转十进制 * * @param binary * 二进制字符串 * @return 十进制数值 */ public static int binaryToAlgorism(String binary) { int max = binary.length(); int result = 0; for (int i = max; i > 0; i--) { char c = binary.charAt(i - 1); int algorism = c - '0'; result += Math.pow(2, max - i) * algorism; } return result; } /** * 十进制转换为十六进制字符串 * * @param algorism * int 十进制的数字 * @return String 对应的十六进制字符串 */ public static String algorismToHEXString(int algorism) { String result = ""; result = Integer.toHexString(algorism); if (result.length() % 2 == 1) { result = "0" + result; } result = result.toUpperCase(); return result; } /** * HEX字符串前补0,主要用于长度位数不足。 * * @param str * String 需要补充长度的十六进制字符串 * @param maxLength * int 补充后十六进制字符串的长度 * @return 补充结果 */ static public String patchHexString(String str, int maxLength) { String temp = ""; for (int i = 0; i < maxLength - str.length(); i++) { temp = "0" + temp; } str = (temp + str).substring(0, maxLength); return str; } /** * 将一个字符串转换为int * * @param s * String 要转换的字符串 * @param defaultInt * int 如果出现异常,默认返回的数字 * @param radix * int 要转换的字符串是什么进制的,如16 8 10. * @return int 转换后的数字 */ public static int parseToInt(String s, int defaultInt, int radix) { int i = 0; try { i = Integer.parseInt(s, radix); } catch (NumberFormatException ex) { i = defaultInt; } return i; } /** * 将一个十进制形式的数字字符串转换为int * * @param s * String 要转换的字符串 * @param defaultInt * int 如果出现异常,默认返回的数字 * @return int 转换后的数字 */ public static int parseToInt(String s, int defaultInt) { int i = 0; try { i = Integer.parseInt(s); } catch (NumberFormatException ex) { i = defaultInt; } return i; } /** * 十六进制字符串转为Byte数组,每两个十六进制字符转为一个Byte * * @param hex * 十六进制字符串 * @return byte 转换结果 */ public static byte[] hexStringToByte(String hex) { int max = hex.length() / 2; byte[] bytes = new byte[max]; String binarys = DigitalTrans.hexStringToBinary(hex); for (int i = 0; i < max; i++) { bytes[i] = (byte) DigitalTrans.binaryToAlgorism(binarys.substring( i * 8 + 1, (i + 1) * 8)); if (binarys.charAt(8 * i) == '1') { bytes[i] = (byte) (0 - bytes[i]); } } return bytes; } /** * 十六进制串转化为byte数组 * * @return the array of byte */ public static final byte[] hex2byte(String hex) throws IllegalArgumentException { if (hex.length() % 2 != 0) { throw new IllegalArgumentException(); } char[] arr = hex.toCharArray(); byte[] b = new byte[hex.length() / 2]; for (int i = 0, j = 0, l = hex.length(); i < l; i++, j++) { String swap = "" + arr[i++] + arr[i]; int byteint = Integer.parseInt(swap, 16) & 0xFF; b[j] = new Integer(byteint).byteValue(); } return b; } /** * 字节数组转换为十六进制字符串 * * @param b * byte[] 需要转换的字节数组 * @return String 十六进制字符串 */ public static final String byte2hex(byte b[]) { if (b == null) { throw new IllegalArgumentException( "Argument b ( byte array ) is null! "); } String hs = ""; String stmp = ""; for (int n = 0; n < b.length; n++) { stmp = Integer.toHexString(b[n] & 0xff); if (stmp.length() == 1) { hs = hs + "0" + stmp; } else { hs = hs + stmp; } } return hs.toUpperCase(); } }