• 常用工具类一


    一 .  Base64Util

    package com.jarvis.base.util;
    
    import java.io.*;
    
    /**   
    * @Title: Base64Util.java 
    * @Package com.jarvis.base.util 
    * @Description:Base64工具类
    * @author Jack  
    * @date 2017年9月2日 下午5:10:32 
    * @version V1.0   
    */ 
    public final class Base64Util
    {
        private static final int BASELENGTH = 255;
    
        private static final int LOOKUPLENGTH = 64;
    
        private static final int TWENTYFOURBITGROUP = 24;
    
        private static final int EIGHTBIT = 8;
    
        private static final int SIXTEENBIT = 16;
    
        // private static final int SIXBIT = 6;
        private static final int FOURBYTE = 4;
    
        // private static final int TWOBYTE = 2;
        private static final int SIGN = -128;
    
        private static final byte PAD = (byte) '=';
    
        private static byte[] base64Alphabet = new byte[BASELENGTH];
    
        private static byte[] lookUpBase64Alphabet = new byte[LOOKUPLENGTH];
    
        static
        {
            for (int i = 0; i < BASELENGTH; i++)
            {
                base64Alphabet[i] = -1;
            }
            for (int i = 'Z'; i >= 'A'; i--)
            {
                base64Alphabet[i] = (byte) (i - 'A');
            }
            for (int i = 'z'; i >= 'a'; i--)
            {
                base64Alphabet[i] = (byte) (i - 'a' + 26);
            }
            for (int i = '9'; i >= '0'; i--)
            {
                base64Alphabet[i] = (byte) (i - '0' + 52);
            }
    
            base64Alphabet['+'] = 62;
            base64Alphabet['/'] = 63;
    
            for (int i = 0; i <= 25; i++)
            {
                lookUpBase64Alphabet[i] = (byte) ('A' + i);
            }
    
            for (int i = 26, j = 0; i <= 51; i++, j++)
            {
                lookUpBase64Alphabet[i] = (byte) ('a' + j);
            }
    
            for (int i = 52, j = 0; i <= 61; i++, j++)
            {
                lookUpBase64Alphabet[i] = (byte) ('0' + j);
            }
    
            lookUpBase64Alphabet[62] = (byte) '+';
            lookUpBase64Alphabet[63] = (byte) '/';
        }
    
        public static boolean isBase64(String isValidString)
        {
            return isArrayByteBase64(isValidString.getBytes());
        }
    
        public static boolean isBase64(byte octect)
        {
            // shall we ignore white space? JEFF??
            return (octect == PAD || base64Alphabet[octect] != -1);
        }
    
        public static boolean isArrayByteBase64(byte[] arrayOctect)
        {
            int length = arrayOctect.length;
            if (length == 0)
            {
                // shouldn't a 0 length array be valid base64 data?
                // return false;
                return true;
            }
            for (int i = 0; i < length; i++)
            {
                if (!isBase64(arrayOctect[i]))
                {
                    return false;
                }
            }
            return true;
        }
    
        /**
         * Encode String object;
         *
         * @param src String object to be encoded.
         * @return encoded String;
         */
        public static String encodeString(String src)
        {
            return encode(src);
        }
    
        public static String encodeBytes(byte[] src)
        {
            if (src == null || src.length == 0) {
                return null;
            }
            byte[] bytes = encode(src);
            return new String(bytes);
        }
    
        /**
         * Encode String object;
         *
         * @param src String object to be encoded.
         * @return encoded String;
         */
        public static String encode(String src)
        {
            String target = null;
            if (src != null)
            {
                byte[] bts1 = src.getBytes();
                byte[] bts2 = encode(bts1);
                if (bts2 != null)
                {
                    target = new String(bts2);
                }
            }
            return target;
        }
    
        /**
         * Encodes hex octects into Base64.
         *
         * @param binaryData Array containing binary data to encode.
         * @return Base64-encoded data.
         */
        public static byte[] encode(byte[] binaryData)
        {
            int lengthDataBits = binaryData.length * EIGHTBIT;
            int fewerThan24bits = lengthDataBits % TWENTYFOURBITGROUP;
            int numberTriplets = lengthDataBits / TWENTYFOURBITGROUP;
            byte encodedData[] = null;
    
            if (fewerThan24bits != 0)
            {
                // data not divisible by 24 bit
                encodedData = new byte[(numberTriplets + 1) * 4];
            }
            else
            {
                // 16 or 8 bit
                encodedData = new byte[numberTriplets * 4];
            }
    
            byte k = 0, l = 0, b1 = 0, b2 = 0, b3 = 0;
    
            int encodedIndex = 0;
            int dataIndex = 0;
            int i = 0;
            for (i = 0; i < numberTriplets; i++)
            {
                dataIndex = i * 3;
                b1 = binaryData[dataIndex];
                b2 = binaryData[dataIndex + 1];
                b3 = binaryData[dataIndex + 2];
    
                l = (byte) (b2 & 0x0f);
                k = (byte) (b1 & 0x03);
    
                encodedIndex = i * 4;
                byte val1 = ((b1 & SIGN) == 0) ? (byte) (b1 >> 2) : (byte) ((b1) >> 2 ^ 0xc0);
                byte val2 = ((b2 & SIGN) == 0) ? (byte) (b2 >> 4) : (byte) ((b2) >> 4 ^ 0xf0);
                byte val3 = ((b3 & SIGN) == 0) ? (byte) (b3 >> 6) : (byte) ((b3) >> 6 ^ 0xfc);
    
                encodedData[encodedIndex] = lookUpBase64Alphabet[val1];
                encodedData[encodedIndex + 1] = lookUpBase64Alphabet[val2 | (k << 4)];
                encodedData[encodedIndex + 2] = lookUpBase64Alphabet[(l << 2) | val3];
                encodedData[encodedIndex + 3] = lookUpBase64Alphabet[b3 & 0x3f];
            }
    
            // form integral number of 6-bit groups
            dataIndex = i * 3;
            encodedIndex = i * 4;
            if (fewerThan24bits == EIGHTBIT)
            {
                b1 = binaryData[dataIndex];
                k = (byte) (b1 & 0x03);
                byte val1 = ((b1 & SIGN) == 0) ? (byte) (b1 >> 2) : (byte) ((b1) >> 2 ^ 0xc0);
                encodedData[encodedIndex] = lookUpBase64Alphabet[val1];
                encodedData[encodedIndex + 1] = lookUpBase64Alphabet[k << 4];
                encodedData[encodedIndex + 2] = PAD;
                encodedData[encodedIndex + 3] = PAD;
            }
            else if (fewerThan24bits == SIXTEENBIT)
            {
    
                b1 = binaryData[dataIndex];
                b2 = binaryData[dataIndex + 1];
                l = (byte) (b2 & 0x0f);
                k = (byte) (b1 & 0x03);
    
                byte val1 = ((b1 & SIGN) == 0) ? (byte) (b1 >> 2) : (byte) ((b1) >> 2 ^ 0xc0);
                byte val2 = ((b2 & SIGN) == 0) ? (byte) (b2 >> 4) : (byte) ((b2) >> 4 ^ 0xf0);
    
                encodedData[encodedIndex] = lookUpBase64Alphabet[val1];
                encodedData[encodedIndex + 1] = lookUpBase64Alphabet[val2 | (k << 4)];
                encodedData[encodedIndex + 2] = lookUpBase64Alphabet[l << 2];
                encodedData[encodedIndex + 3] = PAD;
            }
    
            return encodedData;
        }
    
        public static String decode(String src)
        {
            String target = null;
            if (src != null)
            {
                byte[] bts1 = src.getBytes();
                byte[] bts2 = decode(bts1);
                if (bts2 != null)
                {
                    target = new String(bts2);
                }
            }
            return target;
        }
    
        public static String decode(String src, String charSet) throws UnsupportedEncodingException
        {
            String target = null;
            if (src != null)
            {
                byte[] bts1 = src.getBytes();
                byte[] bts2 = decode(bts1);
                if (bts2 != null)
                {
                    target = new String(bts2, charSet);
                }
            }
            return target;
        }
    
        /**
         * Decodes Base64 data into octects
         *
         * @param base64Data Byte array containing Base64 data
         * @return Array containing decoded data.
         */
        public static byte[] decode(byte[] base64Data)
        {
            // handle the edge case, so we don't have to worry about it later
            if (base64Data.length == 0)
            {
                return null;
            }
    
            int numberQuadruple = base64Data.length / FOURBYTE;
            byte decodedData[] = null;
            byte b1 = 0, b2 = 0, b3 = 0, b4 = 0, marker0 = 0, marker1 = 0;
    
            // Throw away anything not in base64Data
    
            int encodedIndex = 0;
            int dataIndex = 0;
            {
                // this sizes the output array properly - rlw
                int lastData = base64Data.length;
                // ignore the '=' padding
                while (base64Data[lastData - 1] == PAD)
                {
                    if (--lastData == 0)
                    {
                        return new byte[0];
                    }
                }
                decodedData = new byte[lastData - numberQuadruple];
            }
    
            for (int i = 0; i < numberQuadruple; i++)
            {
                dataIndex = i * 4;
                marker0 = base64Data[dataIndex + 2];
                marker1 = base64Data[dataIndex + 3];
    
                b1 = base64Alphabet[base64Data[dataIndex]];
                b2 = base64Alphabet[base64Data[dataIndex + 1]];
    
                if (marker0 != PAD && marker1 != PAD)
                {
                    // No PAD e.g 3cQl
                    b3 = base64Alphabet[marker0];
                    b4 = base64Alphabet[marker1];
    
                    decodedData[encodedIndex] = (byte) (b1 << 2 | b2 >> 4);
                    decodedData[encodedIndex + 1] = (byte) (((b2 & 0xf) << 4) | ((b3 >> 2) & 0xf));
                    decodedData[encodedIndex + 2] = (byte) (b3 << 6 | b4);
                }
                else if (marker0 == PAD)
                {
                    // Two PAD e.g. 3c[Pad][Pad]
                    decodedData[encodedIndex] = (byte) (b1 << 2 | b2 >> 4);
                }
                else if (marker1 == PAD)
                {
                    // One PAD e.g. 3cQ[Pad]
                    b3 = base64Alphabet[marker0];
    
                    decodedData[encodedIndex] = (byte) (b1 << 2 | b2 >> 4);
                    decodedData[encodedIndex + 1] = (byte) (((b2 & 0xf) << 4) | ((b3 >> 2) & 0xf));
                }
                encodedIndex += 3;
            }
            return decodedData;
        }
    
        /**
         * 隐藏工具类的构造方法
         */
        protected Base64Util()
        {
            throw new UnsupportedOperationException();
        }
    
        /**
         * 文件读取缓冲区大小
         */
        private static final int CACHE_SIZE = 1024;
    
            /** *//**
         * <p>
         * BASE64字符串解码为二进制数据
         * </p>
         *
         * @param base64
         * @return
         * @throws Exception
         */
        public static byte[] decodeString(String base64) throws Exception {
            return Base64Util.decode(base64.getBytes());
        }
    
            /** *//**
         * <p>
         * 二进制数据编码为BASE64字符串
         * </p>
         *
         * @param bytes
         * @return
         * @throws Exception
         */
        public static String encodeByte(byte[] bytes) throws Exception {
            return new String(Base64Util.encode(bytes));
        }
    
            /** *//**
         * <p>
         * 将文件编码为BASE64字符串
         * </p>
         * <p>
         * 大文件慎用,可能会导致内存溢出
         * </p>
         *
         * @param filePath 文件绝对路径
         * @return
         * @throws Exception
         */
        public static String encodeFile(String filePath) throws Exception {
            byte[] bytes = fileToByte(filePath);
            return encodeByte(bytes);
        }
    
            /** *//**
         * <p>
         * BASE64字符串转回文件
         * </p>
         *
         * @param filePath 文件绝对路径
         * @param base64 编码字符串
         * @throws Exception
         */
        public static void decodeToFile(String filePath, String base64) throws Exception {
            byte[] bytes = decodeString(base64);
            byteArrayToFile(bytes, filePath);
        }
    
            /** *//**
         * <p>
         * 文件转换为二进制数组
         * </p>
         *
         * @param filePath 文件路径
         * @return
         * @throws Exception
         */
        public static byte[] fileToByte(String filePath) throws Exception {
            byte[] data = new byte[0];
            File file = new File(filePath);
            if (file.exists()) {
                FileInputStream in = new FileInputStream(file);
                ByteArrayOutputStream out = new ByteArrayOutputStream(2048);
                byte[] cache = new byte[CACHE_SIZE];
                int nRead = 0;
                while ((nRead = in.read(cache)) != -1) {
                    out.write(cache, 0, nRead);
                    out.flush();
                }
                out.close();
                in.close();
                data = out.toByteArray();
            }
            return data;
        }
    
            /** *//**
         * <p>
         * 二进制数据写文件
         * </p>
         *
         * @param bytes 二进制数据
         * @param filePath 文件生成目录
         */
        public static void byteArrayToFile(byte[] bytes, String filePath) throws Exception {
            InputStream in = new ByteArrayInputStream(bytes);
            File destFile = new File(filePath);
            if (!destFile.getParentFile().exists()) {
                destFile.getParentFile().mkdirs();
            }
            destFile.createNewFile();
            OutputStream out = new FileOutputStream(destFile);
            byte[] cache = new byte[CACHE_SIZE];
            int nRead = 0;
            while ((nRead = in.read(cache)) != -1) {
                out.write(cache, 0, nRead);
                out.flush();
            }
            out.close();
            in.close();
        }
    
    }

    二.  FastJsonUtil

    package com.jarvis.base.util;
    
    import java.io.BufferedReader;
    import java.io.BufferedWriter;
    import java.io.File;
    import java.io.FileInputStream;
    import java.io.FileOutputStream;
    import java.io.IOException;
    import java.io.InputStreamReader;
    import java.io.OutputStreamWriter;
    import java.util.List;
    import java.util.Map;
    
    import com.alibaba.fastjson.JSON;
    import com.alibaba.fastjson.JSONObject;
    import com.alibaba.fastjson.TypeReference;
    import com.alibaba.fastjson.serializer.JSONLibDataFormatSerializer;
    import com.alibaba.fastjson.serializer.SerializeConfig;
    import com.alibaba.fastjson.serializer.SerializerFeature;
    
    /**
     *   
     * 
     * @Title: FastJsonUtil.java
     * @Package com.jarvis.base.util
     * @Description:fastjson工具类
     * @author Jack 
     * @date 2017年9月2日 下午4:16:27
     * @version V1.0  
     */
    public class FastJsonUtil {
    
        private static final SerializeConfig config;
    
        static {
            config = new SerializeConfig();
            config.put(java.util.Date.class, new JSONLibDataFormatSerializer()); // 使用和json-lib兼容的日期输出格式
            config.put(java.sql.Date.class, new JSONLibDataFormatSerializer()); // 使用和json-lib兼容的日期输出格式
        }
    
        private static final SerializerFeature[] features = { SerializerFeature.WriteMapNullValue, // 输出空置字段
                SerializerFeature.WriteNullListAsEmpty, // list字段如果为null,输出为[],而不是null
                SerializerFeature.WriteNullNumberAsZero, // 数值字段如果为null,输出为0,而不是null
                SerializerFeature.WriteNullBooleanAsFalse, // Boolean字段如果为null,输出为false,而不是null
                SerializerFeature.WriteNullStringAsEmpty, // 字符类型字段如果为null,输出为"",而不是null
                SerializerFeature.PrettyFormat  //是否需要格式化输出Json数据
        };
    
        /**
         * Author:Jack Time:2017年9月2日下午4:24:14
         * 
         * @param object
         * @return Return:String Description:将对象转成成Json对象
         */
        public static String toJSONString(Object object) {
            return JSON.toJSONString(object, config, features);
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:27:25
         * 
         * @param object
         * @return Return:String Description:使用和json-lib兼容的日期输出格式
         */
        public static String toJSONNoFeatures(Object object) {
            return JSON.toJSONString(object, config);
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:24:54
         * 
         * @param jsonStr
         * @return Return:Object Description:将Json数据转换成JSONObject
         */
        public static JSONObject toJsonObj(String jsonStr) {
            return (JSONObject) JSON.parse(jsonStr);
        }
        
        /**
         * Author:Jack Time:2017年9月2日下午4:25:20
         * 
         * @param jsonStr
         * @param clazz
         * @return Return:T Description:将Json数据转换成Object
         */
        public static <T> T toBean(String jsonStr, Class<T> clazz) {
            return JSON.parseObject(jsonStr, clazz);
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:25:34
         * 
         * @param jsonStr
         * @return Return:Object[] Description:将Json数据转换为数组
         */
        public static <T> Object[] toArray(String jsonStr) {
            return toArray(jsonStr, null);
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:25:57
         * 
         * @param jsonStr
         * @param clazz
         * @return Return:Object[] Description:将Json数据转换为数组
         */
        public static <T> Object[] toArray(String jsonStr, Class<T> clazz) {
            return JSON.parseArray(jsonStr, clazz).toArray();
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:26:08
         * 
         * @param jsonStr
         * @param clazz
         * @return Return:List<T> Description:将Json数据转换为List
         */
        public static <T> List<T> toList(String jsonStr, Class<T> clazz) {
            return JSON.parseArray(jsonStr, clazz);
        }
    
        /**
         * 将javabean转化为序列化的JSONObject对象
         * 
         * @param keyvalue
         * @return
         */
        public static JSONObject beanToJsonObj(Object bean) {
            String jsonStr = JSON.toJSONString(bean);
            JSONObject objectJson = (JSONObject) JSON.parse(jsonStr);
            return objectJson;
        }
        /**
         * json字符串转化为map
         * 
         * @param s
         * @return
         */
        public static Map<?, ?> stringToCollect(String jsonStr) {
            Map<?, ?> map = JSONObject.parseObject(jsonStr);
            return map;
        }
    
        /**
         * 将map转化为string
         * 
         * @param m
         * @return
         */
        public static String collectToString(Map<?, ?> map) {
            String jsonStr = JSONObject.toJSONString(map);
            return jsonStr;
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:19:00
         * 
         * @param t
         * @param file
         * @throws IOException
         *             Return:void Description:将对象的Json数据写入文件。
         */
        public static <T> void writeJsonToFile(T t, File file) throws IOException {
            String jsonStr = JSONObject.toJSONString(t, SerializerFeature.PrettyFormat);
            BufferedWriter bw = new BufferedWriter(new OutputStreamWriter(new FileOutputStream(file)));
            bw.write(jsonStr);
            bw.close();
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:19:12
         * 
         * @param t
         * @param filename
         * @throws IOException
         *             Return:void Description:将对象的Json数据写入文件。
         */
        public static <T> void writeJsonToFile(T t, String filename) throws IOException {
            writeJsonToFile(t, new File(filename));
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:22:07
         * 
         * @param cls
         * @param file
         * @return
         * @throws IOException
         *             Return:T Description:将文件中的Json数据转换成Object对象
         */
        public static <T> T readJsonFromFile(Class<T> cls, File file) throws IOException {
            StringBuilder strBuilder = new StringBuilder();
            BufferedReader br = new BufferedReader(new InputStreamReader(new FileInputStream(file)));
            String line = null;
            while ((line = br.readLine()) != null) {
                strBuilder.append(line);
            }
            br.close();
            return JSONObject.parseObject(strBuilder.toString(), cls);
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:22:30
         * 
         * @param cls
         * @param filename
         * @return
         * @throws IOException
         *             Return:T Description:将文件中的Json数据转换成Object对象
         */
        public static <T> T readJsonFromFile(Class<T> cls, String filename) throws IOException {
            return readJsonFromFile(cls, new File(filename));
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:23:06
         * 
         * @param typeReference
         * @param file
         * @return
         * @throws IOException
         *             Return:T Description:从文件中读取出Json对象
         */
        public static <T> T readJsonFromFile(TypeReference<T> typeReference, File file) throws IOException {
            StringBuilder strBuilder = new StringBuilder();
            BufferedReader br = new BufferedReader(new InputStreamReader(new FileInputStream(file)));
            String line = null;
            while ((line = br.readLine()) != null) {
                strBuilder.append(line);
            }
            br.close();
            return JSONObject.parseObject(strBuilder.toString(), typeReference);
        }
    
        /**
         * Author:Jack Time:2017年9月2日下午4:23:11
         * 
         * @param typeReference
         * @param filename
         * @return
         * @throws IOException
         *             Return:T Description:从文件中读取出Json对象
         */
        public static <T> T readJsonFromFile(TypeReference<T> typeReference, String filename) throws IOException {
            return readJsonFromFile(typeReference, new File(filename));
        }
    
    }

    三. ImageHelper

    package com.jarvis.base.util;
    
    import java.io.ByteArrayInputStream;
    import java.io.ByteArrayOutputStream;
    import java.io.FileInputStream;
    import java.io.FileOutputStream;
    import java.io.IOException;
    import java.io.InputStream;
    import java.io.OutputStream;
    import net.coobird.thumbnailator.Thumbnails;
    import sun.misc.BASE64Decoder;
    import sun.misc.BASE64Encoder;
    
    /**
     *   
     * 
     * @Title: ImageHelper.java
     * @Package com.jarvis.base.util
     * @Description:图片处理工具类。
     * @author Jack 
     * @date 2017年9月2日 下午3:04:40
     * @version V1.0  
     */
    @SuppressWarnings("restriction")
    public class ImageHelper {
        /**
         * @描述:Base64解码并生成图片
         * @入参:@param imgStr
         * @入参:@param imgFile
         * @入参:@throws IOException
         * @出参:void
         */
        public static void generateImage(String imgStr, String imgFile) throws IOException {
            BASE64Decoder decoder = new BASE64Decoder();
            // Base64解码
            byte[] bytes;
            OutputStream out = null;
            try {
                bytes = decoder.decodeBuffer(imgStr);
                for (int i = 0; i < bytes.length; ++i) {
                    if (bytes[i] < 0) {// 调整异常数据
                        bytes[i] += 256;
                    }
                }
                // 生成图片
                out = new FileOutputStream(imgFile);
                out.write(bytes);
                out.flush();
            } catch (IOException e) {
                throw new IOException();
            } finally {
                if (out != null) {
                    try {
                        out.close();
                    } catch (IOException e) {
                        e.printStackTrace();
                    }
                }
            }
    
        }
    
        /**
         * @throws IOException
         * @描述:根据路径得到base编码后图片
         * @入参:@param imgFilePath
         * @入参:@return
         * @出参:String
         */
        public static String getImageStr(String imgFilePath) throws IOException {// 将图片文件转化为字节数组字符串,并对其进行Base64编码处理
            byte[] data = null;
    
            // 读取图片字节数组
            try {
                InputStream in = new FileInputStream(imgFilePath);
                data = new byte[in.available()];
                in.read(data);
                in.close();
            } catch (IOException e) {
                throw new IOException();
            }
    
            // 对字节数组Base64编码
            BASE64Encoder encoder = new BASE64Encoder();
            return encoder.encode(data);// 返回Base64编码过的字节数组字符串
        }
    
        /**
         * @throws IOException
         * @描述:图片旋转
         * @入参:@param base64In 传入的图片base64
         * @入参:@param angle 图片旋转度数
         * @入参:@throws Exception
         * @出参:String 传出的图片base64
         */
        public static String imgAngleRevolve(String base64In, int angle) throws IOException {
            ByteArrayOutputStream os = new ByteArrayOutputStream();
            try {
                Thumbnails.of(base64ToIo(base64In)).scale(1.0).rotate(angle).toOutputStream(os);
            } catch (IOException e) {
                throw new IOException();
            }
            byte[] bs = os.toByteArray();
            String s = new BASE64Encoder().encode(bs);
            return s;
        }
    
        /**
         * @描述:base64转为io流
         * @入参:@param strBase64
         * @入参:@return
         * @入参:@throws IOException
         * @出参:InputStream
         */
        public static InputStream base64ToIo(String strBase64) throws IOException {
            // 解码,然后将字节转换为文件
            byte[] bytes = new BASE64Decoder().decodeBuffer(strBase64); // 将字符串转换为byte数组
            return new ByteArrayInputStream(bytes);
        }
    }

    四. UUID

    package com.jarvis.base.util;
    
    import java.security.MessageDigest;
    import java.security.NoSuchAlgorithmException;
    import java.security.SecureRandom;
    
    /**
     * A class that represents an immutable universally unique identifier (UUID).
     * A UUID represents a 128-bit value.
     * <p/>
     * <p>There exist different variants of these global identifiers. The methods
     * of this class are for manipulating the Leach-Salz variant, although the
     * constructors allow the creation of any variant of UUID (described below).
     * <p/>
     * <p>The layout of a variant 2 (Leach-Salz) UUID is as follows:
     * <p/>
     * The most significant long consists of the following unsigned fields:
     * <pre>
     * 0xFFFFFFFF00000000 time_low
     * 0x00000000FFFF0000 time_mid
     * 0x000000000000F000 version
     * 0x0000000000000FFF time_hi
     * </pre>
     * The least significant long consists of the following unsigned fields:
     * <pre>
     * 0xC000000000000000 variant
     * 0x3FFF000000000000 clock_seq
     * 0x0000FFFFFFFFFFFF node
     * </pre>
     * <p/>
     * <p>The variant field contains a value which identifies the layout of
     * the <tt>UUID</tt>. The bit layout described above is valid only for
     * a <tt>UUID</tt> with a variant value of 2, which indicates the
     * Leach-Salz variant.
     * <p/>
     * <p>The version field holds a value that describes the type of this
     * <tt>UUID</tt>. There are four different basic types of UUIDs: time-based,
     * DCE security, name-based, and randomly generated UUIDs. These types
     * have a version value of 1, 2, 3 and 4, respectively.
     * <p/>
     * <p>For more information including algorithms used to create <tt>UUID</tt>s,
     * see the Internet-Draft <a href="http://www.ietf.org/internet-drafts/draft-mealling-uuid-urn-03.txt">UUIDs and GUIDs</a>
     * or the standards body definition at
     * <a href="http://www.iso.ch/cate/d2229.html">ISO/IEC 11578:1996</a>.
     *
     * @version 1.14, 07/12/04
     * @since 1.5
     */
    @Deprecated
    public final class UUID implements java.io.Serializable
    {
    
        /**
         * Explicit serialVersionUID for interoperability.
         */
        private static final long serialVersionUID = -4856846361193249489L;
    
        /*
         * The most significant 64 bits of this UUID.
         *
         * @serial
         */
        private final long mostSigBits;
    
        /**
         * The least significant 64 bits of this UUID.
         *
         * @serial
         */
        private final long leastSigBits;
    
        /*
         * The version number associated with this UUID. Computed on demand.
         */
        private transient int version = -1;
    
        /*
         * The variant number associated with this UUID. Computed on demand.
         */
        private transient int variant = -1;
    
        /*
         * The timestamp associated with this UUID. Computed on demand.
         */
        private transient volatile long timestamp = -1;
    
        /*
         * The clock sequence associated with this UUID. Computed on demand.
         */
        private transient int sequence = -1;
    
        /*
         * The node number associated with this UUID. Computed on demand.
         */
        private transient long node = -1;
    
        /*
         * The hashcode of this UUID. Computed on demand.
         */
        private transient int hashCode = -1;
    
        /*
         * The random number generator used by this class to create random
         * based UUIDs.
         */
        private static volatile SecureRandom numberGenerator = null;
    
        // Constructors and Factories
    
        /*
         * Private constructor which uses a byte array to construct the new UUID.
         */
        private UUID(byte[] data)
        {
            long msb = 0;
            long lsb = 0;
            for (int i = 0; i < 8; i++)
                msb = (msb << 8) | (data[i] & 0xff);
            for (int i = 8; i < 16; i++)
                lsb = (lsb << 8) | (data[i] & 0xff);
            this.mostSigBits = msb;
            this.leastSigBits = lsb;
        }
    
        /**
         * Constructs a new <tt>UUID</tt> using the specified data.
         * <tt>mostSigBits</tt> is used for the most significant 64 bits
         * of the <tt>UUID</tt> and <tt>leastSigBits</tt> becomes the
         * least significant 64 bits of the <tt>UUID</tt>.
         *
         * @param mostSigBits
         * @param leastSigBits
         */
        public UUID(long mostSigBits, long leastSigBits)
        {
            this.mostSigBits = mostSigBits;
            this.leastSigBits = leastSigBits;
        }
    
        /**
         * Static factory to retrieve a type 4 (pseudo randomly generated) UUID.
         * <p/>
         * The <code>UUID</code> is generated using a cryptographically strong
         * pseudo random number generator.
         *
         * @return a randomly generated <tt>UUID</tt>.
         */
        @SuppressWarnings("unused")
        public static UUID randomUUID()
        {
            SecureRandom ng = numberGenerator;
            if (ng == null)
            {
                numberGenerator = ng = new SecureRandom();
            }
    
            byte[] randomBytes = new byte[16];
            ng.nextBytes(randomBytes);
            randomBytes[6] &= 0x0f;  /* clear version        */
            randomBytes[6] |= 0x40;  /* set to version 4     */
            randomBytes[8] &= 0x3f;  /* clear variant        */
            randomBytes[8] |= 0x80;  /* set to IETF variant  */
            UUID result = new UUID(randomBytes);
            return new UUID(randomBytes);
        }
    
        /**
         * Static factory to retrieve a type 3 (name based) <tt>UUID</tt> based on
         * the specified byte array.
         *
         * @param name a byte array to be used to construct a <tt>UUID</tt>.
         * @return a <tt>UUID</tt> generated from the specified array.
         */
        public static UUID nameUUIDFromBytes(byte[] name)
        {
            MessageDigest md;
            try
            {
                md = MessageDigest.getInstance("MD5");
            }
            catch (NoSuchAlgorithmException nsae)
            {
                throw new InternalError("MD5 not supported");
            }
            byte[] md5Bytes = md.digest(name);
            md5Bytes[6] &= 0x0f;  /* clear version        */
            md5Bytes[6] |= 0x30;  /* set to version 3     */
            md5Bytes[8] &= 0x3f;  /* clear variant        */
            md5Bytes[8] |= 0x80;  /* set to IETF variant  */
            return new UUID(md5Bytes);
        }
    
        /**
         * Creates a <tt>UUID</tt> from the string standard representation as
         * described in the {@link #toString} method.
         *
         * @param name a string that specifies a <tt>UUID</tt>.
         * @return a <tt>UUID</tt> with the specified value.
         * @throws IllegalArgumentException if name does not conform to the
         *                                  string representation as described in {@link #toString}.
         */
        public static UUID fromString(String name)
        {
            String[] components = name.split("-");
            if (components.length != 5)
                throw new IllegalArgumentException("Invalid UUID string: " + name);
            for (int i = 0; i < 5; i++)
                components[i] = "0x" + components[i];
    
            long mostSigBits = Long.decode(components[0]).longValue();
            mostSigBits <<= 16;
            mostSigBits |= Long.decode(components[1]).longValue();
            mostSigBits <<= 16;
            mostSigBits |= Long.decode(components[2]).longValue();
    
            long leastSigBits = Long.decode(components[3]).longValue();
            leastSigBits <<= 48;
            leastSigBits |= Long.decode(components[4]).longValue();
    
            return new UUID(mostSigBits, leastSigBits);
        }
    
        // Field Accessor Methods
    
        /**
         * Returns the least significant 64 bits of this UUID's 128 bit value.
         *
         * @return the least significant 64 bits of this UUID's 128 bit value.
         */
        public long getLeastSignificantBits()
        {
            return leastSigBits;
        }
    
        /**
         * Returns the most significant 64 bits of this UUID's 128 bit value.
         *
         * @return the most significant 64 bits of this UUID's 128 bit value.
         */
        public long getMostSignificantBits()
        {
            return mostSigBits;
        }
    
        /**
         * The version number associated with this <tt>UUID</tt>. The version
         * number describes how this <tt>UUID</tt> was generated.
         * <p/>
         * The version number has the following meaning:<p>
         * <ul>
         * <li>1    Time-based UUID
         * <li>2    DCE security UUID
         * <li>3    Name-based UUID
         * <li>4    Randomly generated UUID
         * </ul>
         *
         * @return the version number of this <tt>UUID</tt>.
         */
        public int version()
        {
            if (version < 0)
            {
                // Version is bits masked by 0x000000000000F000 in MS long
                version = (int) ((mostSigBits >> 12) & 0x0f);
            }
            return version;
        }
    
        /**
         * The variant number associated with this <tt>UUID</tt>. The variant
         * number describes the layout of the <tt>UUID</tt>.
         * <p/>
         * The variant number has the following meaning:<p>
         * <ul>
         * <li>0    Reserved for NCS backward compatibility
         * <li>2    The Leach-Salz variant (used by this class)
         * <li>6    Reserved, Microsoft Corporation backward compatibility
         * <li>7    Reserved for future definition
         * </ul>
         *
         * @return the variant number of this <tt>UUID</tt>.
         */
        public int variant()
        {
            if (variant < 0)
            {
                // This field is composed of a varying number of bits
                if ((leastSigBits >>> 63) == 0)
                {
                    variant = 0;
                }
                else if ((leastSigBits >>> 62) == 2)
                {
                    variant = 2;
                }
                else
                {
                    variant = (int) (leastSigBits >>> 61);
                }
            }
            return variant;
        }
    
        /**
         * The timestamp value associated with this UUID.
         * <p/>
         * <p>The 60 bit timestamp value is constructed from the time_low,
         * time_mid, and time_hi fields of this <tt>UUID</tt>. The resulting
         * timestamp is measured in 100-nanosecond units since midnight,
         * October 15, 1582 UTC.<p>
         * <p/>
         * The timestamp value is only meaningful in a time-based UUID, which
         * has version type 1. If this <tt>UUID</tt> is not a time-based UUID then
         * this method throws UnsupportedOperationException.
         *
         * @throws UnsupportedOperationException if this UUID is not a
         *                                       version 1 UUID.
         */
        public long timestamp()
        {
            if (version() != 1)
            {
                throw new UnsupportedOperationException("Not a time-based UUID");
            }
            long result = timestamp;
            if (result < 0)
            {
                result = (mostSigBits & 0x0000000000000FFFL) << 48;
                result |= ((mostSigBits >> 16) & 0xFFFFL) << 32;
                result |= mostSigBits >>> 32;
                timestamp = result;
            }
            return result;
        }
    
        /**
         * The clock sequence value associated with this UUID.
         * <p/>
         * <p>The 14 bit clock sequence value is constructed from the clock
         * sequence field of this UUID. The clock sequence field is used to
         * guarantee temporal uniqueness in a time-based UUID.<p>
         * <p/>
         * The  clockSequence value is only meaningful in a time-based UUID, which
         * has version type 1. If this UUID is not a time-based UUID then
         * this method throws UnsupportedOperationException.
         *
         * @return the clock sequence of this <tt>UUID</tt>.
         * @throws UnsupportedOperationException if this UUID is not a
         *                                       version 1 UUID.
         */
        public int clockSequence()
        {
            if (version() != 1)
            {
                throw new UnsupportedOperationException("Not a time-based UUID");
            }
            if (sequence < 0)
            {
                sequence = (int) ((leastSigBits & 0x3FFF000000000000L) >>> 48);
            }
            return sequence;
        }
    
        /**
         * The node value associated with this UUID.
         * <p/>
         * <p>The 48 bit node value is constructed from the node field of
         * this UUID. This field is intended to hold the IEEE 802 address
         * of the machine that generated this UUID to guarantee spatial
         * uniqueness.<p>
         * <p/>
         * The node value is only meaningful in a time-based UUID, which
         * has version type 1. If this UUID is not a time-based UUID then
         * this method throws UnsupportedOperationException.
         *
         * @return the node value of this <tt>UUID</tt>.
         * @throws UnsupportedOperationException if this UUID is not a
         *                                       version 1 UUID.
         */
        public long node()
        {
            if (version() != 1)
            {
                throw new UnsupportedOperationException("Not a time-based UUID");
            }
            if (node < 0)
            {
                node = leastSigBits & 0x0000FFFFFFFFFFFFL;
            }
            return node;
        }
    
        // Object Inherited Methods
    
        /**
         * Returns a <code>String</code> object representing this
         * <code>UUID</code>.
         * <p/>
         * <p>The UUID string representation is as described by this BNF :
         * <pre>
         *  UUID                   = <time_low> "-" <time_mid> "-"
         *                           <time_high_and_version> "-"
         *                           <variant_and_sequence> "-"
         *                           <node>
         *  time_low               = 4*<hexOctet>
         *  time_mid               = 2*<hexOctet>
         *  time_high_and_version  = 2*<hexOctet>
         *  variant_and_sequence   = 2*<hexOctet>
         *  node                   = 6*<hexOctet>
         *  hexOctet               = <hexDigit><hexDigit>
         *  hexDigit               =
         *        "0" | "1" | "2" | "3" | "4" | "5" | "6" | "7" | "8" | "9"
         *        | "a" | "b" | "c" | "d" | "e" | "f"
         *        | "A" | "B" | "C" | "D" | "E" | "F"
         * </pre>
         *
         * @return a string representation of this <tt>UUID</tt>.
         */
        public String toString()
        {
            return (digits(mostSigBits >> 32, 8) + "-" +
                    digits(mostSigBits >> 16, 4) + "-" +
                    digits(mostSigBits, 4) + "-" +
                    digits(leastSigBits >> 48, 4) + "-" +
                    digits(leastSigBits, 12));
        }
    
        /**
         * Returns val represented by the specified number of hex digits.
         */
        private static String digits(long val, int digits)
        {
            long hi = 1L << (digits * 4);
            return Long.toHexString(hi | (val & (hi - 1))).substring(1);
        }
    
        /**
         * Returns a hash code for this <code>UUID</code>.
         *
         * @return a hash code value for this <tt>UUID</tt>.
         */
        public int hashCode()
        {
            if (hashCode == -1)
            {
                hashCode = (int) ((mostSigBits >> 32) ^
                        mostSigBits ^
                        (leastSigBits >> 32) ^
                        leastSigBits);
            }
            return hashCode;
        }
    
        /**
         * Compares this object to the specified object.  The result is
         * <tt>true</tt> if and only if the argument is not
         * <tt>null</tt>, is a <tt>UUID</tt> object, has the same variant,
         * and contains the same value, bit for bit, as this <tt>UUID</tt>.
         *
         * @param obj the object to compare with.
         * @return <code>true</code> if the objects are the same;
         *         <code>false</code> otherwise.
         */
        public boolean equals(Object obj)
        {
            if (!(obj instanceof UUID))
                return false;
            if (((UUID) obj).variant() != this.variant())
                return false;
            UUID id = (UUID) obj;
            return (mostSigBits == id.mostSigBits &&
                    leastSigBits == id.leastSigBits);
        }
    
        // Comparison Operations
    
        /**
         * Compares this UUID with the specified UUID.
         * <p/>
         * <p>The first of two UUIDs follows the second if the most significant
         * field in which the UUIDs differ is greater for the first UUID.
         *
         * @param val <tt>UUID</tt> to which this <tt>UUID</tt> is to be compared.
         * @return -1, 0 or 1 as this <tt>UUID</tt> is less than, equal
         *         to, or greater than <tt>val</tt>.
         */
        public int compareTo(UUID val)
        {
            // The ordering is intentionally set up so that the UUIDs
            // can simply be numerically compared as two numbers
            return (this.mostSigBits < val.mostSigBits ? -1 :
                    (this.mostSigBits > val.mostSigBits ? 1 :
                            (this.leastSigBits < val.leastSigBits ? -1 :
                                    (this.leastSigBits > val.leastSigBits ? 1 :
                                            0))));
        }
    
        /**
         * Reconstitute the <tt>UUID</tt> instance from a stream (that is,
         * deserialize it). This is necessary to set the transient fields
         * to their correct uninitialized value so they will be recomputed
         * on demand.
         */
        private void readObject(java.io.ObjectInputStream in)
                throws java.io.IOException, ClassNotFoundException
        {
    
            in.defaultReadObject();
    
            // Set "cached computation" fields to their initial values
            version = -1;
            variant = -1;
            timestamp = -1;
            sequence = -1;
            node = -1;
            hashCode = -1;
        }
       
    }
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  • 原文地址:https://www.cnblogs.com/ncy1/p/9814075.html
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