基于Java实现的Base64加密、解密原理代码
一、概述
1.base64是什么:
base64是网络上最常见的用于传输8bit字节代码的编码方式之一,大家可以查看rfc2045~rfc2049,上面有mime的详细规范。base64编码可用于在http环境下传递较长的标识信息。例如,在java persistence系统hibernate中,就采用了base64来将一个较长的唯一标识符(一般为128-bit的uuid)编码为一个字符串,用作http表单和http get url中的参数。在其他应用程序中,也常常需要把二进制数据编码为适合放在url(包括隐藏表单域)中的形式。此时,采用base64编码不仅比较简短,同时也具有不可读性,即所编码的数据不会被人用肉眼所直接看到
2.简介:
标准的base64并不适合直接放在url里传输,因为url编码器会把标准base64中的“/”和“+”字符变为形如“%xx”的形式,而这些“%”号在存入数据库时还需要再进行转换,因为ansi sql中已将“%”号用作通配符。
为解决此问题,可采用一种用于url的改进base64编码,它不在末尾填充'='号,并将标准base64中的“+”和“/”分别改成了“*”和“-”,这样就免去了在url编解码和数据库存储时所要作的转换,避免了编码信息长度在此过程中的增加,并统一了数据库、表单等处对象标识符的格式。
另有一种用于正则表达式的改进base64变种,它将“+”和“/”改成了“!”和“-”,因为“+”,“*”以及前面在ircu中用到的“[”和“]”在正则表达式中都可能具有特殊含义。
此外还有一些变种,它们将“+/”改为“_-”或“._”(用作编程语言中的标识符名称)或“.-”(用于xml中的nmtoken)甚至“_:”(用于xml中的name)。
base64要求把每三个8bit的字节转换为四个6bit的字节(3*8 = 4*6 = 24),然后把6bit再添两位高位0,组成四个8bit的字节,也就是说,转换后的字符串理论上将要比原来的长1/3。
3.规则:
关于这个编码的规则:
①.把3个字符变成4个字符..
②.每76个字符加一个换行符..
③.最后的结束符也要处理..
这样说会不会太抽象了?不用着急,我们来看一个例子:
转换前: aaaaaabb ccccdddd eeffffff
转换后: 00aaaaaa 00bbcccc 00ddddee 00ffffff
应该很清楚了吧?上面的三个字节是原文,下面的四个字节是转换后的base64编码,其前两位均为0。
转换后,我们用一个码表来得到我们想要的字符串(也就是最终的base64编码)
二、java实现代码示例:
public final class base64 { static private final int baselength = 255; static private final int lookuplength = 64; static private final int twentyfourbitgroup = 24; static private final int eightbit = 8; static private final int sixteenbit = 16; static private final int sixbit = 6; static private final int fourbyte = 4; static private final int sign = -128; static private final char pad = '='; static private final boolean fdebug = false; static final private byte[] base64alphabet = new byte[baselength]; static final private char[] lookupbase64alphabet = new char[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] = (char) ('a' + i); for (int i = 26, j = 0; i <= 51; i++, j++) lookupbase64alphabet[i] = (char) ('a' + j); for (int i = 52, j = 0; i <= 61; i++, j++) lookupbase64alphabet[i] = (char) ('0' + j); lookupbase64alphabet[62] = (char) '+'; lookupbase64alphabet[63] = (char) '/'; } protected static boolean iswhitespace(char octect) { return (octect == 0x20 || octect == 0xd || octect == 0xa || octect == 0x9); } protected static boolean ispad(char octect) { return (octect == pad); } protected static boolean isdata(char octect) { return (base64alphabet[octect] != -1); } protected static boolean isbase64(char octect) { return (iswhitespace(octect) || ispad(octect) || isdata(octect)); } /** * encodes hex octects into base64 * * @param binarydata * array containing binarydata * @return encoded base64 array */ public static string encode(byte[] binarydata) { if (binarydata == null) return null; int lengthdatabits = binarydata.length * eightbit; if (lengthdatabits == 0) { return ""; } int fewerthan24bits = lengthdatabits % twentyfourbitgroup; int numbertriplets = lengthdatabits / twentyfourbitgroup; int numberquartet = fewerthan24bits != 0 ? numbertriplets + 1 : numbertriplets; int numberlines = (numberquartet - 1) / 19 + 1; char encodeddata[] = null; encodeddata = new char[numberquartet * 4 + numberlines]; byte k = 0, l = 0, b1 = 0, b2 = 0, b3 = 0; int encodedindex = 0; int dataindex = 0; int i = 0; if (fdebug) { system.out.println("number of triplets = " + numbertriplets); } for (int line = 0; line < numberlines - 1; line++) { for (int quartet = 0; quartet < 19; quartet++) { b1 = binarydata[dataindex++]; b2 = binarydata[dataindex++]; b3 = binarydata[dataindex++]; if (fdebug) { system.out.println("b1= " + b1 + ", b2= " + b2 + ", b3= " + b3); } 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); byte val3 = ((b3 & sign) == 0) ? (byte) (b3 >> 6) : (byte) ((b3) >> 6 ^ 0xfc); if (fdebug) { system.out.println("val2 = " + val2); system.out.println("k4 = " + (k << 4)); system.out.println("vak = " + (val2 | (k << 4))); } encodeddata[encodedindex++] = lookupbase64alphabet[val1]; encodeddata[encodedindex++] = lookupbase64alphabet[val2 | (k << 4)]; encodeddata[encodedindex++] = lookupbase64alphabet[(l << 2) | val3]; encodeddata[encodedindex++] = lookupbase64alphabet[b3 & 0x3f]; i++; } encodeddata[encodedindex++] = 0xa; } for (; i < numbertriplets; i++) { b1 = binarydata[dataindex++]; b2 = binarydata[dataindex++]; b3 = binarydata[dataindex++]; if (fdebug) { system.out.println("b1= " + b1 + ", b2= " + b2 + ", b3= " + b3); } 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); byte val3 = ((b3 & sign) == 0) ? (byte) (b3 >> 6) : (byte) ((b3) >> 6 ^ 0xfc); if (fdebug) { system.out.println("val2 = " + val2); system.out.println("k4 = " + (k << 4)); system.out.println("vak = " + (val2 | (k << 4))); } encodeddata[encodedindex++] = lookupbase64alphabet[val1]; encodeddata[encodedindex++] = lookupbase64alphabet[val2 | (k << 4)]; encodeddata[encodedindex++] = lookupbase64alphabet[(l << 2) | val3]; encodeddata[encodedindex++] = lookupbase64alphabet[b3 & 0x3f]; } // form integral number of 6-bit groups if (fewerthan24bits == eightbit) { b1 = binarydata[dataindex]; k = (byte) (b1 & 0x03); if (fdebug) { system.out.println("b1=" + b1); system.out.println("b1<<2 = " + (b1 >> 2)); } byte val1 = ((b1 & sign) == 0) ? (byte) (b1 >> 2) : (byte) ((b1) >> 2 ^ 0xc0); encodeddata[encodedindex++] = lookupbase64alphabet[val1]; encodeddata[encodedindex++] = lookupbase64alphabet[k << 4]; encodeddata[encodedindex++] = pad; encodeddata[encodedindex++] = 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++] = lookupbase64alphabet[val2 | (k << 4)]; encodeddata[encodedindex++] = lookupbase64alphabet[l << 2]; encodeddata[encodedindex++] = pad; } encodeddata[encodedindex] = 0xa; return new string(encodeddata); } /** * decodes base64 data into octects * * @param binarydata * byte array containing base64 data * @return array containind decoded data. */ public static byte[] decode(string encoded) { if (encoded == null) return null; char[] base64data = encoded.tochararray(); // remove white spaces int len = removewhitespace(base64data); if (len % fourbyte != 0) { return null;// should be divisible by four } int numberquadruple = (len / fourbyte); if (numberquadruple == 0) return new byte[0]; byte decodeddata[] = null; byte b1 = 0, b2 = 0, b3 = 0, b4 = 0, marker0 = 0, marker1 = 0; char d1 = 0, d2 = 0, d3 = 0, d4 = 0; int i = 0; int encodedindex = 0; int dataindex = 0; decodeddata = new byte[(numberquadruple) * 3]; for (; i < numberquadruple - 1; i++) { if (!isdata((d1 = base64data[dataindex++])) || !isdata((d2 = base64data[dataindex++])) || !isdata((d3 = base64data[dataindex++])) || !isdata((d4 = base64data[dataindex++]))) return null;// if found "no data" just return null b1 = base64alphabet[d1]; b2 = base64alphabet[d2]; b3 = base64alphabet[d3]; b4 = base64alphabet[d4]; decodeddata[encodedindex++] = (byte) (b1 << 2 | b2 >> 4); decodeddata[encodedindex++] = (byte) (((b2 & 0xf) << 4) | ((b3 >> 2) & 0xf)); decodeddata[encodedindex++] = (byte) (b3 << 6 | b4); } if (!isdata((d1 = base64data[dataindex++])) || !isdata((d2 = base64data[dataindex++]))) { return null;// if found "no data" just return null } b1 = base64alphabet[d1]; b2 = base64alphabet[d2]; d3 = base64data[dataindex++]; d4 = base64data[dataindex++]; if (!isdata((d3)) || !isdata((d4))) {// check if they are pad characters if (ispad(d3) && ispad(d4)) { // two pad e.g. 3c[pad][pad] if ((b2 & 0xf) != 0)// last 4 bits should be zero return null; byte[] tmp = new byte[i * 3 + 1]; system.arraycopy(decodeddata, 0, tmp, 0, i * 3); tmp[encodedindex] = (byte) (b1 << 2 | b2 >> 4); return tmp; } else if (!ispad(d3) && ispad(d4)) { // one pad e.g. 3cq[pad] b3 = base64alphabet[d3]; if ((b3 & 0x3) != 0)// last 2 bits should be zero return null; byte[] tmp = new byte[i * 3 + 2]; system.arraycopy(decodeddata, 0, tmp, 0, i * 3); tmp[encodedindex++] = (byte) (b1 << 2 | b2 >> 4); tmp[encodedindex] = (byte) (((b2 & 0xf) << 4) | ((b3 >> 2) & 0xf)); return tmp; } else { return null;// an error like "3c[pad]r", "3cdx", "3cxd", "3cxx" // where x is non data } } else { // no pad e.g 3cql b3 = base64alphabet[d3]; b4 = base64alphabet[d4]; decodeddata[encodedindex++] = (byte) (b1 << 2 | b2 >> 4); decodeddata[encodedindex++] = (byte) (((b2 & 0xf) << 4) | ((b3 >> 2) & 0xf)); decodeddata[encodedindex++] = (byte) (b3 << 6 | b4); } return decodeddata; } /** * remove whitespace from mime containing encoded base64 data. * * @param data * the byte array of base64 data (with ws) * @return the new length */ protected static int removewhitespace(char[] data) { if (data == null) return 0; // count characters that's not whitespace int newsize = 0; int len = data.length; for (int i = 0; i < len; i++) { if (!iswhitespace(data[i])) data[newsize++] = data[i]; } return newsize; } public static void main(string[] args) { system.out.println(encode("*".getbytes())); } }
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