【免费】Base64加解密算法资源-CSDN文库

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h：1个

cpp：1个

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Base64是一种网络上常见的数据编码方式，它将任意二进制数据转化为可打印的ASCII字符，主要用于在电子邮件等文本环境中传输非文本数据。Base64编码的基本原理是将每3个字节（24位）的数据转换为4个6位的十六进制数，再用64个预定义的字符表示这6位数，这些字符包括大小写字母、数字以及"+"和"/"，最后用"="作为填充符。在给定的标题"Base64 加解密算法"中，提到的是一个已经封装好的Base64加解密工具，可以处理文件和字符串。这意味着它具备两个核心功能：Base64编码和Base64解码。编码过程是将原始数据转化为Base64格式的字符串，而解码则是将Base64字符串还原为原始的二进制数据。描述中提到的"实现了对文件的算法"，意味着这个库不仅支持对字符串进行Base64操作，还能够读取文件内容进行编码或解码。使用MFC（Microsoft Foundation Classes）库函数进行文件读写，但同时也指出可以去除MFC依赖，以适应更多不依赖MFC环境的项目。这表明该库具有较好的移植性。标签"Base64 加解密文件"进一步强调了该库的功能焦点，即处理与文件相关的Base64加解密任务。这可能包括读取文件内容，对其进行Base64编码，然后将编码后的字符串写入新文件，或者从含有Base64编码的字符串中解码并写回原始二进制文件。在压缩包内的文件"CBase64.cpp"和"CBase64.h"中，我们可以推测这是实现Base64算法的C++源代码文件。`CBase64.cpp`很可能包含了类的实现，包括编码和解码的函数，而`CBase64.h`则是头文件，定义了相关的类接口和函数原型，供其他模块调用。这样的设计符合面向对象编程的原则，使得代码结构清晰，易于维护和使用。在实际应用中，Base64加解密算法广泛用于数据的网络传输、存储和显示，比如在HTTPS协议中传输证书、在电子邮件中传递图片，或者在JSON格式中编码二进制数据等。通过这个封装好的库，开发者可以轻松地在自己的项目中集成Base64功能，提高开发效率。

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CBase64.rar （2个子文件）

CBase64.h 3KB

CBase64.cpp 9KB

/************************************************ * * * CBase64.cpp * * Base 64 de- and encoding class * * * * ============================================ * * * * This class was written on 28.05.2003 * * by Jan Raddatz [jan-raddatz@web.de] * * * * ============================================ * * * * Copyright (c) by Jan Raddatz * * This class was published @ codeguru.com * * 28.05.2003 * * * ************************************************/ #include "CBase64.h" CBase64::CBase64 () { } unsigned int CBase64::CalculateRecquiredEncodeOutputBufferSize (unsigned int p_InputByteCount) { div_t result = div (p_InputByteCount, 3); unsigned int RecquiredBytes = 0; if (result.rem == 0) { // Number of encoded characters RecquiredBytes = result.quot * 4; // CRLF -> "\r\n" each 76 characters result = div (RecquiredBytes, 76); RecquiredBytes += result.quot * 2; // Terminating null for the Encoded String RecquiredBytes += 1; return RecquiredBytes; } else { // Number of encoded characters RecquiredBytes = result.quot * 4 + 4; // CRLF -> "\r\n" each 76 characters result = div (RecquiredBytes, 76); RecquiredBytes += result.quot * 2; // Terminating null for the Encoded String RecquiredBytes += 1; return RecquiredBytes; } } unsigned int CBase64::CalculateRecquiredDecodeOutputBufferSize (char* p_pInputBufferString) { unsigned int BufferLength = strlen (p_pInputBufferString); div_t result = div (BufferLength, 4); if (p_pInputBufferString [BufferLength - 1] != '=') { return result.quot * 3; } else { if (p_pInputBufferString [BufferLength - 2] == '=') { return result.quot * 3 - 2; } else { return result.quot * 3 - 1; } } } void CBase64::EncodeByteTriple (char* p_pInputBuffer, unsigned int InputCharacters, char* p_pOutputBuffer) { unsigned int mask = 0xfc000000; unsigned int buffer = 0; char* temp = (char*) &buffer; temp [3] = p_pInputBuffer [0]; if (InputCharacters > 1) temp [2] = p_pInputBuffer [1]; if (InputCharacters > 2) temp [1] = p_pInputBuffer [2]; switch (InputCharacters) { case 3: { p_pOutputBuffer [0] = BASE64_ALPHABET [(buffer & mask) >> 26]; buffer = buffer << 6; p_pOutputBuffer [1] = BASE64_ALPHABET [(buffer & mask) >> 26]; buffer = buffer << 6; p_pOutputBuffer [2] = BASE64_ALPHABET [(buffer & mask) >> 26]; buffer = buffer << 6; p_pOutputBuffer [3] = BASE64_ALPHABET [(buffer & mask) >> 26]; break; } case 2: { p_pOutputBuffer [0] = BASE64_ALPHABET [(buffer & mask) >> 26]; buffer = buffer << 6; p_pOutputBuffer [1] = BASE64_ALPHABET [(buffer & mask) >> 26]; buffer = buffer << 6; p_pOutputBuffer [2] = BASE64_ALPHABET [(buffer & mask) >> 26]; p_pOutputBuffer [3] = '='; break; } case 1: { p_pOutputBuffer [0] = BASE64_ALPHABET [(buffer & mask) >> 26]; buffer = buffer << 6; p_pOutputBuffer [1] = BASE64_ALPHABET [(buffer & mask) >> 26]; p_pOutputBuffer [2] = '='; p_pOutputBuffer [3] = '='; break; } } } unsigned int CBase64::DecodeByteQuartet (char* p_pInputBuffer, char* p_pOutputBuffer) { unsigned int buffer = 0; if (p_pInputBuffer[3] == '=') { if (p_pInputBuffer[2] == '=') { buffer = (buffer | BASE64_DEALPHABET [p_pInputBuffer[0]]) << 6; buffer = (buffer | BASE64_DEALPHABET [p_pInputBuffer[1]]) << 6; buffer = buffer << 14; char* temp = (char*) &buffer; p_pOutputBuffer [0] = temp [3]; return 1; } else { buffer = (buffer | BASE64_DEALPHABET [p_pInputBuffer[0]]) << 6; buffer = (buffer | BASE64_DEALPHABET [p_pInputBuffer[1]]) << 6; buffer = (buffer | BASE64_DEALPHABET [p_pInputBuffer[2]]) << 6; buffer = buffer << 8; char* temp = (char*) &buffer; p_pOutputBuffer [0] = temp [3]; p_pOutputBuffer [1] = temp [2]; return 2; } } else { buffer = (buffer | BASE64_DEALPHABET [p_pInputBuffer[0]]) << 6; buffer = (buffer | BASE64_DEALPHABET [p_pInputBuffer[1]]) << 6; buffer = (buffer | BASE64_DEALPHABET [p_pInputBuffer[2]]) << 6; buffer = (buffer | BASE64_DEALPHABET [p_pInputBuffer[3]]) << 6; buffer = buffer << 2; char* temp = (char*) &buffer; p_pOutputBuffer [0] = temp [3]; p_pOutputBuffer [1] = temp [2]; p_pOutputBuffer [2] = temp [1]; return 3; } return -1; } void CBase64::EncodeBuffer (char* p_pInputBuffer, unsigned int p_InputBufferLength, char* p_pOutputBufferString) { unsigned int FinishedByteQuartetsPerLine = 0; unsigned int InputBufferIndex = 0; unsigned int OutputBufferIndex = 0; memset (p_pOutputBufferString, 0, CalculateRecquiredEncodeOutputBufferSize (p_InputBufferLength)); while (InputBufferIndex < p_InputBufferLength) { if (p_InputBufferLength - InputBufferIndex <= 2) { FinishedByteQuartetsPerLine ++; EncodeByteTriple (p_pInputBuffer + InputBufferIndex, p_InputBufferLength - InputBufferIndex, p_pOutputBufferString + OutputBufferIndex); break; } else { FinishedByteQuartetsPerLine++; EncodeByteTriple (p_pInputBuffer + InputBufferIndex, 3, p_pOutputBufferString + OutputBufferIndex); InputBufferIndex += 3; OutputBufferIndex += 4; } if (FinishedByteQuartetsPerLine == 19) { p_pOutputBufferString [OutputBufferIndex ] = '\r'; p_pOutputBufferString [OutputBufferIndex+1] = '\n'; p_pOutputBufferString += 2; FinishedByteQuartetsPerLine = 0; } } } unsigned int CBase64::DecodeBuffer (char* p_pInputBufferString, char* p_pOutputBuffer) { unsigned int InputBufferIndex = 0; unsigned int OutputBufferIndex = 0; unsigned int InputBufferLength = strlen (p_pInputBufferString); char ByteQuartet [4]; while (InputBufferIndex < InputBufferLength) { for (int i = 0; i < 4; i++) { ByteQuartet [i] = p_pInputBufferString [InputBufferIndex]; // Ignore all characters except the ones in BASE64_ALPHABET if ((ByteQuartet [i] >= 48 && ByteQuartet [i] <= 57) || (ByteQuartet [i] >= 65 && ByteQuartet [i] <= 90) || (ByteQuartet [i] >= 97 && ByteQuartet [i] <= 122) || ByteQuartet [i] == '+' || ByteQuartet [i] == '/' || ByteQuartet [i] == '=') { } else { // Invalid character i--; } InputBufferIndex++; } OutputBufferIndex += DecodeByteQuartet (ByteQuartet, p_pOutputBuffer + OutputBufferIndex); } // OutputBufferIndex gives us the next position of the next decoded character // inside our output buffer and thus represents the number of decoded characters // in our buffer. return OutputBufferIndex; } unsigned int CBase64::CreateMatchingEncodingBuffer (unsigned int p_InputByteCount, char** p_ppEncodingBuffer) { unsigned int Size = CalculateRecquiredEncodeOutputBufferSize (p_InputByteCount); (*p_ppEncodingBuffer) = (char*) malloc (Size); memset (*p_ppEncodingBuffer, 0, Size); return Size; } unsigned int CBase64::CreateMatchingDecodingBuffer (char* p_pInputBufferString, char** p_ppDecodingBuffer) { unsigned int Size = CalculateRecquiredDecodeOutputBufferSize (p_pInputBufferString); (*p_ppDecodingBuffer) = (char*) malloc (Size); memset (*p_ppDecodingBuffer, 0, Size); return Size; } unsigned int CBase64::EncodeFile (char* p_pSourceFileName, char* p_pEncodedFileName) { CFile InputFile; CFile OutputFile; if (!InputFile.Open (p_pSourceFileName, CFile::modeRead)) return UNABLE_TO_OPEN_INPUT_FILE; if (!OutputFile.Open (p_pEncodedFileName, CFile::modeCreate|CFile::modeWrite)) return UNABLE_TO_OPEN_OUTPUT_FILE; char InputBuffer [19 * 3]; char* pOutputBuffer; CreateMatchingEncodingBuffer (sizeof (InputBuffer), &pOutputBuffer); if (pOutputBuffe