• Delphi- 数据加密和解密


      Delphi进行数据加密,在数据库方面经常要使用到。从网上转载过来的,以后会经常会用到。

      一、MD5加密算法

      在C#/.Net里提供了MD5加密的类库。在Delphi中没有。只能自己建一个新的单位,将网上别人写的MD5加密函数拿来用。

    {******************************************************************}
    {          MD5 Hashsum Evaluation Unit For Borland Delphi          }
    {                                                                  }
    {          Copyright ? 2002 by Dimka Maslov                        }
    {          E-mail:   mail@endimus.com,                             }
    {          Web-site: http://www.endimus.com                        }
    {                                                                  }
    {         Derived from the RSA Data Security, Inc.                 }
    {         MD5 Message-Digest Algorithm described in RFC 1321       }
    {         http://www.faqs.org/rfcs/rfc1321.html                    }
    {******************************************************************}
    
    unit MD5Unit;
    
    interface
    
    uses Windows, SysUtils, Classes;
    
    type
    { The TMD5Digest record is the type of results of
      the MD5 hashsum evaluation functions. The contents
      of a record may be used as four 32-bit integer values
      or as an array of 16 bytes }
     PMD5Digest = ^TMD5Digest;
     TMD5Digest = record
      case Integer of
       0: (A, B, C, D: LongInt);
       1: (v: array [0..15] of Byte);
     end;
    
    { The MD5String function evaluates the MD5 hashsum for
      a string. The S parameter specifies a string to
      evaluate hashsum }
    procedure MD5String(const S: string;PMD5:PMD5Digest);
    
    { The MD5File function evaluates the MD5 hashsum for
      a file. The FileName parameter specifies the name
      of a file to evaluate hashsum }
    procedure MD5File(const FileName: string;PMD5:PMD5Digest);
    
    { The MD5Stream function evaluates the MD5 hashsum for
      a stream. The Stream parameters specifies the
      TStream descendant class object to evaluate hashsum }
    procedure MD5Stream(const Stream: TStream;PMD5:PMD5Digest);
    
    { The MD5Buffer function evaluates the MD5 hashsum for
      any memory buffer. The Buffer parameters specifies a
      buffer to evaluate hashsum. The Size parameter specifies
      the size (in bytes) of a buffer }
    procedure MD5Buffer(const Buffer; Size: Integer;PMD5:PMD5Digest);
    
    { The MD5DigestToStr function converts the result of
      a hashsum evaluation function into a string of
      hexadecimal digits }
    function MD5DigestToStr(const Digest: TMD5Digest): string;
    
    { The MD5DigestCompare function compares two
      TMD5Digest record variables. This function returns
      TRUE if parameters are equal or FALSE otherwise }
    function MD5DigestCompare(const Digest1, Digest2: TMD5Digest): Boolean;
    
    implementation
    
    {
    Copyright (C) 1991-2, RSA Data Security, Inc. Created 1991. All
    rights reserved.
    
    License to copy and use this software is granted provided that it
    is identified as the "RSA Data Security, Inc. MD5 Message-Digest
    Algorithm" in all material mentioning or referencing this software
    or this function.
    
    License is also granted to make and use derivative works provided
    that such works are identified as "derived from the RSA Data
    Security, Inc. MD5 Message-Digest Algorithm" in all material
    mentioning or referencing the derived work.
    
    RSA Data Security, Inc. makes no representations concerning either
    the merchantability of this software or the suitability of this
    software for any particular purpose. It is provided "as is"
    without express or implied warranty of any kind.
    
    These notices must be retained in any copies of any part of this
    documentation and/or software.
    }
    
    
    type
     UINT4 = LongWord;
    
     PArray4UINT4 = ^TArray4UINT4;
     TArray4UINT4 = array [0..3] of UINT4;
     PArray2UINT4 = ^TArray2UINT4;
     TArray2UINT4 = array [0..1] of UINT4;
     PArray16Byte = ^TArray16Byte;
     TArray16Byte = array [0..15] of Byte;
     PArray64Byte = ^TArray64Byte;
     TArray64Byte = array [0..63] of Byte;
    
     PByteArray = ^TByteArray;
     TByteArray = array [0..0] of Byte;
    
     PUINT4Array = ^TUINT4Array;
     TUINT4Array = array [0..0] of UINT4;
    
     PMD5Context = ^TMD5Context;
     TMD5Context = record
       state: TArray4UINT4;
       count: TArray2UINT4;
       buffer: TArray64Byte;
     end;
    
    const
      S11 = 7;
      S12 = 12;
      S13 = 17;
      S14 = 22;
      S21 = 5;
      S22 = 9;
      S23 = 14;
      S24 = 20;
      S31 = 4;
      S32 = 11;
      S33 = 16;
      S34 = 23;
      S41 = 6;
      S42 = 10;
      S43 = 15;
      S44 = 21;
    
    var
     Padding : TArray64Byte =
     ($80, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
      0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
      0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0);
    
    
    function _F(x, y, z: UINT4): UINT4;
    begin
     Result := (((x) and (y)) or ((not x) and (z)));
    end;
    
    function _G(x, y, z: UINT4): UINT4;
    begin
     Result := (((x) and (z)) or ((y) and (not z)));
    end;
    
    function _H(x, y, z: UINT4): UINT4;
    begin
     Result := ((x) xor (y) xor (z));
    end;
    
    function _I(x, y, z: UINT4): UINT4;
    begin
     Result := ((y) xor ((x) or ( not z)));
    end;
    
    function ROTATE_LEFT(x, n: UINT4): UINT4;
    begin
     Result := (((x) shl (n)) or ((x) shr (32-(n))));
    end;
    
    procedure FF(var a: UINT4; b, c, d, x, s, ac: UINT4);
    begin
      a := a + _F(b, c, d) + x + ac;
      a := ROTATE_LEFT (a, s);
      a := a + b;
    end;
    
    procedure GG(var a: UINT4; b, c, d, x, s, ac: UINT4);
    begin
     a := a + _G(b, c, d) + x + ac;
     a := ROTATE_LEFT(a, s);
     a := a + b;
    end;
    
    procedure HH(var a: UINT4; b, c, d, x, s, ac: UINT4);
    begin
     a := a + _H(b, c, d) + x + ac;
     a := ROTATE_LEFT(a, s);
     a := a + b;
    end;
    
    procedure II(var a: UINT4; b, c, d, x, s, ac: UINT4);
    begin
     a := a + _I(b, c, d) + x + ac;
     a := ROTATE_LEFT(a, s);
     a := a + b;
    end;
    
    procedure MD5Encode(Output: PByteArray; Input: PUINT4Array; Len: LongWord);
    var
     i, j: LongWord;
    begin
     j:=0;
     i:=0;
     while j < Len do  begin
      output[j] := Byte(input[i] and $ff);
      output[j+1] := Byte((input[i] shr 8) and $ff);
      output[j+2] := Byte((input[i] shr 16) and $ff);
      output[j+3] := Byte((input[i] shr 24) and $ff);
      Inc(j, 4);
      Inc(i);
     end;
    end;
    
    procedure MD5Decode(Output: PUINT4Array; Input: PByteArray; Len: LongWord);
    var
     i, j: LongWord;
    begin
     j:=0;
     i:=0;
     while j < Len do begin
      Output[i] := UINT4(input[j]) or (UINT4(input[j+1]) shl 8) or
       (UINT4(input[j+2]) shl 16) or ( UINT4(input[j+3]) shl 24);
      Inc(j, 4);
      Inc(i);
     end;
    end;
    
    procedure MD5_memcpy(Output: PByteArray; Input: PByteArray; Len: LongWord);
    begin
     Move(Input^, Output^, Len);
    end;
    
    procedure MD5_memset(Output: PByteArray; Value: Integer; Len: LongWord);
    begin
     FillChar(Output^, Len, Byte(Value));
    end;
    
    procedure MD5Transform(State: PArray4UINT4; Buffer: PArray64Byte);
    var
     a, b, c, d: UINT4;
     x : array[0..15] of UINT4;
    begin
     a:=State[0]; b:=State[1]; c:=State[2]; d:=State[3];
     MD5Decode(PUINT4Array(@x), PByteArray(Buffer), 64);
    
     FF (a, b, c, d, x[ 0], S11, $d76aa478);
     FF (d, a, b, c, x[ 1], S12, $e8c7b756);
     FF (c, d, a, b, x[ 2], S13, $242070db);
     FF (b, c, d, a, x[ 3], S14, $c1bdceee);
     FF (a, b, c, d, x[ 4], S11, $f57c0faf);
     FF (d, a, b, c, x[ 5], S12, $4787c62a);
     FF (c, d, a, b, x[ 6], S13, $a8304613);
     FF (b, c, d, a, x[ 7], S14, $fd469501);
     FF (a, b, c, d, x[ 8], S11, $698098d8);
     FF (d, a, b, c, x[ 9], S12, $8b44f7af);
     FF (c, d, a, b, x[10], S13, $ffff5bb1);
     FF (b, c, d, a, x[11], S14, $895cd7be);
     FF (a, b, c, d, x[12], S11, $6b901122);
     FF (d, a, b, c, x[13], S12, $fd987193);
     FF (c, d, a, b, x[14], S13, $a679438e);
     FF (b, c, d, a, x[15], S14, $49b40821);
    
     GG (a, b, c, d, x[ 1], S21, $f61e2562);
     GG (d, a, b, c, x[ 6], S22, $c040b340);
     GG (c, d, a, b, x[11], S23, $265e5a51);
     GG (b, c, d, a, x[ 0], S24, $e9b6c7aa);
     GG (a, b, c, d, x[ 5], S21, $d62f105d);
     GG (d, a, b, c, x[10], S22,  $2441453);
     GG (c, d, a, b, x[15], S23, $d8a1e681);
     GG (b, c, d, a, x[ 4], S24, $e7d3fbc8);
     GG (a, b, c, d, x[ 9], S21, $21e1cde6);
     GG (d, a, b, c, x[14], S22, $c33707d6);
     GG (c, d, a, b, x[ 3], S23, $f4d50d87);
    
     GG (b, c, d, a, x[ 8], S24, $455a14ed);
     GG (a, b, c, d, x[13], S21, $a9e3e905);
     GG (d, a, b, c, x[ 2], S22, $fcefa3f8);
     GG (c, d, a, b, x[ 7], S23, $676f02d9);
     GG (b, c, d, a, x[12], S24, $8d2a4c8a);
    
     HH (a, b, c, d, x[ 5], S31, $fffa3942);
     HH (d, a, b, c, x[ 8], S32, $8771f681);
     HH (c, d, a, b, x[11], S33, $6d9d6122);
     HH (b, c, d, a, x[14], S34, $fde5380c);
     HH (a, b, c, d, x[ 1], S31, $a4beea44);
     HH (d, a, b, c, x[ 4], S32, $4bdecfa9);
     HH (c, d, a, b, x[ 7], S33, $f6bb4b60);
     HH (b, c, d, a, x[10], S34, $bebfbc70);
     HH (a, b, c, d, x[13], S31, $289b7ec6);
     HH (d, a, b, c, x[ 0], S32, $eaa127fa);
     HH (c, d, a, b, x[ 3], S33, $d4ef3085);
     HH (b, c, d, a, x[ 6], S34,  $4881d05);
     HH (a, b, c, d, x[ 9], S31, $d9d4d039);
     HH (d, a, b, c, x[12], S32, $e6db99e5);
     HH (c, d, a, b, x[15], S33, $1fa27cf8);
     HH (b, c, d, a, x[ 2], S34, $c4ac5665);
    
     II (a, b, c, d, x[ 0], S41, $f4292244);
     II (d, a, b, c, x[ 7], S42, $432aff97);
     II (c, d, a, b, x[14], S43, $ab9423a7);
     II (b, c, d, a, x[ 5], S44, $fc93a039);
     II (a, b, c, d, x[12], S41, $655b59c3);
     II (d, a, b, c, x[ 3], S42, $8f0ccc92);
     II (c, d, a, b, x[10], S43, $ffeff47d);
     II (b, c, d, a, x[ 1], S44, $85845dd1);
     II (a, b, c, d, x[ 8], S41, $6fa87e4f);
     II (d, a, b, c, x[15], S42, $fe2ce6e0);
     II (c, d, a, b, x[ 6], S43, $a3014314);
     II (b, c, d, a, x[13], S44, $4e0811a1);
     II (a, b, c, d, x[ 4], S41, $f7537e82);
     II (d, a, b, c, x[11], S42, $bd3af235);
     II (c, d, a, b, x[ 2], S43, $2ad7d2bb);
     II (b, c, d, a, x[ 9], S44, $eb86d391);
    
     Inc(State[0], a);
     Inc(State[1], b);
     Inc(State[2], c);
     Inc(State[3], d);
    
     MD5_memset (PByteArray(@x), 0, SizeOf (x));
    end;
    
    
    procedure MD5Init(var Context: TMD5Context);
    begin
     FillChar(Context, SizeOf(Context), 0);
     Context.state[0] := $67452301;
     Context.state[1] := $efcdab89;
     Context.state[2] := $98badcfe;
     Context.state[3] := $10325476;
    end;
    
    procedure MD5Update(var Context: TMD5Context; Input: PByteArray; InputLen: LongWord);
    var
     i, index, partLen: LongWord;
    
    begin
     index := LongWord( (context.count[0] shr 3) and $3F);
     Inc(Context.count[0], UINT4(InputLen) shl 3);
     if Context.count[0] < UINT4(InputLen) shl 3 then Inc(Context.count[1]);
     Inc(Context.count[1], UINT4(InputLen) shr 29);
     partLen := 64 - index;
     if inputLen >= partLen then begin
      MD5_memcpy(PByteArray(@Context.buffer[index]), Input, PartLen);
      MD5Transform(@Context.state, @Context.buffer);
      i := partLen;
      while i + 63 < inputLen do begin
       MD5Transform(@Context.state, PArray64Byte(@Input[i]));
       Inc(i, 64);
      end;
      index := 0;
     end else i:=0;
     MD5_memcpy(PByteArray(@Context.buffer[index]), PByteArray(@Input[i]), inputLen - i);
    end;
    
    
    procedure MD5Final(Digest: PMD5Digest; var Context: TMD5Context);
    var
     bits: array [0..7] of Byte;
     index, padLen: LongWord;
    begin
     MD5Encode(PByteArray(@bits), PUINT4Array(@Context.count), 8);
     index := LongWord( (Context.count[0] shr 3) and $3F);
     if index < 56 then padLen := 56 - index else padLen := 120 - index;
     MD5Update(Context, PByteArray(@PADDING), padLen);
     MD5Update(Context, PByteArray(@Bits), 8);
     MD5Encode(PByteArray(Digest), PUINT4Array(@Context.state), 16);
     MD5_memset(PByteArray(@Context), 0, SizeOf(Context));
    end;
    
    function MD5DigestToStr(const Digest: TMD5Digest): string;
    var
     i: Integer;
    begin
     Result:='';
     for i:=0 to 15 do Result:=Result+IntToHex(Digest.v[i], 2);
    end;
    
    procedure MD5String(const S: string;PMD5:PMD5Digest);
    begin
     MD5Buffer(PChar(S)^, Length(S),PMD5);
    end;
    
    procedure MD5File(const FileName: string;PMD5:PMD5Digest);
    var
      F: TFileStream;
    begin
      F:=TFileStream.Create(FileName, fmOpenRead);
      try
        MD5Stream(F,PMD5);
      finally
        F.Free;
      end;
    end;
    
    procedure MD5Stream(const Stream: TStream;PMD5:PMD5Digest);
    var
     Context: TMD5Context;
     Buffer: array[0..4095] of Byte;
     Size: Integer;
     ReadBytes : Integer;
     TotalBytes : Integer;
     SavePos: Integer;
    begin
     MD5Init(Context);
     Size:=Stream.Size;
     SavePos:=Stream.Position;
     TotalBytes:=0;
     try
      Stream.Seek(0, soFromBeginning);
      repeat
       ReadBytes:=Stream.Read(Buffer, SizeOf(Buffer));
       Inc(TotalBytes, ReadBytes);
       MD5Update(Context, @Buffer, ReadBytes);
      until (ReadBytes = 0) or (TotalBytes = Size);
     finally
      Stream.Seek(SavePos, soFromBeginning);
     end;
     MD5Final(PMD5, Context);
    end;
    
    procedure MD5Buffer(const Buffer; Size: Integer;PMD5:PMD5Digest);
    var
      Context: TMD5Context;
    begin
      MD5Init(Context);
      MD5Update(Context, PByteArray(@Buffer), Size);
      MD5Final(PMD5, Context);
    end;
    
    function MD5DigestCompare(const Digest1, Digest2: TMD5Digest): Boolean;
    begin
      Result:=False;
      if Digest1.A <> Digest2.A then Exit;
      if Digest1.B <> Digest2.B then Exit;
      if Digest1.C <> Digest2.C then Exit;
      if Digest1.D <> Digest2.D then Exit;
      Result:=True;
    end;
    
    end.
    View Code

      调用方法:

    var
        md5: TMD5Digest;      //MD5Unit.pas
        passwordSource:string;
        passwordDestinate:string;
    begin
        passwordSource:='testStringForMD5';
    
        MD5String(passwordSource, @md5);
        passwordDestinate:= LowerCase(MD5DigestToStr(md5));
    
        ShowMessage(passwordDestinate);
    end;

      调用方法二:

    uses MD5Unit,IdHashMessageDigest,IdHash;
    procedure TForm1.btn1Click(Sender: TObject);
    var
      MyMD5: TIdHashMessageDigest5;//IdHashMessageDigest.pas
      Digest: T4x4LongWordRecord; //IdHash.pas
      passwordSource:string;
    
      passwordDestinate32:string;
      passwordDestinate16:string;
    begin
      passwordSource:='testStringForMD5';
      MyMD5 := TIdHashMessageDigest5.Create;
    
      Digest := MyMD5.HashValue(passwordSource);
      passwordDestinate32:=LowerCase(MyMD5.AsHex(Digest)); //32个字符长度的MD5签名结果
      passwordDestinate16:=Copy(passwordDestinate32, 9, 16);//16个字符长度的MD5签名结果
    
      ShowMessage('32: ' +passwordDestinate32+#13#10+'16: ' + passwordDestinate16);
    
      MyMD5.Free;
    end;
    
    end.

      二、DES加密算法

      DES的加密、解密封库单元

    unit StandardDES;
    interface
    
    uses
       Windows, Classes, SysUtils;
    
    type
       fdArray   = array of dword;
    
       function EncryStr(Str, Key: String): String;overload;
       function EncryStr(Str:TStream; Key: String): String;overload;
       function DecryStr(Str, Key: String): String;overload;
       function DecryStr(Str:TStream; Key: String): String;overload;
       function EncryStrHex(Str, Key: String): String;
       function DecryStrHex(Str, Key: String): String;overload;
       function DecryStrHex(Str:TStream; Key: String): String;overload;
    
       function des(key:string;smessage:string;encrypt:dword;mode:dword;iv:string):string;
       function des_createKeys(key:string):fdArray;
       function StrToHex(Str:string):string;
       function HexToStr(Hex:string):string;
       function IsInt(Str:String):Boolean;
    
    implementation
    
    function EncryStr(Str, Key: String): String;
    begin
       Result := des(Key, Str, 1, 0, '');
    end;
    
    function EncryStr(Str:TStream; Key: String): String;
    var
       AStr:String;
    begin
       Str.Seek(0,soFromBeginning);
       setlength(AStr, Str.Size);
       Str.Read(AStr[1], Str.Size);
       Result := des(Key, AStr, 1, 0, '');
    end;
    
    function DecryStr(Str, Key: String): String;
    begin
       Result := trim(des(Key, Str, 0, 0, ''));
    end;
    
    function DecryStr(Str:TStream; Key: String): String;
    var
       AStr:String;
    begin
       Str.Seek(0,soFromBeginning);
       setlength(AStr, Str.Size);
       Str.Read(AStr[1], Str.Size);
       Result := trim(des(Key, AStr, 0, 0, ''));
    end;
    
    function EncryStrHex(Str, Key: String): String;
    begin
       Result := trim(StrToHex(des(Key, Str, 1, 0, '')));
    end;
    
    function DecryStrHex(Str, Key: String): String;
    begin
       Result := trim(des(Key, HexToStr(Str), 0, 0, ''));
    end;
    
    function DecryStrHex(Str:TStream; Key: String): String;
    var
       AStr:String;
    begin
       Str.Seek(0,soFromBeginning);
       setlength(AStr, Str.Size);
       Str.Read(AStr[1], Str.Size);
       Result := trim(des(Key, HexToStr(AStr), 0, 0, ''));
    end;
    
    function des(key:string;smessage:string;encrypt:dword;mode:dword;iv:string):string;
    const
       spfunction1 : array[0..63] of dword = ($1010400,0,$10000,$1010404,$1010004,$10404,$4,$10000,$400,$1010400,$1010404,$400,$1000404,$1010004,$1000000,$4,$404,$1000400,$1000400,$10400,$10400,$1010000,$1010000,$1000404,$10004,$1000004,$1000004,$10004,0,$404,$10404,$1000000,$10000,$1010404,$4,$1010000,$1010400,$1000000,$1000000,$400,$1010004,$10000,$10400,$1000004,$400,$4,$1000404,$10404,$1010404,$10004,$1010000,$1000404,$1000004,$404,$10404,$1010400,$404,$1000400,$1000400,0,$10004,$10400,0,$1010004);
       spfunction2 : array[0..63] of dword = ($80108020,$80008000,$8000,$108020,$100000,$20,$80100020,$80008020,$80000020,$80108020,$80108000,$80000000,$80008000,$100000,$20,$80100020,$108000,$100020,$80008020,0,$80000000,$8000,$108020,$80100000,$100020,$80000020,0,$108000,$8020,$80108000,$80100000,$8020,0,$108020,$80100020,$100000,$80008020,$80100000,$80108000,$8000,$80100000,$80008000,$20,$80108020,$108020,$20,$8000,$80000000,$8020,$80108000,$100000,$80000020,$100020,$80008020,$80000020,$100020,$108000,0,$80008000,$8020,$80000000,$80100020,$80108020,$108000);
       spfunction3 : array[0..63] of dword = ($208,$8020200,0,$8020008,$8000200,0,$20208,$8000200,$20008,$8000008,$8000008,$20000,$8020208,$20008,$8020000,$208,$8000000,$8,$8020200,$200,$20200,$8020000,$8020008,$20208,$8000208,$20200,$20000,$8000208,$8,$8020208,$200,$8000000,$8020200,$8000000,$20008,$208,$20000,$8020200,$8000200,0,$200,$20008,$8020208,$8000200,$8000008,$200,0,$8020008,$8000208,$20000,$8000000,$8020208,$8,$20208,$20200,$8000008,$8020000,$8000208,$208,$8020000,$20208,$8,$8020008,$20200);
       spfunction4 : array[0..63] of dword = ($802001,$2081,$2081,$80,$802080,$800081,$800001,$2001,0,$802000,$802000,$802081,$81,0,$800080,$800001,$1,$2000,$800000,$802001,$80,$800000,$2001,$2080,$800081,$1,$2080,$800080,$2000,$802080,$802081,$81,$800080,$800001,$802000,$802081,$81,0,0,$802000,$2080,$800080,$800081,$1,$802001,$2081,$2081,$80,$802081,$81,$1,$2000,$800001,$2001,$802080,$800081,$2001,$2080,$800000,$802001,$80,$800000,$2000,$802080);
       spfunction5 : array[0..63] of dword = ($100,$2080100,$2080000,$42000100,$80000,$100,$40000000,$2080000,$40080100,$80000,$2000100,$40080100,$42000100,$42080000,$80100,$40000000,$2000000,$40080000,$40080000,0,$40000100,$42080100,$42080100,$2000100,$42080000,$40000100,0,$42000000,$2080100,$2000000,$42000000,$80100,$80000,$42000100,$100,$2000000,$40000000,$2080000,$42000100,$40080100,$2000100,$40000000,$42080000,$2080100,$40080100,$100,$2000000,$42080000,$42080100,$80100,$42000000,$42080100,$2080000,0,$40080000,$42000000,$80100,$2000100,$40000100,$80000,0,$40080000,$2080100,$40000100);
       spfunction6 : array[0..63] of dword = ($20000010,$20400000,$4000,$20404010,$20400000,$10,$20404010,$400000,$20004000,$404010,$400000,$20000010,$400010,$20004000,$20000000,$4010,0,$400010,$20004010,$4000,$404000,$20004010,$10,$20400010,$20400010,0,$404010,$20404000,$4010,$404000,$20404000,$20000000,$20004000,$10,$20400010,$404000,$20404010,$400000,$4010,$20000010,$400000,$20004000,$20000000,$4010,$20000010,$20404010,$404000,$20400000,$404010,$20404000,0,$20400010,$10,$4000,$20400000,$404010,$4000,$400010,$20004010,0,$20404000,$20000000,$400010,$20004010);
       spfunction7 : array[0..63] of dword = ($200000,$4200002,$4000802,0,$800,$4000802,$200802,$4200800,$4200802,$200000,0,$4000002,$2,$4000000,$4200002,$802,$4000800,$200802,$200002,$4000800,$4000002,$4200000,$4200800,$200002,$4200000,$800,$802,$4200802,$200800,$2,$4000000,$200800,$4000000,$200800,$200000,$4000802,$4000802,$4200002,$4200002,$2,$200002,$4000000,$4000800,$200000,$4200800,$802,$200802,$4200800,$802,$4000002,$4200802,$4200000,$200800,0,$2,$4200802,0,$200802,$4200000,$800,$4000002,$4000800,$800,$200002);
       spfunction8 : array[0..63] of dword = ($10001040,$1000,$40000,$10041040,$10000000,$10001040,$40,$10000000,$40040,$10040000,$10041040,$41000,$10041000,$41040,$1000,$40,$10040000,$10000040,$10001000,$1040,$41000,$40040,$10040040,$10041000,$1040,0,0,$10040040,$10000040,$10001000,$41040,$40000,$41040,$40000,$10041000,$1000,$40,$10040040,$1000,$41040,$10001000,$40,$10000040,$10040000,$10040040,$10000000,$40000,$10001040,0,$10041040,$40040,$10000040,$10040000,$10001000,$10001040,0,$10041040,$41000,$41000,$1040,$1040,$40040,$10000000,$10041000);
    var
       keys:fdArray;
       m, i, j:integer;
       temp, temp2, right1, right2, left, right:dword;
       looping:array of integer;
       cbcleft, cbcleft2, cbcright, cbcright2:dword;
       endloop, loopinc:integer;
       len, iterations:integer;
       chunk:integer;
       tempresult:string;
    begin
       //create the 16 or 48 subkeys we will need
       keys := des_createKeys(key);
       m:=0;cbcleft:=0;cbcleft2:=0;cbcright:=0;cbcright2:=0;chunk:=0;
       len := length(smessage);
       //set up the loops for single and triple des
       if length(keys) = 32 then
         iterations := 3
       else
         iterations := 9;
    
       if iterations = 3 then
         begin
           if encrypt = 1 then
             begin
               setlength(looping,3);
               looping[0] := 0;
               looping[1] := 32;
               looping[2] := 2;
             end
           else
             begin
               setlength(looping,3);
               looping[0] := 30;
               looping[1] := -2;
               looping[2] := -2;
             end;
         end
       else
         begin
           if encrypt = 1 then
             begin
               setlength(looping,9);
               looping[0] := 0;
               looping[1] := 32;
               looping[2] := 2;
               looping[3] := 62;
               looping[4] := 30;
               looping[5] := -2;
               looping[6] := 64;
               looping[7] := 96;
               looping[8] := 2;
             end
           else
             begin
               setlength(looping,9);
               looping[0] := 94;
               looping[1] := 62;
               looping[2] := -2;
               looping[3] := 32;
               looping[4] := 64;
               looping[5] := 2;
               looping[6] := 30;
               looping[7] := -2;
               looping[8] := -2;
             end;
         end;
    
       smessage := smessage + #0#0#0#0#0#0#0#0; //pad the message out with null bytes
    
       //store the result here
       result := '';
       tempresult := '';
    
       if mode = 1 then //CBC mode
         begin
           cbcleft := (ord(iv[m+1]) shl 24) or (ord(iv[m+2]) shl 16) or (ord(iv[m+3]) shl 8) or ord(iv[m+4]);
           cbcright := (ord(iv[m+5]) shl 24) or (ord(iv[m+6]) shl 16) or (ord(iv[m+7]) shl 8) or ord(iv[m+8]);
           m:=0;
         end;
    
       //loop through each 64 bit chunk of the message
       while m < len do
         begin
           left := (ord(smessage[m+1]) shl 24) or (ord(smessage[m+2]) shl 16) or (ord(smessage[m+3]) shl 8) or ord(smessage[m+4]);
           right := (ord(smessage[m+5]) shl 24) or (ord(smessage[m+6]) shl 16) or (ord(smessage[m+7]) shl 8) or ord(smessage[m+8]);
           m := m + 8;
    
           //for Cipher Block Chaining mode, xor the message with the previous result
           if mode = 1 then
             if encrypt=1 then
               begin
                 left := left xor cbcleft;
                 right := right xor cbcright;
               end
             else
               begin
                 cbcleft2 := cbcleft;
                 cbcright2 := cbcright;
                 cbcleft := left;
                 cbcright := right;
               end;
    
           //first each 64 but chunk of the message must be permuted according to IP
           temp := ((left shr 4) xor right) and $0f0f0f0f; right := right xor temp; left := left xor (temp shl 4);
           temp := ((left shr 16) xor right) and $0000ffff; right := right xor temp; left := left xor (temp shl 16);
           temp := ((right shr 2) xor left) and $33333333; left := left xor temp; right := right xor (temp shl 2);
           temp := ((right shr 8) xor left) and $00ff00ff; left := left xor temp; right := right xor (temp shl 8);
           temp := ((left shr 1) xor right) and $55555555; right := right xor temp; left := left xor (temp shl 1);
    
           left := ((left shl 1) or (left shr 31));
           right := ((right shl 1) or (right shr 31));
    
           //do this either 1 or 3 times for each chunk of the message
           j:=0;
           while j<iterations do
             begin
               endloop := looping[j+1];
               loopinc := looping[j+2];
               //now go through and perform the encryption or decryption
               i:= looping[j];
               while i<>endloop do
                 begin
                   right1 := right xor keys[i];
                   right2 := ((right shr 4) or (right shl 28)) xor keys[i+1];
                   //the result is attained by passing these bytes through the S selection functions
                   temp := left;
                   left := right;
                   right := temp xor (spfunction2[(right1 shr 24) and $3f] or spfunction4[(right1 shr 16) and $3f]
                            or spfunction6[(right1 shr   8) and $3f] or spfunction8[right1 and $3f]
                            or spfunction1[(right2 shr 24) and $3f] or spfunction3[(right2 shr 16) and $3f]
                            or spfunction5[(right2 shr   8) and $3f] or spfunction7[right2 and $3f]);
                   i:=i+loopinc;
                 end;
               temp := left; left := right; right := temp; //unreverse left and right
               j:=j+3;
             end; //for either 1 or 3 iterations
    
           //move then each one bit to the right
           left := ((left shr 1) or (left shl 31));
           right := ((right shr 1) or (right shl 31));
    
           //now perform IP-1, which is IP in the opposite direction
           temp := ((left shr 1) xor right) and $55555555; right := right xor temp; left :=left xor (temp shl 1);
           temp := ((right shr 8) xor left) and $00ff00ff; left := left xor temp; right := right xor (temp shl 8);
           temp := ((right shr 2) xor left) and $33333333; left := left xor temp; right := right xor (temp shl 2);
           temp := ((left shr 16) xor right) and $0000ffff; right := right xor temp; left := left xor (temp shl 16);
           temp := ((left shr 4) xor right) and $0f0f0f0f; right := right xor temp; left := left xor (temp shl 4);
    
           //for Cipher Block Chaining mode, xor the message with the previous result
           if mode = 1 then
             if encrypt=1 then
               begin
               cbcleft := left; cbcright := right;
               end
             else
               begin
                 left :=left xor cbcleft2;
                 right := right xor cbcright2;
               end;
    
           tempresult := tempresult + chr(left shr 24) + chr((left shr 16) and $ff) + chr((left shr 8) and $ff) + chr(left and $ff) + chr(right shr 24) + chr((right shr 16) and $ff) + chr((right shr 8) and $ff) + chr(right and $ff);
    
           chunk := chunk + 8;
           if chunk = 512 then
             begin
               result := result + tempresult; tempresult := ''; chunk := 0;
             end;
         end; //for every 8 characters, or 64 bits in the message
    
       //return the result as an array
       result := result + tempresult;
    end; //end of des
    
    //des_createKeys
    //this takes as input a 64 bit key (even though only 56 bits are used)
    //as an array of 2 dwords, and returns 16 48 bit keys
    function des_createKeys(key:string):fdArray;
    const
       //declaring this locally speeds things up a bit
       pc2bytes0   :array[0..15] of dword= (0,$4,$20000000,$20000004,$10000,$10004,$20010000,$20010004,$200,$204,$20000200,$20000204,$10200,$10204,$20010200,$20010204);
       pc2bytes1   :array[0..15] of dword= (0,$1,$100000,$100001,$4000000,$4000001,$4100000,$4100001,$100,$101,$100100,$100101,$4000100,$4000101,$4100100,$4100101);
       pc2bytes2   :array[0..15] of dword= (0,$8,$800,$808,$1000000,$1000008,$1000800,$1000808,0,$8,$800,$808,$1000000,$1000008,$1000800,$1000808);
       pc2bytes3   :array[0..15] of dword= (0,$200000,$8000000,$8200000,$2000,$202000,$8002000,$8202000,$20000,$220000,$8020000,$8220000,$22000,$222000,$8022000,$8222000);
       pc2bytes4   :array[0..15] of dword= (0,$40000,$10,$40010,0,$40000,$10,$40010,$1000,$41000,$1010,$41010,$1000,$41000,$1010,$41010);
       pc2bytes5   :array[0..15] of dword= (0,$400,$20,$420,0,$400,$20,$420,$2000000,$2000400,$2000020,$2000420,$2000000,$2000400,$2000020,$2000420);
       pc2bytes6   :array[0..15] of dword= (0,$10000000,$80000,$10080000,$2,$10000002,$80002,$10080002,0,$10000000,$80000,$10080000,$2,$10000002,$80002,$10080002);
       pc2bytes7   :array[0..15] of dword= (0,$10000,$800,$10800,$20000000,$20010000,$20000800,$20010800,$20000,$30000,$20800,$30800,$20020000,$20030000,$20020800,$20030800);
       pc2bytes8   :array[0..15] of dword= (0,$40000,0,$40000,$2,$40002,$2,$40002,$2000000,$2040000,$2000000,$2040000,$2000002,$2040002,$2000002,$2040002);
       pc2bytes9   :array[0..15] of dword= (0,$10000000,$8,$10000008,0,$10000000,$8,$10000008,$400,$10000400,$408,$10000408,$400,$10000400,$408,$10000408);
       pc2bytes10 :array[0..15] of dword= (0,$20,0,$20,$100000,$100020,$100000,$100020,$2000,$2020,$2000,$2020,$102000,$102020,$102000,$102020);
       pc2bytes11 :array[0..15] of dword= (0,$1000000,$200,$1000200,$200000,$1200000,$200200,$1200200,$4000000,$5000000,$4000200,$5000200,$4200000,$5200000,$4200200,$5200200);
       pc2bytes12 :array[0..15] of dword= (0,$1000,$8000000,$8001000,$80000,$81000,$8080000,$8081000,$10,$1010,$8000010,$8001010,$80010,$81010,$8080010,$8081010);
       pc2bytes13 :array[0..15] of dword= (0,$4,$100,$104,0,$4,$100,$104,$1,$5,$101,$105,$1,$5,$101,$105);
    
       //now define the left shifts which need to be done
       shifts :array[0..15] of dword = (0, 0, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, 0);
    var
       iterations:integer;
       keys:fdArray;
       lefttemp, righttemp, temp:dword;
       m, n, j,i:integer;
       left,right:dword;
    begin
       //how many iterations (1 for des, 3 for triple des)
       if length(key) = 24 then
         iterations := 3
       else
         iterations := 1;
    
       //stores the return keys
       setlength(keys,32 * iterations);
    
       //other variables
       m:=0;n:=0;
    
       for j:=0 to iterations-1 do //either 1 or 3 iterations
         begin
           left := (ord(key[m+1]) shl 24) or (ord(key[m+2]) shl 16) or (ord(key[m+3]) shl 8) or ord(key[m+4]);
           right := (ord(key[m+5]) shl 24) or (ord(key[m+6]) shl 16) or (ord(key[m+7]) shl 8) or ord(key[m+8]);
           m:=m+8;
    
           temp := ((left shr 4) xor right) and $0f0f0f0f; right :=right xor temp; left :=left xor (temp shl 4);
           temp := ((right shr 16) xor left) and $0000ffff; left := left xor temp; right :=right xor (temp shl 16);
           temp := ((left shr 2) xor right) and $33333333; right :=right xor temp; left := left xor (temp shl 2);
           temp := ((right shr 16) xor left) and $0000ffff; left :=left xor temp; right := right xor (temp shl 16);
           temp := ((left shr 1) xor right) and $55555555; right := right xor temp; left := left xor (temp shl 1);
           temp := ((right shr 8) xor left) and $00ff00ff; left :=left xor temp; right := right xor (temp shl 8);
           temp := ((left shr 1) xor right) and $55555555; right :=right xor temp; left := left xor (temp shl 1);
    
           //the right side needs to be shifted and to get the last four bits of the left side
           temp := (left shl 8) or ((right shr 20) and $000000f0);
           //left needs to be put upside down
           left := (right shl 24) or ((right shl 8) and $ff0000) or ((right shr 8) and $ff00) or ((right shr 24) and $f0);
           right := temp;
    
           //now go through and perform these shifts on the left and right keys
           for i:=low(shifts) to   high(shifts) do
             begin
               //shift the keys either one or two bits to the left
               if shifts[i] > 0 then
                 begin
                   left := (left shl 2) or (left shr 26);
                   right := (right shl 2) or (right shr 26);
                   //left := left shl 0;
                   //right:= right shl 0;
                 end
               else
                 begin
                   left := (left shl 1) or (left shr 27);
                   right := (right shl 1) or (right shr 27);
                   //left := left shl 0;
                   //right:= right shl 0;
                 end;
    
               left := left and $fffffff0;
               right:= right and $fffffff0;
    
               //now apply PC-2, in such a way that E is easier when encrypting or decrypting
               //this conversion will look like PC-2 except only the last 6 bits of each byte are used
               //rather than 48 consecutive bits and the order of lines will be according to
               //how the S selection functions will be applied: S2, S4, S6, S8, S1, S3, S5, S7
               lefttemp := pc2bytes0[left shr 28] or pc2bytes1[(left shr 24) and $f]
                           or pc2bytes2[(left shr 20) and $f] or pc2bytes3[(left shr 16) and $f]
                           or pc2bytes4[(left shr 12) and $f] or pc2bytes5[(left shr 8) and $f]
                           or pc2bytes6[(left shr 4) and $f];
               righttemp := pc2bytes7[right shr 28] or pc2bytes8[(right shr 24) and $f]
                            or pc2bytes9[(right shr 20) and $f] or pc2bytes10[(right shr 16) and $f]
                            or pc2bytes11[(right shr 12) and $f] or pc2bytes12[(right shr 8) and $f]
                            or pc2bytes13[(right shr 4) and $f];
               temp := ((righttemp shr 16) xor lefttemp) and $0000ffff;
               keys[n+0] := lefttemp xor temp;
               keys[n+1] := righttemp xor (temp shl 16);
               n:=n+2;
             end;
         end; //for each iterations
    
       //return the keys we've created
       Result := keys;
    
    end;//end of des_createKeys
    
    
    function StrToHex(Str:string):string;
    var
       i:integer;
    begin
       result := '';
       for i := 1 to length(Str) do
         result := result + IntToHex(Ord(Str[i]), 2);
    end;
    
    function HexToStr(Hex:string):string;
    var
       i:Integer;
    begin
       Result := '';
       for i := 1 to length(Hex) div 2 do
         if IsInt('$' + Hex[i * 2 - 1] + Hex[i * 2]) then
           Result := Result + Chr(StrToInt('$' + Hex[i * 2 - 1] + Hex[i * 2]));
    end;
    
    function IsInt(Str:String):Boolean;
    begin
       result := True;
       try
         StrToInt(Str);
       except
         result := False
       end;
    end;
    
    end.
    View Code

      调用方法,加密:

    var
      PlaintextStr:string;
    begin
      PlaintextStr:='加密测试!';
      PublicCiphertextStr:=EncryStrHex(PlaintextStr, '11111111');//StandardDES.pas
    
      showmessage(PublicCiphertextStr);
    end;

      调用方法,解密:

    var
      PlaintextStr:string;
    begin
      PlaintextStr:=DecryStrHex(PublicCiphertextStr, '11111111');//StandardDES.pas
      
      showmessage(PlaintextStr);
    end;

     

      转截自:http://www.cnblogs.com/edisonfeng/archive/2011/07/22/2054520.html

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  • 原文地址:https://www.cnblogs.com/cxeye/p/3525891.html
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