restemplate/indy/Protocols/IdHashMessageDigest.pas

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{
$Project$
$Workfile$
$Revision$
$DateUTC$
$Id$
This file is part of the Indy (Internet Direct) project, and is offered
under the dual-licensing agreement described on the Indy website.
(http://www.indyproject.org/)
Copyright:
(c) 1993-2005, Chad Z. Hower and the Indy Pit Crew. All rights reserved.
}
{
$Log$
}
{
Rev 1.3 24/01/2004 19:21:36 CCostelloe
Cleaned up warnings
Rev 1.2 1/15/2004 2:32:50 AM JPMugaas
Attempt to add MD5 coder support for partial streams. THis is needed for the
XMD5 command in the FTP Server.
Rev 1.1 2003-10-12 22:36:40 HHellstr<74>m
Reimplemented, optimized and tested for both Win32 and dotNET.
Rev 1.0 11/13/2002 07:53:40 AM JPMugaas
}
{
Implementation of the MD2, MD4 and MD5 Message-Digest Algorithm
as specified in RFC 1319 (1115), 1320 (1186), 1321
Author: Henrick Hellstr<74>m <henrick@streamsec.se>
Original Intellectual Property Statement:
Author: Pete Mee
Port to Indy 8.1 Doychin Bondzhev (doychin@dsoft-bg.com)
Copyright: (c) Chad Z. Hower and The Winshoes Working Group.
}
unit IdHashMessageDigest;
interface
{$i IdCompilerDefines.inc}
uses
IdFIPS, IdGlobal, IdHash, Classes;
type
T4x4LongWordRecord = array[0..3] of UInt32;
T16x4LongWordRecord = array[0..15] of UInt32;
T4x4x4LongWordRecord = array[0..3] of T4x4LongWordRecord;
T512BitRecord = array[0..63] of Byte;
T384BitRecord = array[0..47] of Byte;
T128BitRecord = array[0..15] of Byte;
TIdHashMessageDigest = class(TIdHashNativeAndIntF)
protected
FCBuffer: TIdBytes;
procedure MDCoder; virtual; abstract;
procedure Reset; virtual;
end;
TIdHashMessageDigest2 = class(TIdHashMessageDigest)
protected
FX: T384BitRecord;
FCheckSum: T128BitRecord;
procedure MDCoder; override;
procedure Reset; override;
function InitHash : TIdHashIntCtx; override;
function NativeGetHashBytes(AStream: TStream; ASize: TIdStreamSize): TIdBytes; override;
function HashToHex(const AHash: TIdBytes): String; override;
public
constructor Create; override;
class function IsIntfAvailable: Boolean; override;
end;
TIdHashMessageDigest4 = class(TIdHashMessageDigest)
protected
FState: T4x4LongWordRecord;
function NativeGetHashBytes(AStream: TStream; ASize: TIdStreamSize): TIdBytes; override;
function HashToHex(const AHash: TIdBytes): String; override;
procedure MDCoder; override;
function InitHash : TIdHashIntCtx; override;
public
constructor Create; override;
class function IsIntfAvailable: Boolean; override;
end;
TIdHashMessageDigest5 = class(TIdHashMessageDigest4)
protected
procedure MDCoder; override;
function InitHash : TIdHashIntCtx; override;
public
class function IsIntfAvailable : Boolean; override;
end;
implementation
uses
{$IFDEF DOTNET}
System.Security.Cryptography,
IdStreamNET,
{$ELSE}
IdStreamVCL,
{$ENDIF}
IdGlobalProtocols;
{ TIdHashMessageDigest }
procedure TIdHashMessageDigest.Reset;
begin
FillBytes(FCBuffer, Length(FCBuffer), 0);
end;
{ TIdHashMessageDigest2 }
const
MD2_PI_SUBST : array [0..255] of Byte = (
41, 46, 67, 201, 162, 216, 124, 1, 61, 54, 84, 161, 236, 240,
6, 19, 98, 167, 5, 243, 192, 199, 115, 140, 152, 147, 43, 217,
188, 76, 130, 202, 30, 155, 87, 60, 253, 212, 224, 22, 103, 66,
111, 24, 138, 23, 229, 18, 190, 78, 196, 214, 218, 158, 222, 73,
160, 251, 245, 142, 187, 47, 238, 122, 169, 104, 121, 145, 21, 178,
7, 63, 148, 194, 16, 137, 11, 34, 95, 33, 128, 127, 93, 154,
90, 144, 50, 39, 53, 62, 204, 231, 191, 247, 151, 3, 255, 25,
48, 179, 72, 165, 181, 209, 215, 94, 146, 42, 172, 86, 170, 198,
79, 184, 56, 210, 150, 164, 125, 182, 118, 252, 107, 226, 156, 116,
4, 241, 69, 157, 112, 89, 100, 113, 135, 32, 134, 91, 207, 101,
230, 45, 168, 2, 27, 96, 37, 173, 174, 176, 185, 246, 28, 70,
97, 105, 52, 64, 126, 15, 85, 71, 163, 35, 221, 81, 175, 58,
195, 92, 249, 206, 186, 197, 234, 38, 44, 83, 13, 110, 133, 40,
132, 9, 211, 223, 205, 244, 65, 129, 77, 82, 106, 220, 55, 200,
108, 193, 171, 250, 36, 225, 123, 8, 12, 189, 177, 74, 120, 136,
149, 139, 227, 99, 232, 109, 233, 203, 213, 254, 59, 0, 29, 57,
242, 239, 183, 14, 102, 88, 208, 228, 166, 119, 114, 248, 235, 117,
75, 10, 49, 68, 80, 180, 143, 237, 31, 26, 219, 153, 141, 51,
159, 17, 131, 20);
constructor TIdHashMessageDigest2.Create;
begin
inherited Create;
SetLength(FCBuffer, 16);
end;
procedure TIdHashMessageDigest2.MDCoder;
const
NumRounds = 18;
var
x: Byte;
i, j: Integer;
T: UInt16;
LCheckSumScore: Byte;
begin
// Move the next 16 bytes into the second 16 bytes of X.
for i := 0 to 15 do begin
x := FCBuffer[i];
FX[i + 16] := x;
FX[i + 32] := x xor FX[i];
end;
{ Do 18 rounds. }
T := 0;
for i := 0 to NumRounds - 1 do begin
for j := 0 to 47 do
begin
T := FX[j] xor MD2_PI_SUBST[T];
FX[j] := T and $FF;
end;
T := (T + i) and $FF;
end;
LCheckSumScore := FChecksum[15];
for i := 0 to 15 do begin
x := FCBuffer[i] xor LCheckSumScore;
LCheckSumScore := FChecksum[i] xor MD2_PI_SUBST[x];
FChecksum[i] := LCheckSumScore;
end;
end;
// Clear Buffer and Checksum arrays
procedure TIdHashMessageDigest2.Reset;
var
I: Integer;
begin
inherited Reset;
for I := 0 to 15 do begin
FCheckSum[I] := 0;
FX[I] := 0;
FX[I+16] := 0;
FX[I+32] := 0;
end;
end;
function TIdHashMessageDigest2.NativeGetHashBytes(AStream: TStream; ASize: TIdStreamSize): TIdBytes;
var
LStartPos: Integer;
LSize: Integer;
Pad: Byte;
I: Integer;
begin
Result := nil;
Reset;
// Code the entire file in complete 16-byte chunks.
while ASize >= 16 do begin
LSize := ReadTIdBytesFromStream(AStream, FCBuffer, 16);
// TODO: handle stream read error
MDCoder;
Dec(ASize, LSize);
end;
// Read the last set of bytes.
LStartPos := ReadTIdBytesFromStream(AStream, FCBuffer, ASize);
// TODO: handle stream read error
Pad := 16 - LStartPos;
// Step 1
for I := LStartPos to 15 do begin
FCBuffer[I] := Pad;
end;
MDCoder;
// Step 2
for I := 0 to 15 do begin
FCBuffer[I] := FCheckSum[I];
end;
MDCoder;
SetLength(Result, SizeOf(UInt32)*4);
for I := 0 to 3 do
begin
CopyTIdUInt32(
FX[I*4] + (FX[I*4+1] shl 8) + (FX[I*4+2] shl 16) + (FX[I*4+3] shl 24),
Result, SizeOf(UInt32)*I);
end;
end;
function TIdHashMessageDigest2.HashToHex(const AHash: TIdBytes): String;
begin
Result := LongWordHashToHex(AHash, 4);
end;
function TIdHashMessageDigest2.InitHash: TIdHashIntCtx;
begin
Result := GetMD2HashInst;
end;
class function TIdHashMessageDigest2.IsIntfAvailable: Boolean;
begin
Result := IsHashingIntfAvail and IsMD2HashIntfAvail;
end;
{ TIdHashMessageDigest4 }
const
MD4_INIT_VALUES: T4x4LongWordRecord = (
$67452301, $EFCDAB89, $98BADCFE, $10325476);
{$Q-} // Arithmetic operations performed modulo $100000000
constructor TIdHashMessageDigest4.Create;
begin
inherited Create;
SetLength(FCBuffer, 64);
end;
procedure TIdHashMessageDigest4.MDCoder;
var
A, B, C, D, i : UInt32;
buff : T16x4LongWordRecord; // 64-byte buffer
begin
A := FState[0];
B := FState[1];
C := FState[2];
D := FState[3];
for i := 0 to 15 do
begin
buff[i] := FCBuffer[i*4+0] +
(FCBuffer[i*4+1] shl 8) +
(FCBuffer[i*4+2] shl 16) +
(FCBuffer[i*4+3] shl 24);
end;
// Round 1
{ Note:
(x and y) or ( (not x) and z)
is equivalent to
(((z xor y) and x) xor z)
-HHellstr<74>m }
for i := 0 to 3 do
begin
A := ROL((((D xor C) and B) xor D) + A + buff[i*4+0], 3);
D := ROL((((C xor B) and A) xor C) + D + buff[i*4+1], 7);
C := ROL((((B xor A) and D) xor B) + C + buff[i*4+2], 11);
B := ROL((((A xor D) and C) xor A) + B + buff[i*4+3], 19);
end;
// Round 2
{ Note:
(x and y) or (x and z) or (y and z)
is equivalent to
((x and y) or (z and (x or y)))
-HHellstr<74>m }
for i := 0 to 3 do
begin
A := ROL(((B and C) or (D and (B or C))) + A + buff[0*4+i] + $5A827999, 3);
D := ROL(((A and B) or (C and (A or B))) + D + buff[1*4+i] + $5A827999, 5);
C := ROL(((D and A) or (B and (D or A))) + C + buff[2*4+i] + $5A827999, 9);
B := ROL(((C and D) or (A and (C or D))) + B + buff[3*4+i] + $5A827999, 13);
end;
// Round 3
A := ROL((B xor C xor D) + A + buff[ 0] + $6ED9EBA1, 3);
D := ROL((A xor B xor C) + D + buff[ 8] + $6ED9EBA1, 9);
C := ROL((D xor A xor B) + C + buff[ 4] + $6ED9EBA1, 11);
B := ROL((C xor D xor A) + B + buff[12] + $6ED9EBA1, 15);
A := ROL((B xor C xor D) + A + buff[ 2] + $6ED9EBA1, 3);
D := ROL((A xor B xor C) + D + buff[10] + $6ED9EBA1, 9);
C := ROL((D xor A xor B) + C + buff[ 6] + $6ED9EBA1, 11);
B := ROL((C xor D xor A) + B + buff[14] + $6ED9EBA1, 15);
A := ROL((B xor C xor D) + A + buff[ 1] + $6ED9EBA1, 3);
D := ROL((A xor B xor C) + D + buff[ 9] + $6ED9EBA1, 9);
C := ROL((D xor A xor B) + C + buff[ 5] + $6ED9EBA1, 11);
B := ROL((C xor D xor A) + B + buff[13] + $6ED9EBA1, 15);
A := ROL((B xor C xor D) + A + buff[ 3] + $6ED9EBA1, 3);
D := ROL((A xor B xor C) + D + buff[11] + $6ED9EBA1, 9);
C := ROL((D xor A xor B) + C + buff[ 7] + $6ED9EBA1, 11);
B := ROL((C xor D xor A) + B + buff[15] + $6ED9EBA1, 15);
Inc(FState[0], A);
Inc(FState[1], B);
Inc(FState[2], C);
Inc(FState[3], D);
end;
{$Q+}
function TIdHashMessageDigest4.NativeGetHashBytes(AStream: TStream; ASize: TIdStreamSize): TidBytes;
var
LStartPos: Integer;
LSize: TIdStreamSize;
LBitSize: Int64;
I, LReadSize: Integer;
begin
Result := nil;
LSize := ASize;
// A straight assignment would be by ref on dotNET.
for I := 0 to 3 do begin
FState[I] := MD4_INIT_VALUES[I];
end;
while LSize >= 64 do
begin
LReadSize := ReadTIdBytesFromStream(AStream, FCBuffer, 64);
// TODO: handle stream read error
MDCoder;
Dec(LSize, LReadSize);
end;
// Read the last set of bytes.
LStartPos := ReadTIdBytesFromStream(AStream, FCBuffer, LSize);
// TODO: handle stream read error
// Append one bit with value 1
FCBuffer[LStartPos] := $80;
Inc(LStartPos);
// Must have sufficient space to insert the 64-bit size value
if LStartPos > 56 then
begin
for I := LStartPos to 63 do begin
FCBuffer[I] := 0;
end;
MDCoder;
LStartPos := 0;
end;
// Pad with zeroes. Leave room for the 64 bit size value.
for I := LStartPos to 55 do begin
FCBuffer[I] := 0;
end;
// Append the Number of bits processed.
LBitSize := ASize * 8;
for I := 56 to 63 do
begin
FCBuffer[I] := LBitSize and $FF;
LBitSize := LBitSize shr 8;
end;
MDCoder;
SetLength(Result, SizeOf(UInt32)*4);
for I := 0 to 3 do begin
CopyTIdUInt32(FState[I], Result, SizeOf(UInt32)*I);
end;
end;
function TIdHashMessageDigest4.InitHash : TIdHashIntCtx;
begin
Result := GetMD4HashInst;
end;
function TIdHashMessageDigest4.HashToHex(const AHash: TIdBytes): String;
begin
Result := LongWordHashToHex(AHash, 4);
end;
class function TIdHashMessageDigest4.IsIntfAvailable: Boolean;
begin
Result := IsHashingIntfAvail and IsMD4HashIntfAvail ;
end;
{ TIdHashMessageDigest5 }
const
MD5_SINE : array[1..64] of UInt32 = (
{ Round 1. }
$d76aa478, $e8c7b756, $242070db, $c1bdceee, $f57c0faf, $4787c62a,
$a8304613, $fd469501, $698098d8, $8b44f7af, $ffff5bb1, $895cd7be,
$6b901122, $fd987193, $a679438e, $49b40821,
{ Round 2. }
$f61e2562, $c040b340, $265e5a51, $e9b6c7aa, $d62f105d, $02441453,
$d8a1e681, $e7d3fbc8, $21e1cde6, $c33707d6, $f4d50d87, $455a14ed,
$a9e3e905, $fcefa3f8, $676f02d9, $8d2a4c8a,
{ Round 3. }
$fffa3942, $8771f681, $6d9d6122, $fde5380c, $a4beea44, $4bdecfa9,
$f6bb4b60, $bebfbc70, $289b7ec6, $eaa127fa, $d4ef3085, $04881d05,
$d9d4d039, $e6db99e5, $1fa27cf8, $c4ac5665,
{ Round 4. }
$f4292244, $432aff97, $ab9423a7, $fc93a039, $655b59c3, $8f0ccc92,
$ffeff47d, $85845dd1, $6fa87e4f, $fe2ce6e0, $a3014314, $4e0811a1,
$f7537e82, $bd3af235, $2ad7d2bb, $eb86d391
);
{$Q-} // Arithmetic operations performed modulo $100000000
function TIdHashMessageDigest5.InitHash: TIdHashIntCtx;
begin
Result := GetMD5HashInst;
end;
class function TIdHashMessageDigest5.IsIntfAvailable: Boolean;
begin
Result := IsHashingIntfAvail and IsMD5HashIntfAvail ;
end;
procedure TIdHashMessageDigest5.MDCoder;
var
A, B, C, D : UInt32;
i: Integer;
x : T16x4LongWordRecord; // 64-byte buffer
begin
A := FState[0];
B := FState[1];
C := FState[2];
D := FState[3];
for i := 0 to 15 do
begin
x[i] := FCBuffer[i*4+0] +
(FCBuffer[i*4+1] shl 8) +
(FCBuffer[i*4+2] shl 16) +
(FCBuffer[i*4+3] shl 24);
end;
{ Round 1 }
{ Note:
(x and y) or ( (not x) and z)
is equivalent to
(((z xor y) and x) xor z)
-HHellstr<74>m }
A := ROL(A + (((D xor C) and B) xor D) + x[ 0] + MD5_SINE[ 1], 7) + B;
D := ROL(D + (((C xor B) and A) xor C) + x[ 1] + MD5_SINE[ 2], 12) + A;
C := ROL(C + (((B xor A) and D) xor B) + x[ 2] + MD5_SINE[ 3], 17) + D;
B := ROL(B + (((A xor D) and C) xor A) + x[ 3] + MD5_SINE[ 4], 22) + C;
A := ROL(A + (((D xor C) and B) xor D) + x[ 4] + MD5_SINE[ 5], 7) + B;
D := ROL(D + (((C xor B) and A) xor C) + x[ 5] + MD5_SINE[ 6], 12) + A;
C := ROL(C + (((B xor A) and D) xor B) + x[ 6] + MD5_SINE[ 7], 17) + D;
B := ROL(B + (((A xor D) and C) xor A) + x[ 7] + MD5_SINE[ 8], 22) + C;
A := ROL(A + (((D xor C) and B) xor D) + x[ 8] + MD5_SINE[ 9], 7) + B;
D := ROL(D + (((C xor B) and A) xor C) + x[ 9] + MD5_SINE[10], 12) + A;
C := ROL(C + (((B xor A) and D) xor B) + x[10] + MD5_SINE[11], 17) + D;
B := ROL(B + (((A xor D) and C) xor A) + x[11] + MD5_SINE[12], 22) + C;
A := ROL(A + (((D xor C) and B) xor D) + x[12] + MD5_SINE[13], 7) + B;
D := ROL(D + (((C xor B) and A) xor C) + x[13] + MD5_SINE[14], 12) + A;
C := ROL(C + (((B xor A) and D) xor B) + x[14] + MD5_SINE[15], 17) + D;
B := ROL(B + (((A xor D) and C) xor A) + x[15] + MD5_SINE[16], 22) + C;
{ Round 2 }
{ Note:
(x and z) or (y and (not z) )
is equivalent to
(((y xor x) and z) xor y)
-HHellstr<74>m }
A := ROL(A + (C xor (D and (B xor C))) + x[ 1] + MD5_SINE[17], 5) + B;
D := ROL(D + (B xor (C and (A xor B))) + x[ 6] + MD5_SINE[18], 9) + A;
C := ROL(C + (A xor (B and (D xor A))) + x[11] + MD5_SINE[19], 14) + D;
B := ROL(B + (D xor (A and (C xor D))) + x[ 0] + MD5_SINE[20], 20) + C;
A := ROL(A + (C xor (D and (B xor C))) + x[ 5] + MD5_SINE[21], 5) + B;
D := ROL(D + (B xor (C and (A xor B))) + x[10] + MD5_SINE[22], 9) + A;
C := ROL(C + (A xor (B and (D xor A))) + x[15] + MD5_SINE[23], 14) + D;
B := ROL(B + (D xor (A and (C xor D))) + x[ 4] + MD5_SINE[24], 20) + C;
A := ROL(A + (C xor (D and (B xor C))) + x[ 9] + MD5_SINE[25], 5) + B;
D := ROL(D + (B xor (C and (A xor B))) + x[14] + MD5_SINE[26], 9) + A;
C := ROL(C + (A xor (B and (D xor A))) + x[ 3] + MD5_SINE[27], 14) + D;
B := ROL(B + (D xor (A and (C xor D))) + x[ 8] + MD5_SINE[28], 20) + C;
A := ROL(A + (C xor (D and (B xor C))) + x[13] + MD5_SINE[29], 5) + B;
D := ROL(D + (B xor (C and (A xor B))) + x[ 2] + MD5_SINE[30], 9) + A;
C := ROL(C + (A xor (B and (D xor A))) + x[ 7] + MD5_SINE[31], 14) + D;
B := ROL(B + (D xor (A and (C xor D))) + x[12] + MD5_SINE[32], 20) + C;
{ Round 3. }
A := ROL(A + (B xor C xor D) + x[ 5] + MD5_SINE[33], 4) + B;
D := ROL(D + (A xor B xor C) + x[ 8] + MD5_SINE[34], 11) + A;
C := ROL(C + (D xor A xor B) + x[11] + MD5_SINE[35], 16) + D;
B := ROL(B + (C xor D xor A) + x[14] + MD5_SINE[36], 23) + C;
A := ROL(A + (B xor C xor D) + x[ 1] + MD5_SINE[37], 4) + B;
D := ROL(D + (A xor B xor C) + x[ 4] + MD5_SINE[38], 11) + A;
C := ROL(C + (D xor A xor B) + x[ 7] + MD5_SINE[39], 16) + D;
B := ROL(B + (C xor D xor A) + x[10] + MD5_SINE[40], 23) + C;
A := ROL(A + (B xor C xor D) + x[13] + MD5_SINE[41], 4) + B;
D := ROL(D + (A xor B xor C) + x[ 0] + MD5_SINE[42], 11) + A;
C := ROL(C + (D xor A xor B) + x[ 3] + MD5_SINE[43], 16) + D;
B := ROL(B + (C xor D xor A) + x[ 6] + MD5_SINE[44], 23) + C;
A := ROL(A + (B xor C xor D) + x[ 9] + MD5_SINE[45], 4) + B;
D := ROL(D + (A xor B xor C) + x[12] + MD5_SINE[46], 11) + A;
C := ROL(C + (D xor A xor B) + x[15] + MD5_SINE[47], 16) + D;
B := ROL(B + (C xor D xor A) + x[ 2] + MD5_SINE[48], 23) + C;
{ Round 4. }
A := ROL(A + ((B or not D) xor C) + x[ 0] + MD5_SINE[49], 6) + B;
D := ROL(D + ((A or not C) xor B) + x[ 7] + MD5_SINE[50], 10) + A;
C := ROL(C + ((D or not B) xor A) + x[14] + MD5_SINE[51], 15) + D;
B := ROL(B + ((C or not A) xor D) + x[ 5] + MD5_SINE[52], 21) + C;
A := ROL(A + ((B or not D) xor C) + x[12] + MD5_SINE[53], 6) + B;
D := ROL(D + ((A or not C) xor B) + x[ 3] + MD5_SINE[54], 10) + A;
C := ROL(C + ((D or not B) xor A) + x[10] + MD5_SINE[55], 15) + D;
B := ROL(B + ((C or not A) xor D) + x[ 1] + MD5_SINE[56], 21) + C;
A := ROL(A + ((B or not D) xor C) + x[ 8] + MD5_SINE[57], 6) + B;
D := ROL(D + ((A or not C) xor B) + x[15] + MD5_SINE[58], 10) + A;
C := ROL(C + ((D or not B) xor A) + x[ 6] + MD5_SINE[59], 15) + D;
B := ROL(B + ((C or not A) xor D) + x[13] + MD5_SINE[60], 21) + C;
A := ROL(A + ((B or not D) xor C) + x[ 4] + MD5_SINE[61], 6) + B;
D := ROL(D + ((A or not C) xor B) + x[11] + MD5_SINE[62], 10) + A;
C := ROL(C + ((D or not B) xor A) + x[ 2] + MD5_SINE[63], 15) + D;
B := ROL(B + ((C or not A) xor D) + x[ 9] + MD5_SINE[64], 21) + C;
Inc(FState[0], A);
Inc(FState[1], B);
Inc(FState[2], C);
Inc(FState[3], D);
end;
{$Q+}
end.