#include "rar.hpp" #ifndef SFX_MODULE extern uint CRCTab[256]; #endif #define NROUNDS 32 #define rol(x,n,xsize) (((x)<<(n)) | ((x)>>(xsize-(n)))) #define ror(x,n,xsize) (((x)>>(n)) | ((x)<<(xsize-(n)))) #define substLong(t) ( (uint)SubstTable[(uint)t&255] | \ ((uint)SubstTable[(int)(t>> 8)&255]<< 8) | \ ((uint)SubstTable[(int)(t>>16)&255]<<16) | \ ((uint)SubstTable[(int)(t>>24)&255]<<24) ) CryptKeyCacheItem CryptData::Cache[4]; int CryptData::CachePos=0; #ifndef SFX_MODULE static byte InitSubstTable[256]={ 215, 19,149, 35, 73,197,192,205,249, 28, 16,119, 48,221, 2, 42, 232, 1,177,233, 14, 88,219, 25,223,195,244, 90, 87,239,153,137, 255,199,147, 70, 92, 66,246, 13,216, 40, 62, 29,217,230, 86, 6, 71, 24,171,196,101,113,218,123, 93, 91,163,178,202, 67, 44,235, 107,250, 75,234, 49,167,125,211, 83,114,157,144, 32,193,143, 36, 158,124,247,187, 89,214,141, 47,121,228, 61,130,213,194,174,251, 97,110, 54,229,115, 57,152, 94,105,243,212, 55,209,245, 63, 11, 164,200, 31,156, 81,176,227, 21, 76, 99,139,188,127, 17,248, 51, 207,120,189,210, 8,226, 41, 72,183,203,135,165,166, 60, 98, 7, 122, 38,155,170, 69,172,252,238, 39,134, 59,128,236, 27,240, 80, 131, 3, 85,206,145, 79,154,142,159,220,201,133, 74, 64, 20,129, 224,185,138,103,173,182, 43, 34,254, 82,198,151,231,180, 58, 10, 118, 26,102, 12, 50,132, 22,191,136,111,162,179, 45, 4,148,108, 161, 56, 78,126,242,222, 15,175,146, 23, 33,241,181,190, 77,225, 0, 46,169,186, 68, 95,237, 65, 53,208,253,168, 9, 18,100, 52, 116,184,160, 96,109, 37, 30,106,140,104,150, 5,204,117,112, 84 }; #endif void CryptData::DecryptBlock(byte *Buf,int Size) { rin.blockDecrypt(Buf,Size,Buf); } #ifndef SFX_MODULE void CryptData::EncryptBlock20(byte *Buf) { uint A,B,C,D,T,TA,TB; #if defined(BIG_ENDIAN) || !defined(PRESENT_INT32) || !defined(ALLOW_NOT_ALIGNED_INT) A=((uint)Buf[0]|((uint)Buf[1]<<8)|((uint)Buf[2]<<16)|((uint)Buf[3]<<24))^Key[0]; B=((uint)Buf[4]|((uint)Buf[5]<<8)|((uint)Buf[6]<<16)|((uint)Buf[7]<<24))^Key[1]; C=((uint)Buf[8]|((uint)Buf[9]<<8)|((uint)Buf[10]<<16)|((uint)Buf[11]<<24))^Key[2]; D=((uint)Buf[12]|((uint)Buf[13]<<8)|((uint)Buf[14]<<16)|((uint)Buf[15]<<24))^Key[3]; #else uint32 *BufPtr=(uint32 *)Buf; A=BufPtr[0]^Key[0]; B=BufPtr[1]^Key[1]; C=BufPtr[2]^Key[2]; D=BufPtr[3]^Key[3]; #endif for(int I=0;I>8); Buf[2]=(byte)(C>>16); Buf[3]=(byte)(C>>24); D^=Key[1]; Buf[4]=(byte)D; Buf[5]=(byte)(D>>8); Buf[6]=(byte)(D>>16); Buf[7]=(byte)(D>>24); A^=Key[2]; Buf[8]=(byte)A; Buf[9]=(byte)(A>>8); Buf[10]=(byte)(A>>16); Buf[11]=(byte)(A>>24); B^=Key[3]; Buf[12]=(byte)B; Buf[13]=(byte)(B>>8); Buf[14]=(byte)(B>>16); Buf[15]=(byte)(B>>24); #else BufPtr[0]=C^Key[0]; BufPtr[1]=D^Key[1]; BufPtr[2]=A^Key[2]; BufPtr[3]=B^Key[3]; #endif UpdKeys(Buf); } void CryptData::DecryptBlock20(byte *Buf) { byte InBuf[16]; uint A,B,C,D,T,TA,TB; #if defined(BIG_ENDIAN) || !defined(PRESENT_INT32) || !defined(ALLOW_NOT_ALIGNED_INT) A=((uint)Buf[0]|((uint)Buf[1]<<8)|((uint)Buf[2]<<16)|((uint)Buf[3]<<24))^Key[0]; B=((uint)Buf[4]|((uint)Buf[5]<<8)|((uint)Buf[6]<<16)|((uint)Buf[7]<<24))^Key[1]; C=((uint)Buf[8]|((uint)Buf[9]<<8)|((uint)Buf[10]<<16)|((uint)Buf[11]<<24))^Key[2]; D=((uint)Buf[12]|((uint)Buf[13]<<8)|((uint)Buf[14]<<16)|((uint)Buf[15]<<24))^Key[3]; #else uint32 *BufPtr=(uint32 *)Buf; A=BufPtr[0]^Key[0]; B=BufPtr[1]^Key[1]; C=BufPtr[2]^Key[2]; D=BufPtr[3]^Key[3]; #endif memcpy(InBuf,Buf,sizeof(InBuf)); for(int I=NROUNDS-1;I>=0;I--) { T=((C+rol(D,11,32))^Key[I&3]); TA=A^substLong(T); T=((D^rol(C,17,32))+Key[I&3]); TB=B^substLong(T); A=C; B=D; C=TA; D=TB; } #if defined(BIG_ENDIAN) || !defined(PRESENT_INT32) || !defined(ALLOW_NOT_ALIGNED_INT) C^=Key[0]; Buf[0]=(byte)C; Buf[1]=(byte)(C>>8); Buf[2]=(byte)(C>>16); Buf[3]=(byte)(C>>24); D^=Key[1]; Buf[4]=(byte)D; Buf[5]=(byte)(D>>8); Buf[6]=(byte)(D>>16); Buf[7]=(byte)(D>>24); A^=Key[2]; Buf[8]=(byte)A; Buf[9]=(byte)(A>>8); Buf[10]=(byte)(A>>16); Buf[11]=(byte)(A>>24); B^=Key[3]; Buf[12]=(byte)B; Buf[13]=(byte)(B>>8); Buf[14]=(byte)(B>>16); Buf[15]=(byte)(B>>24); #else BufPtr[0]=C^Key[0]; BufPtr[1]=D^Key[1]; BufPtr[2]=A^Key[2]; BufPtr[3]=B^Key[3]; #endif UpdKeys(InBuf); } void CryptData::UpdKeys(byte *Buf) { for (int I=0;I<16;I+=4) { Key[0]^=CRCTab[Buf[I]]; Key[1]^=CRCTab[Buf[I+1]]; Key[2]^=CRCTab[Buf[I+2]]; Key[3]^=CRCTab[Buf[I+3]]; } } void CryptData::Swap(byte *Ch1,byte *Ch2) { byte Ch=*Ch1; *Ch1=*Ch2; *Ch2=Ch; } #endif void CryptData::SetCryptKeys(char *Password,byte *Salt,bool Encrypt,bool OldOnly) { if (*Password==0) return; if (OldOnly) { #ifndef SFX_MODULE if (CRCTab[1]==0) InitCRC(); byte Psw[MAXPASSWORD]; SetOldKeys(Password); Key[0]=0xD3A3B879L; Key[1]=0x3F6D12F7L; Key[2]=0x7515A235L; Key[3]=0xA4E7F123L; memset(Psw,0,sizeof(Psw)); #if defined(_WIN_32) && !defined(GUI) && !defined(TARGET_POSIX) CharToOemBuff(Password,(char*)Psw,strlen(Password)); #else strncpy((char *)Psw,Password,MAXPASSWORD-1); #endif int PswLength=strlen(Password); memcpy(SubstTable,InitSubstTable,sizeof(SubstTable)); for (int J=0;J<256;J++) for (int I=0;I>8); PswNum[2]=(byte)(I>>16); hash_process( &c, PswNum, 3); if (I%(HashRounds/16)==0) { hash_context tempc=c; uint32 digest[5]; hash_final( &tempc, digest); AESInit[I/(HashRounds/16)]=(byte)digest[4]; } } uint32 digest[5]; hash_final( &c, digest); for (int I=0;I<4;I++) for (int J=0;J<4;J++) AESKey[I*4+J]=(byte)(digest[I]>>(J*8)); strcpy(Cache[CachePos].Password,Password); if ((Cache[CachePos].SaltPresent=(Salt!=NULL))==true) memcpy(Cache[CachePos].Salt,Salt,SALT_SIZE); memcpy(Cache[CachePos].AESKey,AESKey,sizeof(AESKey)); memcpy(Cache[CachePos].AESInit,AESInit,sizeof(AESInit)); CachePos=(CachePos+1)%(sizeof(Cache)/sizeof(Cache[0])); } rin.init(Encrypt ? Rijndael::Encrypt : Rijndael::Decrypt,AESKey,AESInit); } #ifndef SFX_MODULE void CryptData::SetOldKeys(char *Password) { uint PswCRC=CRC(0xffffffff,Password,strlen(Password)); OldKey[0]=PswCRC&0xffff; OldKey[1]=(PswCRC>>16)&0xffff; OldKey[2]=OldKey[3]=0; PN1=PN2=PN3=0; byte Ch; while ((Ch=*Password)!=0) { PN1+=Ch; PN2^=Ch; PN3+=Ch; PN3=(byte)rol(PN3,1,8); OldKey[2]^=Ch^CRCTab[Ch]; OldKey[3]+=Ch+(CRCTab[Ch]>>16); Password++; } } void CryptData::SetAV15Encryption() { OldKey[0]=0x4765; OldKey[1]=0x9021; OldKey[2]=0x7382; OldKey[3]=0x5215; } void CryptData::SetCmt13Encryption() { PN1=0; PN2=7; PN3=77; } void CryptData::Crypt(byte *Data,uint Count,int Method) { if (Method==OLD_DECODE) Decode13(Data,Count); else if (Method==OLD_ENCODE) Encode13(Data,Count); else Crypt15(Data,Count); } void CryptData::Encode13(byte *Data,uint Count) { while (Count--) { PN2+=PN3; PN1+=PN2; *Data+=PN1; Data++; } } void CryptData::Decode13(byte *Data,uint Count) { while (Count--) { PN2+=PN3; PN1+=PN2; *Data-=PN1; Data++; } } void CryptData::Crypt15(byte *Data,uint Count) { while (Count--) { OldKey[0]+=0x1234; OldKey[1]^=CRCTab[(OldKey[0] & 0x1fe)>>1]; OldKey[2]-=CRCTab[(OldKey[0] & 0x1fe)>>1]>>16; OldKey[0]^=OldKey[2]; OldKey[3]=ror(OldKey[3]&0xffff,1,16)^OldKey[1]; OldKey[3]=ror(OldKey[3]&0xffff,1,16); OldKey[0]^=OldKey[3]; *Data^=(byte)(OldKey[0]>>8); Data++; } } #endif