SA-MP/arctool2/ArchiveBuilder.cpp

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2024-05-23 23:22:12 +08:00
#include "ArchiveBuilder.h"
#include "../saco/archive/CryptoContext.h"
#include "../saco/archive/KeyPair.h"
#include "../saco/archive/Signer.h"
#include "../saco/archive/Hasher.h"
#include "../saco/archive/TinyEncrypt.h"
#include "../saco/archive/Obfuscator.h"
#include <time.h>
#define DO_ENCRYPT
//------------------------------------
DWORD CArchiveBuilder::ms_dwHashInit = OBFUSCATE_DATA(0x9E3779B9);
//------------------------------------
CArchiveBuilder::CArchiveBuilder(void)
{
m_dwNumEntries = SAA_MAX_ENTRIES;
m_dwFDSize = SAA_MAX_FAKEDATA;
m_bProperHeader = TRUE;
}
//------------------------------------
CArchiveBuilder::CArchiveBuilder(DWORD dwNumEntries, DWORD dwFDSize, BOOL bProperHeader)
{
m_dwNumEntries = dwNumEntries;
m_dwFDSize = dwFDSize;
m_bProperHeader = bProperHeader;
}
//------------------------------------
CArchiveBuilder::~CArchiveBuilder(void)
{
if (!m_vecEntries.empty()) {
EntryMemStateVector_t::iterator it = m_vecEntries.begin();
while(it != m_vecEntries.end()) {
AB_ENTRY_MEMSTATE* pEntry = (*it);
fclose(pEntry->fiFile);
delete pEntry;
it++;
}
}
}
//------------------------------------
DWORD CArchiveBuilder::HashString(PCHAR szString)
{
// This is an implementation of the Jenkins hash
# define mix(a,b,c) \
{ \
a -= b; a -= c; a ^= (c>>13); \
b -= c; b -= a; b ^= (a<<8); \
c -= a; c -= b; c ^= (b>>13); \
a -= b; a -= c; a ^= (c>>12); \
b -= c; b -= a; b ^= (a<<16); \
c -= a; c -= b; c ^= (b>>5); \
a -= b; a -= c; a ^= (c>>3); \
b -= c; b -= a; b ^= (a<<10); \
c -= a; c -= b; c ^= (b>>15); \
}
register BYTE* k = (BYTE*)szString;
register DWORD initval = 0x12345678;
register DWORD length;
length = (DWORD)strlen(szString);
register DWORD a,b,c,len;
/* Set up the internal state */
len = length;
a = b = UNOBFUSCATE_DATA(ms_dwHashInit); /* the golden ratio; an arbitrary value */
c = initval; /* the previous hash value */
/*---------------------------------------- handle most of the key */
while (len >= 12)
{
a += (k[0] +((DWORD)k[1]<<8) +((DWORD)k[2]<<16) +((DWORD)k[3]<<24));
b += (k[4] +((DWORD)k[5]<<8) +((DWORD)k[6]<<16) +((DWORD)k[7]<<24));
c += (k[8] +((DWORD)k[9]<<8) +((DWORD)k[10]<<16)+((DWORD)k[11]<<24));
mix(a,b,c);
k += 12; len -= 12;
}
/*------------------------------------- handle the last 11 bytes */
c += length;
switch(len) /* all the case statements fall through */
{
case 11: c+=((DWORD)k[10]<<24);
case 10: c+=((DWORD)k[9]<<16);
case 9 : c+=((DWORD)k[8]<<8);
/* the first byte of c is reserved for the length */
case 8 : b+=((DWORD)k[7]<<24);
case 7 : b+=((DWORD)k[6]<<16);
case 6 : b+=((DWORD)k[5]<<8);
case 5 : b+=k[4];
case 4 : a+=((DWORD)k[3]<<24);
case 3 : a+=((DWORD)k[2]<<16);
case 2 : a+=((DWORD)k[1]<<8);
case 1 : a+=k[0];
/* case 0: nothing left to add */
}
mix(a,b,c);
/*-------------------------------------------- report the result */
return c;
}
//------------------------------------
PCHAR CArchiveBuilder::ExtractFileName(PCHAR szString)
{
DWORD dwOffset = (DWORD)strlen(szString);
while((dwOffset > 0) && (szString[dwOffset] != '\\'))
dwOffset--;
if (dwOffset == 0)
return szString;
else
return szString+dwOffset+1;
}
//------------------------------------
DWORD CArchiveBuilder::AddFile(PCHAR szFileName)
{
AB_ENTRY_MEMSTATE* pEntry = new AB_ENTRY_MEMSTATE();
PCHAR szNameOnly = ExtractFileName(szFileName);
if ((strlen(szNameOnly)+1) > sizeof(pEntry->szFileName))
throw "Internal Error: Not enough memory allocated for the length of the filename.";
strcpy(pEntry->szFileName, szNameOnly);
_strlwr(pEntry->szFileName);
pEntry->dwFileNameHash = HashString(pEntry->szFileName);
FILE* fiFile;
fiFile = fopen(szFileName, "rb");
if (!fiFile)
throw "Could not load archive data file.";
pEntry->fiFile = fiFile;
fseek(fiFile, 0, SEEK_END);
pEntry->dwFileSize = (DWORD)ftell(fiFile);
fseek(fiFile, 0, SEEK_SET);
if (pEntry->dwFileSize > 16*1024*1024)
throw "Archive data file is greater than 16MB.";
m_vecEntries.push_back(pEntry);
return pEntry->dwFileNameHash;
}
//------------------------------------
void CArchiveBuilder::BuildEntryTable(SAA_ENTRY *pEntryTable, DWORD dwInvalidIndex)
{
CCryptoContext context;
BOOL* pbEntryUsed;
EntryMemStateVector_t::iterator it;
DWORD dwIndex;
AB_ENTRY_MEMSTATE* pEntry;
// Create some stuff to make things simple
pbEntryUsed = new BOOL[m_dwNumEntries];
memset(pbEntryUsed, 0, sizeof(BOOL)*m_dwNumEntries);
// Make the entire table's data random
context.GenerateRandom(m_dwNumEntries*sizeof(SAA_ENTRY), reinterpret_cast<BYTE*>(pEntryTable));
// Ensure that there are no hash collisions between whats in the entry table and our files
BOOL bCollision = FALSE;
for(DWORD i=0; i<m_dwNumEntries; i++) {
it = m_vecEntries.begin();
while(it != m_vecEntries.end()) {
pEntry = (*it);
if (pEntryTable[i].dwFileNameHash == pEntry->dwFileNameHash) {
pEntryTable[i].dwFileNameHash = GetRandom();
bCollision = TRUE;
break;
}
it++;
}
if (bCollision) {
bCollision = FALSE;
i--;
}
}
/*
// Ver1: Set all the invalid entries to the invalid index
for(DWORD i=0; i<m_dwNumEntries; i++) {
pEntryTable[i].dwPrevEntry = dwInvalidIndex;
}
*/
// Ver2: Set all the invalid entries to itself, use the invalid index for the first entry instead
for(DWORD i=0; i<m_dwNumEntries; i++) {
pEntryTable[i].dwPrevEntry = i;
}
// Randomly place our loaded entries into the entry table
it = m_vecEntries.begin();
while(it != m_vecEntries.end()) {
pEntry = (*it);
// Generate a random value that works for us
while(1) {
dwIndex = (GetRandom() >> 5) & 0xFF; // Take it from the middle!
dwIndex %= m_dwNumEntries;
// Check if it matches our reserved index for invalid files
if (dwIndex == dwInvalidIndex)
continue;
// Check to see if any existing entries have this index
if (pbEntryUsed[dwIndex])
continue;
break;
}
pbEntryUsed[dwIndex] = true;
pEntry->pEntry = &(pEntryTable[dwIndex]);
pEntry->dwEntryTableOffset = dwIndex;
pEntry->pbTEAKey = reinterpret_cast<BYTE*>(pEntryTable) +
(pEntry->dwFileNameHash % (sizeof(SAA_ENTRY)*m_dwNumEntries-TEA_KEY_SIZE));
pEntry->pEntry->dwFileNameHash = pEntry->dwFileNameHash;
pEntry->pEntry->dwFileSize = pEntry->dwFileSize;
if (it == m_vecEntries.begin()) {
// Ver2: Set the first index to the invalid index
pEntry->pEntry->dwPrevEntry = dwInvalidIndex;
} else {
pEntry->pEntry->dwPrevEntry = (*(it-1))->dwEntryTableOffset;
}
it++;
}
/*
// Ver1:
// Process the first entry finally and set its previous index to
// an invalid entry, but not to our invalid index
it = m_vecEntries.begin();
while(1) {
dwIndex = (GetRandom() >> 5) & 0xFF; // Take it from the middle!
// Check if it matches our reserved index for invalid files
if (dwIndex == dwInvalidIndex)
continue;
// Check to see if any existing entries have this index
if (pbEntryUsed[dwIndex])
continue;
break;
}
(*it)->pEntry->dwPrevEntry = dwIndex;
*/
// Now obfuscate the non-hash part of all our entries
// XOR it with the hash for good measure.
for(DWORD i=0; i<m_dwNumEntries; i++) {
pEntryTable[i].dwDataBlock ^= pEntryTable[i].dwFileNameHash;
pEntryTable[i].dwDataBlock = OBFUSCATE_DATA(pEntryTable[i].dwDataBlock);
}
}
//------------------------------------
DWORD CArchiveBuilder::GetRandom()
{
static BOOL bSeeded = FALSE;
if (!bSeeded) {
srand((DWORD)time(NULL));
bSeeded = true;
}
DWORD dwRandom;
dwRandom = rand();
dwRandom <<= 15;
dwRandom ^= rand();
dwRandom <<= 15;
dwRandom ^= rand();
return dwRandom;
}
//------------------------------------
void CArchiveBuilder::BuildHeader(SAA_FILE_HEADER* pFileHeader)
{
CCryptoContext context;
context.GenerateRandom(pFileHeader->SizeOf(), reinterpret_cast<BYTE*>(pFileHeader));
pFileHeader->dwFakeDataSize = this->m_dwFDSize;
if (this->m_bProperHeader)
pFileHeader->InitializeDataV1();
pFileHeader->InitializeDataV2();
pFileHeader->headerV2.dwInvalidIndex %= m_dwNumEntries;
}
//------------------------------------
void CArchiveBuilder::BuildEntryData(FILE *fiArchive)
{
CCryptoContext context;
EntryMemStateVector_t::iterator it;
const DWORD dwReadBlockSize = SAA_BLOCK_SIZE;
CTinyEncrypt tinyEncrypt;
BYTE *pbReadData = new BYTE[dwReadBlockSize];
it = m_vecEntries.begin();
while(it != m_vecEntries.end()) {
AB_ENTRY_MEMSTATE* pEntry = (*it);
tinyEncrypt.SetKey(pEntry->pbTEAKey, 0);
DWORD dwReadSize;
for(DWORD i=0; i<pEntry->dwFileSize; i+=dwReadBlockSize) {
dwReadSize = (DWORD)fread(pbReadData, 1, dwReadBlockSize, pEntry->fiFile);
if (dwReadSize < dwReadBlockSize) {
context.GenerateRandom(dwReadBlockSize-dwReadSize, pbReadData+dwReadSize);
}
#ifdef DO_ENCRYPT
tinyEncrypt.EncryptData(dwReadBlockSize, pbReadData);
#endif
fwrite(pbReadData, 1, dwReadBlockSize, fiArchive);
}
it++;
}
delete[] pbReadData;
}
//------------------------------------
void CArchiveBuilder::SignArchive(FILE *fiArchive, DWORD dwSignatureOffset, SAA_FILE_HEADER *pHeader)
{
// Sign the archive file
CCryptoContext context;
CKeyPair keyPair(&context);
CHasher hasher(&context);
CSigner signer;
// 1. Hash the stuff
fseek(fiArchive, pHeader->SizeOf(), SEEK_SET); // start from the actual data section
const DWORD dwReadBlockSize = 10 * 1024; // 10kb
BYTE *pbReadData = new BYTE[dwReadBlockSize];
DWORD dwReadSize;
DWORD dwPos = ftell(fiArchive);
while(!feof(fiArchive)) {
dwReadSize = (DWORD)fread(pbReadData, 1, dwReadBlockSize, fiArchive);
hasher.AddData(dwReadSize, pbReadData);
dwPos = ftell(fiArchive);
}
delete[] pbReadData;
// 2. Load the key, and sign the hash
keyPair.LoadFromFile("pkey.bin");
signer.SignHash(&hasher);
keyPair.ReleaseKey();
// 3. Write the signature
pHeader->headerV2.dwSignSize = signer.GetSignatureLength();
fseek(fiArchive, dwSignatureOffset, SEEK_SET);
fwrite(signer.GetSignature(), 1, pHeader->headerV2.dwSignSize, fiArchive);
}
//------------------------------------
void CArchiveBuilder::WriteArchive(PCHAR szFileName)
{
SAA_FILE_HEADER header;
SAA_ENTRY *pEntryTable;
FILE* fiArchive;
fiArchive = fopen(szFileName, "w+b");
pEntryTable = new SAA_ENTRY[m_dwNumEntries];
// 1. Build the header
BuildHeader(&header);
// 2. Build the entry table
BuildEntryTable(pEntryTable, header.headerV2.dwInvalidIndex);
// 3. Encode and write the file data
fseek(fiArchive, header.SizeOf(), SEEK_SET);
BuildEntryData(fiArchive);
// 4. Encrypt and write the entry table
// (Note that the file data decryption must be done with decrypted entry table used for keys)
CTinyEncrypt tinyEnc;
tinyEnc.LoadKey("skey.bin");
#ifdef DO_ENCRYPT
tinyEnc.EncryptData(sizeof(SAA_ENTRY)*m_dwNumEntries, reinterpret_cast<BYTE*>(pEntryTable));
#endif
fwrite(pEntryTable, sizeof(SAA_ENTRY), m_dwNumEntries, fiArchive);
// 5. Sign the data (excluding the header)
fflush(fiArchive);
SignArchive(fiArchive, (DWORD)ftell(fiArchive), &header);
// 6. Finish the header and write it
#ifdef DO_ENCRYPT
header.XorV2Identifier();
#endif
header.Write(fiArchive);
// And we're done.
fclose(fiArchive);
delete[] pEntryTable;
}
//------------------------------------