// Copyright 2014 PDFium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com #include #include "../../../include/fpdfapi/fpdf_parser.h" #include "../../../include/fdrm/fx_crypt.h" const uint8_t defpasscode[32] = { 0x28, 0xbf, 0x4e, 0x5e, 0x4e, 0x75, 0x8a, 0x41, 0x64, 0x00, 0x4e, 0x56, 0xff, 0xfa, 0x01, 0x08, 0x2e, 0x2e, 0x00, 0xb6, 0xd0, 0x68, 0x3e, 0x80, 0x2f, 0x0c, 0xa9, 0xfe, 0x64, 0x53, 0x69, 0x7a }; void CalcEncryptKey(CPDF_Dictionary* pEncrypt, const uint8_t* password, FX_DWORD pass_size, uint8_t* key, int keylen, FX_BOOL bIgnoreMeta, CPDF_Array* pIdArray) { int revision = pEncrypt->GetInteger(FX_BSTRC("R")); uint8_t passcode[32]; for (FX_DWORD i = 0; i < 32; i ++) { passcode[i] = i < pass_size ? password[i] : defpasscode[i - pass_size]; } uint8_t md5[100]; CRYPT_MD5Start(md5); CRYPT_MD5Update(md5, passcode, 32); CFX_ByteString okey = pEncrypt->GetString(FX_BSTRC("O")); CRYPT_MD5Update(md5, (uint8_t*)okey.c_str(), okey.GetLength()); FX_DWORD perm = pEncrypt->GetInteger(FX_BSTRC("P")); CRYPT_MD5Update(md5, (uint8_t*)&perm, 4); if (pIdArray) { CFX_ByteString id = pIdArray->GetString(0); CRYPT_MD5Update(md5, (uint8_t*)id.c_str(), id.GetLength()); } if (!bIgnoreMeta && revision >= 3 && !pEncrypt->GetInteger(FX_BSTRC("EncryptMetadata"), 1)) { FX_DWORD tag = (FX_DWORD) - 1; CRYPT_MD5Update(md5, (uint8_t*)&tag, 4); } uint8_t digest[16]; CRYPT_MD5Finish(md5, digest); FX_DWORD copy_len = keylen; if (copy_len > sizeof(digest)) { copy_len = sizeof(digest); } if (revision >= 3) { for (int i = 0; i < 50; i ++) { CRYPT_MD5Generate(digest, copy_len, digest); } } FXSYS_memset32(key, 0, keylen); FXSYS_memcpy32(key, digest, copy_len); } CPDF_CryptoHandler* CPDF_StandardSecurityHandler::CreateCryptoHandler() { return new CPDF_StandardCryptoHandler; } typedef struct _PDF_CRYPTOITEM { int32_t m_Cipher; int32_t m_KeyLen; FX_BOOL m_bChecked; CPDF_StandardCryptoHandler* m_pCryptoHandler; } PDF_CRYPTOITEM; CPDF_StandardSecurityHandler::CPDF_StandardSecurityHandler() { m_Version = 0; m_Revision = 0; m_pParser = NULL; m_pEncryptDict = NULL; m_bOwner = FALSE; m_Permissions = 0; m_Cipher = FXCIPHER_NONE; m_KeyLen = 0; } CPDF_StandardSecurityHandler::~CPDF_StandardSecurityHandler() { } FX_BOOL CPDF_StandardSecurityHandler::OnInit(CPDF_Parser* pParser, CPDF_Dictionary* pEncryptDict) { m_pParser = pParser; if (!LoadDict(pEncryptDict)) { return FALSE; } if (m_Cipher == FXCIPHER_NONE) { return TRUE; } return CheckSecurity(m_KeyLen); } FX_BOOL CPDF_StandardSecurityHandler::CheckSecurity(int32_t key_len) { CFX_ByteString password = m_pParser->GetPassword(); if (CheckPassword(password, password.GetLength(), TRUE, m_EncryptKey, key_len)) { if (password.IsEmpty()) { if (!CheckPassword(password, password.GetLength(), FALSE, m_EncryptKey, key_len)) { return FALSE; } } m_bOwner = TRUE; return TRUE; } return CheckPassword(password, password.GetLength(), FALSE, m_EncryptKey, key_len); } FX_DWORD CPDF_StandardSecurityHandler::GetPermissions() { return m_Permissions; } static FX_BOOL _LoadCryptInfo(CPDF_Dictionary* pEncryptDict, FX_BSTR name, int& cipher, int& keylen) { int Version = pEncryptDict->GetInteger(FX_BSTRC("V")); cipher = FXCIPHER_RC4; keylen = 0; if (Version >= 4) { CPDF_Dictionary* pCryptFilters = pEncryptDict->GetDict(FX_BSTRC("CF")); if (pCryptFilters == NULL) { return FALSE; } if (name == FX_BSTRC("Identity")) { cipher = FXCIPHER_NONE; } else { CPDF_Dictionary* pDefFilter = pCryptFilters->GetDict(name); if (pDefFilter == NULL) { return FALSE; } int nKeyBits = 0; if (Version == 4) { nKeyBits = pDefFilter->GetInteger(FX_BSTRC("Length"), 0); if (nKeyBits == 0) { nKeyBits = pEncryptDict->GetInteger(FX_BSTRC("Length"), 128); } } else { nKeyBits = pEncryptDict->GetInteger(FX_BSTRC("Length"), 256); } if (nKeyBits < 40) { nKeyBits *= 8; } keylen = nKeyBits / 8; CFX_ByteString cipher_name = pDefFilter->GetString(FX_BSTRC("CFM")); if (cipher_name == FX_BSTRC("AESV2") || cipher_name == FX_BSTRC("AESV3")) { cipher = FXCIPHER_AES; } } } else { keylen = Version > 1 ? pEncryptDict->GetInteger(FX_BSTRC("Length"), 40) / 8 : 5; } if (keylen > 32 || keylen < 0) { return FALSE; } return TRUE; } FX_BOOL CPDF_StandardSecurityHandler::LoadDict(CPDF_Dictionary* pEncryptDict) { m_pEncryptDict = pEncryptDict; m_bOwner = FALSE; m_Version = pEncryptDict->GetInteger(FX_BSTRC("V")); m_Revision = pEncryptDict->GetInteger(FX_BSTRC("R")); m_Permissions = pEncryptDict->GetInteger(FX_BSTRC("P"), -1); if (m_Version < 4) { return _LoadCryptInfo(pEncryptDict, CFX_ByteString(), m_Cipher, m_KeyLen); } CFX_ByteString stmf_name = pEncryptDict->GetString(FX_BSTRC("StmF")); CFX_ByteString strf_name = pEncryptDict->GetString(FX_BSTRC("StrF")); if (stmf_name != strf_name) { return FALSE; } if (!_LoadCryptInfo(pEncryptDict, strf_name, m_Cipher, m_KeyLen)) { return FALSE; } return TRUE; } FX_BOOL CPDF_StandardSecurityHandler::LoadDict(CPDF_Dictionary* pEncryptDict, FX_DWORD type, int& cipher, int& key_len) { m_pEncryptDict = pEncryptDict; m_bOwner = FALSE; m_Version = pEncryptDict->GetInteger(FX_BSTRC("V")); m_Revision = pEncryptDict->GetInteger(FX_BSTRC("R")); m_Permissions = pEncryptDict->GetInteger(FX_BSTRC("P"), -1); CFX_ByteString strf_name, stmf_name; if (m_Version >= 4) { stmf_name = pEncryptDict->GetString(FX_BSTRC("StmF")); strf_name = pEncryptDict->GetString(FX_BSTRC("StrF")); if (stmf_name != strf_name) { return FALSE; } } if (!_LoadCryptInfo(pEncryptDict, strf_name, cipher, key_len)) { return FALSE; } m_Cipher = cipher; m_KeyLen = key_len; return TRUE; return TRUE; } FX_BOOL CPDF_StandardSecurityHandler::GetCryptInfo(int& cipher, const uint8_t*& buffer, int& keylen) { cipher = m_Cipher; buffer = m_EncryptKey; keylen = m_KeyLen; return TRUE; } #define FX_GET_32WORD(n,b,i) \ { \ (n) = (FX_DWORD)(( (uint64_t) (b)[(i)] << 24 ) \ | ( (uint64_t) (b)[(i) + 1] << 16 ) \ | ( (uint64_t) (b)[(i) + 2] << 8 ) \ | ( (uint64_t) (b)[(i) + 3] )); \ } int BigOrder64BitsMod3(uint8_t* data) { uint64_t ret = 0; for (int i = 0; i < 4; ++i) { FX_DWORD value; FX_GET_32WORD(value, data, 4 * i); ret <<= 32; ret |= value; ret %= 3; } return (int)ret; } void Revision6_Hash(const uint8_t* password, FX_DWORD size, const uint8_t* salt, const uint8_t* vector, uint8_t* hash) { int iBlockSize = 32; uint8_t sha[128]; CRYPT_SHA256Start(sha); CRYPT_SHA256Update(sha, password, size); CRYPT_SHA256Update(sha, salt, 8); if (vector) { CRYPT_SHA256Update(sha, vector, 48); } uint8_t digest[32]; CRYPT_SHA256Finish(sha, digest); CFX_ByteTextBuf buf; uint8_t* input = digest; uint8_t* key = input; uint8_t* iv = input + 16; uint8_t* E = buf.GetBuffer(); int iBufLen = buf.GetLength(); CFX_ByteTextBuf interDigest; int i = 0; uint8_t* aes = FX_Alloc(uint8_t, 2048); while (i < 64 || i < E[iBufLen - 1] + 32) { int iRoundSize = size + iBlockSize; if (vector) { iRoundSize += 48; } iBufLen = iRoundSize * 64; buf.EstimateSize(iBufLen); E = buf.GetBuffer(); CFX_ByteTextBuf content; for (int j = 0; j < 64; ++j) { content.AppendBlock(password, size); content.AppendBlock(input, iBlockSize); if (vector) { content.AppendBlock(vector, 48); } } CRYPT_AESSetKey(aes, 16, key, 16, TRUE); CRYPT_AESSetIV(aes, iv); CRYPT_AESEncrypt(aes, E, content.GetBuffer(), iBufLen); int iHash = 0; switch (BigOrder64BitsMod3(E)) { case 0: iHash = 0; iBlockSize = 32; break; case 1: iHash = 1; iBlockSize = 48; break; default: iHash = 2; iBlockSize = 64; break; } interDigest.EstimateSize(iBlockSize); input = interDigest.GetBuffer(); if (iHash == 0) { CRYPT_SHA256Generate(E, iBufLen, input); } else if (iHash == 1) { CRYPT_SHA384Generate(E, iBufLen, input); } else if (iHash == 2) { CRYPT_SHA512Generate(E, iBufLen, input); } key = input; iv = input + 16; ++i; } FX_Free(aes); if (hash) { FXSYS_memcpy32(hash, input, 32); } } FX_BOOL CPDF_StandardSecurityHandler::AES256_CheckPassword(const uint8_t* password, FX_DWORD size, FX_BOOL bOwner, uint8_t* key) { CFX_ByteString okey = m_pEncryptDict ? m_pEncryptDict->GetString(FX_BSTRC("O")) : CFX_ByteString(); if (okey.GetLength() < 48) { return FALSE; } CFX_ByteString ukey = m_pEncryptDict ? m_pEncryptDict->GetString(FX_BSTRC("U")) : CFX_ByteString(); if (ukey.GetLength() < 48) { return FALSE; } const uint8_t* pkey = bOwner ? (const uint8_t*)okey : (const uint8_t*)ukey; uint8_t sha[128]; uint8_t digest[32]; if (m_Revision >= 6) { Revision6_Hash(password, size, (const uint8_t*)pkey + 32, (bOwner ? (const uint8_t*)ukey : NULL), digest); } else { CRYPT_SHA256Start(sha); CRYPT_SHA256Update(sha, password, size); CRYPT_SHA256Update(sha, pkey + 32, 8); if (bOwner) { CRYPT_SHA256Update(sha, ukey, 48); } CRYPT_SHA256Finish(sha, digest); } if (FXSYS_memcmp32(digest, pkey, 32) != 0) { return FALSE; } if (key == NULL) { return TRUE; } if (m_Revision >= 6) { Revision6_Hash(password, size, (const uint8_t*)pkey + 40, (bOwner ? (const uint8_t*)ukey : NULL), digest); } else { CRYPT_SHA256Start(sha); CRYPT_SHA256Update(sha, password, size); CRYPT_SHA256Update(sha, pkey + 40, 8); if (bOwner) { CRYPT_SHA256Update(sha, ukey, 48); } CRYPT_SHA256Finish(sha, digest); } CFX_ByteString ekey = m_pEncryptDict ? m_pEncryptDict->GetString(bOwner ? FX_BSTRC("OE") : FX_BSTRC("UE")) : CFX_ByteString(); if (ekey.GetLength() < 32) { return FALSE; } uint8_t* aes = FX_Alloc(uint8_t, 2048); CRYPT_AESSetKey(aes, 16, digest, 32, FALSE); uint8_t iv[16]; FXSYS_memset32(iv, 0, 16); CRYPT_AESSetIV(aes, iv); CRYPT_AESDecrypt(aes, key, ekey, 32); CRYPT_AESSetKey(aes, 16, key, 32, FALSE); CRYPT_AESSetIV(aes, iv); CFX_ByteString perms = m_pEncryptDict->GetString(FX_BSTRC("Perms")); if (perms.IsEmpty()) { return FALSE; } uint8_t perms_buf[16]; FXSYS_memset32(perms_buf, 0, sizeof(perms_buf)); FX_DWORD copy_len = sizeof(perms_buf); if (copy_len > (FX_DWORD)perms.GetLength()) { copy_len = perms.GetLength(); } FXSYS_memcpy32(perms_buf, (const uint8_t*)perms, copy_len); uint8_t buf[16]; CRYPT_AESDecrypt(aes, buf, perms_buf, 16); FX_Free(aes); if (buf[9] != 'a' || buf[10] != 'd' || buf[11] != 'b') { return FALSE; } if (FXDWORD_GET_LSBFIRST(buf) != m_Permissions) { return FALSE; } if ((buf[8] == 'T' && !IsMetadataEncrypted()) || (buf[8] == 'F' && IsMetadataEncrypted())) { return FALSE; } return TRUE; } int CPDF_StandardSecurityHandler::CheckPassword(const uint8_t* password, FX_DWORD pass_size, FX_BOOL bOwner, uint8_t* key) { return CheckPassword(password, pass_size, bOwner, key, m_KeyLen); } int CPDF_StandardSecurityHandler::CheckPassword(const uint8_t* password, FX_DWORD size, FX_BOOL bOwner, uint8_t* key, int32_t key_len) { if (m_Revision >= 5) { return AES256_CheckPassword(password, size, bOwner, key); } uint8_t keybuf[32]; if (key == NULL) { key = keybuf; } if (bOwner) { return CheckOwnerPassword(password, size, key, key_len); } return CheckUserPassword(password, size, FALSE, key, key_len) || CheckUserPassword(password, size, TRUE, key, key_len); } FX_BOOL CPDF_StandardSecurityHandler::CheckUserPassword(const uint8_t* password, FX_DWORD pass_size, FX_BOOL bIgnoreEncryptMeta, uint8_t* key, int32_t key_len) { CalcEncryptKey(m_pEncryptDict, password, pass_size, key, key_len, bIgnoreEncryptMeta, m_pParser->GetIDArray()); CFX_ByteString ukey = m_pEncryptDict ? m_pEncryptDict->GetString(FX_BSTRC("U")) : CFX_ByteString(); if (ukey.GetLength() < 16) { return FALSE; } uint8_t ukeybuf[32]; if (m_Revision == 2) { FXSYS_memcpy32(ukeybuf, defpasscode, 32); CRYPT_ArcFourCryptBlock(ukeybuf, 32, key, key_len); } else { uint8_t test[32], tmpkey[32]; FX_DWORD copy_len = sizeof(test); if (copy_len > (FX_DWORD)ukey.GetLength()) { copy_len = ukey.GetLength(); } FXSYS_memset32(test, 0, sizeof(test)); FXSYS_memset32(tmpkey, 0, sizeof(tmpkey)); FXSYS_memcpy32(test, ukey.c_str(), copy_len); for (int i = 19; i >= 0; i --) { for (int j = 0; j < key_len; j ++) { tmpkey[j] = key[j] ^ i; } CRYPT_ArcFourCryptBlock(test, 32, tmpkey, key_len); } uint8_t md5[100]; CRYPT_MD5Start(md5); CRYPT_MD5Update(md5, defpasscode, 32); CPDF_Array* pIdArray = m_pParser->GetIDArray(); if (pIdArray) { CFX_ByteString id = pIdArray->GetString(0); CRYPT_MD5Update(md5, (uint8_t*)id.c_str(), id.GetLength()); } CRYPT_MD5Finish(md5, ukeybuf); return FXSYS_memcmp32(test, ukeybuf, 16) == 0; } if (FXSYS_memcmp32((void*)ukey.c_str(), ukeybuf, 16) == 0) { return TRUE; } return FALSE; } CFX_ByteString CPDF_StandardSecurityHandler::GetUserPassword(const uint8_t* owner_pass, FX_DWORD pass_size) { return GetUserPassword(owner_pass, pass_size, m_KeyLen); } CFX_ByteString CPDF_StandardSecurityHandler::GetUserPassword(const uint8_t* owner_pass, FX_DWORD pass_size, int32_t key_len) { CFX_ByteString okey = m_pEncryptDict->GetString(FX_BSTRC("O")); uint8_t passcode[32]; FX_DWORD i; for (i = 0; i < 32; i ++) { passcode[i] = i < pass_size ? owner_pass[i] : defpasscode[i - pass_size]; } uint8_t digest[16]; CRYPT_MD5Generate(passcode, 32, digest); if (m_Revision >= 3) { for (int i = 0; i < 50; i ++) { CRYPT_MD5Generate(digest, 16, digest); } } uint8_t enckey[32]; FXSYS_memset32(enckey, 0, sizeof(enckey)); FX_DWORD copy_len = key_len; if (copy_len > sizeof(digest)) { copy_len = sizeof(digest); } FXSYS_memcpy32(enckey, digest, copy_len); int okeylen = okey.GetLength(); if (okeylen > 32) { okeylen = 32; } uint8_t okeybuf[64]; FXSYS_memset32(okeybuf, 0, sizeof(okeybuf)); FXSYS_memcpy32(okeybuf, okey.c_str(), okeylen); if (m_Revision == 2) { CRYPT_ArcFourCryptBlock(okeybuf, okeylen, enckey, key_len); } else { for (int i = 19; i >= 0; i --) { uint8_t tempkey[32]; FXSYS_memset32(tempkey, 0, sizeof(tempkey)); for (int j = 0; j < m_KeyLen; j ++) { tempkey[j] = enckey[j] ^ i; } CRYPT_ArcFourCryptBlock(okeybuf, okeylen, tempkey, key_len); } } int len = 32; while (len && defpasscode[len - 1] == okeybuf[len - 1]) { len --; } return CFX_ByteString(okeybuf, len); } FX_BOOL CPDF_StandardSecurityHandler::CheckOwnerPassword(const uint8_t* password, FX_DWORD pass_size, uint8_t* key, int32_t key_len) { CFX_ByteString user_pass = GetUserPassword(password, pass_size, key_len); if (CheckUserPassword(user_pass, user_pass.GetLength(), FALSE, key, key_len)) { return TRUE; } return CheckUserPassword(user_pass, user_pass.GetLength(), TRUE, key, key_len); } FX_BOOL CPDF_StandardSecurityHandler::IsMetadataEncrypted() { return m_pEncryptDict->GetBoolean(FX_BSTRC("EncryptMetadata"), TRUE); } CPDF_SecurityHandler* FPDF_CreateStandardSecurityHandler() { return new CPDF_StandardSecurityHandler; } void CPDF_StandardSecurityHandler::OnCreate(CPDF_Dictionary* pEncryptDict, CPDF_Array* pIdArray, const uint8_t* user_pass, FX_DWORD user_size, const uint8_t* owner_pass, FX_DWORD owner_size, FX_BOOL bDefault, FX_DWORD type) { int cipher = 0, key_len = 0; if (!LoadDict(pEncryptDict, type, cipher, key_len)) { return; } if (bDefault && (owner_pass == NULL || owner_size == 0)) { owner_pass = user_pass; owner_size = user_size; } if (m_Revision >= 5) { int t = (int)time(NULL); uint8_t sha[128]; CRYPT_SHA256Start(sha); CRYPT_SHA256Update(sha, (uint8_t*)&t, sizeof t); CRYPT_SHA256Update(sha, m_EncryptKey, 32); CRYPT_SHA256Update(sha, (uint8_t*)"there", 5); CRYPT_SHA256Finish(sha, m_EncryptKey); AES256_SetPassword(pEncryptDict, user_pass, user_size, FALSE, m_EncryptKey); if (bDefault) { AES256_SetPassword(pEncryptDict, owner_pass, owner_size, TRUE, m_EncryptKey); AES256_SetPerms(pEncryptDict, m_Permissions, pEncryptDict->GetBoolean(FX_BSTRC("EncryptMetadata"), TRUE), m_EncryptKey); } return; } if (bDefault) { uint8_t passcode[32]; FX_DWORD i; for (i = 0; i < 32; i ++) { passcode[i] = i < owner_size ? owner_pass[i] : defpasscode[i - owner_size]; } uint8_t digest[16]; CRYPT_MD5Generate(passcode, 32, digest); if (m_Revision >= 3) { for (int i = 0; i < 50; i ++) { CRYPT_MD5Generate(digest, 16, digest); } } uint8_t enckey[32]; FXSYS_memcpy32(enckey, digest, key_len); for (i = 0; i < 32; i ++) { passcode[i] = i < user_size ? user_pass[i] : defpasscode[i - user_size]; } CRYPT_ArcFourCryptBlock(passcode, 32, enckey, key_len); uint8_t tempkey[32]; if (m_Revision >= 3) { for (i = 1; i <= 19; i ++) { for (int j = 0; j < key_len; j ++) { tempkey[j] = enckey[j] ^ (uint8_t)i; } CRYPT_ArcFourCryptBlock(passcode, 32, tempkey, key_len); } } pEncryptDict->SetAtString(FX_BSTRC("O"), CFX_ByteString(passcode, 32)); } CalcEncryptKey(m_pEncryptDict, (uint8_t*)user_pass, user_size, m_EncryptKey, key_len, FALSE, pIdArray); if (m_Revision < 3) { uint8_t tempbuf[32]; FXSYS_memcpy32(tempbuf, defpasscode, 32); CRYPT_ArcFourCryptBlock(tempbuf, 32, m_EncryptKey, key_len); pEncryptDict->SetAtString(FX_BSTRC("U"), CFX_ByteString(tempbuf, 32)); } else { uint8_t md5[100]; CRYPT_MD5Start(md5); CRYPT_MD5Update(md5, defpasscode, 32); if (pIdArray) { CFX_ByteString id = pIdArray->GetString(0); CRYPT_MD5Update(md5, (uint8_t*)id.c_str(), id.GetLength()); } uint8_t digest[32]; CRYPT_MD5Finish(md5, digest); CRYPT_ArcFourCryptBlock(digest, 16, m_EncryptKey, key_len); uint8_t tempkey[32]; for (int i = 1; i <= 19; i ++) { for (int j = 0; j < key_len; j ++) { tempkey[j] = m_EncryptKey[j] ^ (uint8_t)i; } CRYPT_ArcFourCryptBlock(digest, 16, tempkey, key_len); } CRYPT_MD5Generate(digest, 16, digest + 16); pEncryptDict->SetAtString(FX_BSTRC("U"), CFX_ByteString(digest, 32)); } } void CPDF_StandardSecurityHandler::OnCreate(CPDF_Dictionary* pEncryptDict, CPDF_Array* pIdArray, const uint8_t* user_pass, FX_DWORD user_size, const uint8_t* owner_pass, FX_DWORD owner_size, FX_DWORD type) { OnCreate(pEncryptDict, pIdArray, user_pass, user_size, owner_pass, owner_size, TRUE, type); } void CPDF_StandardSecurityHandler::OnCreate(CPDF_Dictionary* pEncryptDict, CPDF_Array* pIdArray, const uint8_t* user_pass, FX_DWORD user_size, FX_DWORD type) { OnCreate(pEncryptDict, pIdArray, user_pass, user_size, NULL, 0, FALSE, type); } void CPDF_StandardSecurityHandler::AES256_SetPassword(CPDF_Dictionary* pEncryptDict, const uint8_t* password, FX_DWORD size, FX_BOOL bOwner, const uint8_t* key) { uint8_t sha[128]; CRYPT_SHA1Start(sha); CRYPT_SHA1Update(sha, key, 32); CRYPT_SHA1Update(sha, (uint8_t*)"hello", 5); uint8_t digest[20]; CRYPT_SHA1Finish(sha, digest); CFX_ByteString ukey = pEncryptDict->GetString(FX_BSTRC("U")); uint8_t digest1[48]; if (m_Revision >= 6) { Revision6_Hash(password, size, digest, (bOwner ? (const uint8_t*)ukey : NULL), digest1); } else { CRYPT_SHA256Start(sha); CRYPT_SHA256Update(sha, password, size); CRYPT_SHA256Update(sha, digest, 8); if (bOwner) { CRYPT_SHA256Update(sha, ukey, ukey.GetLength()); } CRYPT_SHA256Finish(sha, digest1); } FXSYS_memcpy32(digest1 + 32, digest, 16); pEncryptDict->SetAtString(bOwner ? FX_BSTRC("O") : FX_BSTRC("U"), CFX_ByteString(digest1, 48)); if (m_Revision >= 6) { Revision6_Hash(password, size, digest + 8, (bOwner ? (const uint8_t*)ukey : NULL), digest1); } else { CRYPT_SHA256Start(sha); CRYPT_SHA256Update(sha, password, size); CRYPT_SHA256Update(sha, digest + 8, 8); if (bOwner) { CRYPT_SHA256Update(sha, ukey, ukey.GetLength()); } CRYPT_SHA256Finish(sha, digest1); } uint8_t* aes = FX_Alloc(uint8_t, 2048); CRYPT_AESSetKey(aes, 16, digest1, 32, TRUE); uint8_t iv[16]; FXSYS_memset32(iv, 0, 16); CRYPT_AESSetIV(aes, iv); CRYPT_AESEncrypt(aes, digest1, key, 32); FX_Free(aes); pEncryptDict->SetAtString(bOwner ? FX_BSTRC("OE") : FX_BSTRC("UE"), CFX_ByteString(digest1, 32)); } void CPDF_StandardSecurityHandler::AES256_SetPerms(CPDF_Dictionary* pEncryptDict, FX_DWORD permissions, FX_BOOL bEncryptMetadata, const uint8_t* key) { uint8_t buf[16]; buf[0] = (uint8_t)permissions; buf[1] = (uint8_t)(permissions >> 8); buf[2] = (uint8_t)(permissions >> 16); buf[3] = (uint8_t)(permissions >> 24); buf[4] = 0xff; buf[5] = 0xff; buf[6] = 0xff; buf[7] = 0xff; buf[8] = bEncryptMetadata ? 'T' : 'F'; buf[9] = 'a'; buf[10] = 'd'; buf[11] = 'b'; uint8_t* aes = FX_Alloc(uint8_t, 2048); CRYPT_AESSetKey(aes, 16, key, 32, TRUE); uint8_t iv[16], buf1[16]; FXSYS_memset32(iv, 0, 16); CRYPT_AESSetIV(aes, iv); CRYPT_AESEncrypt(aes, buf1, buf, 16); FX_Free(aes); pEncryptDict->SetAtString(FX_BSTRC("Perms"), CFX_ByteString(buf1, 16)); } void CPDF_StandardCryptoHandler::CryptBlock(FX_BOOL bEncrypt, FX_DWORD objnum, FX_DWORD gennum, const uint8_t* src_buf, FX_DWORD src_size, uint8_t* dest_buf, FX_DWORD& dest_size) { if (m_Cipher == FXCIPHER_NONE) { FXSYS_memcpy32(dest_buf, src_buf, src_size); return; } uint8_t realkey[16]; int realkeylen = 16; if (m_Cipher != FXCIPHER_AES || m_KeyLen != 32) { uint8_t key1[32]; FXSYS_memcpy32(key1, m_EncryptKey, m_KeyLen); key1[m_KeyLen + 0] = (uint8_t)objnum; key1[m_KeyLen + 1] = (uint8_t)(objnum >> 8); key1[m_KeyLen + 2] = (uint8_t)(objnum >> 16); key1[m_KeyLen + 3] = (uint8_t)gennum; key1[m_KeyLen + 4] = (uint8_t)(gennum >> 8); FXSYS_memcpy32(key1 + m_KeyLen, &objnum, 3); FXSYS_memcpy32(key1 + m_KeyLen + 3, &gennum, 2); if (m_Cipher == FXCIPHER_AES) { FXSYS_memcpy32(key1 + m_KeyLen + 5, "sAlT", 4); } CRYPT_MD5Generate(key1, m_Cipher == FXCIPHER_AES ? m_KeyLen + 9 : m_KeyLen + 5, realkey); realkeylen = m_KeyLen + 5; if (realkeylen > 16) { realkeylen = 16; } } if (m_Cipher == FXCIPHER_AES) { CRYPT_AESSetKey(m_pAESContext, 16, m_KeyLen == 32 ? m_EncryptKey : realkey, m_KeyLen, bEncrypt); if (bEncrypt) { uint8_t iv[16]; for (int i = 0; i < 16; i ++) { iv[i] = (uint8_t)rand(); } CRYPT_AESSetIV(m_pAESContext, iv); FXSYS_memcpy32(dest_buf, iv, 16); int nblocks = src_size / 16; CRYPT_AESEncrypt(m_pAESContext, dest_buf + 16, src_buf, nblocks * 16); uint8_t padding[16]; FXSYS_memcpy32(padding, src_buf + nblocks * 16, src_size % 16); FXSYS_memset8(padding + src_size % 16, 16 - src_size % 16, 16 - src_size % 16); CRYPT_AESEncrypt(m_pAESContext, dest_buf + nblocks * 16 + 16, padding, 16); dest_size = 32 + nblocks * 16; } else { CRYPT_AESSetIV(m_pAESContext, src_buf); CRYPT_AESDecrypt(m_pAESContext, dest_buf, src_buf + 16, src_size - 16); dest_size = src_size - 16; dest_size -= dest_buf[dest_size - 1]; } } else { ASSERT(dest_size == src_size); if (dest_buf != src_buf) { FXSYS_memcpy32(dest_buf, src_buf, src_size); } CRYPT_ArcFourCryptBlock(dest_buf, dest_size, realkey, realkeylen); } } typedef struct _AESCryptContext { uint8_t m_Context[2048]; FX_BOOL m_bIV; uint8_t m_Block[16]; FX_DWORD m_BlockOffset; } AESCryptContext; void* CPDF_StandardCryptoHandler::CryptStart(FX_DWORD objnum, FX_DWORD gennum, FX_BOOL bEncrypt) { if (m_Cipher == FXCIPHER_NONE) { return this; } if (m_Cipher == FXCIPHER_AES && m_KeyLen == 32) { AESCryptContext* pContext = FX_Alloc(AESCryptContext, 1); pContext->m_bIV = TRUE; pContext->m_BlockOffset = 0; CRYPT_AESSetKey(pContext->m_Context, 16, m_EncryptKey, 32, bEncrypt); if (bEncrypt) { for (int i = 0; i < 16; i ++) { pContext->m_Block[i] = (uint8_t)rand(); } CRYPT_AESSetIV(pContext->m_Context, pContext->m_Block); } return pContext; } uint8_t key1[48]; FXSYS_memcpy32(key1, m_EncryptKey, m_KeyLen); FXSYS_memcpy32(key1 + m_KeyLen, &objnum, 3); FXSYS_memcpy32(key1 + m_KeyLen + 3, &gennum, 2); if (m_Cipher == FXCIPHER_AES) { FXSYS_memcpy32(key1 + m_KeyLen + 5, "sAlT", 4); } uint8_t realkey[16]; CRYPT_MD5Generate(key1, m_Cipher == FXCIPHER_AES ? m_KeyLen + 9 : m_KeyLen + 5, realkey); int realkeylen = m_KeyLen + 5; if (realkeylen > 16) { realkeylen = 16; } if (m_Cipher == FXCIPHER_AES) { AESCryptContext* pContext = FX_Alloc(AESCryptContext, 1); pContext->m_bIV = TRUE; pContext->m_BlockOffset = 0; CRYPT_AESSetKey(pContext->m_Context, 16, realkey, 16, bEncrypt); if (bEncrypt) { for (int i = 0; i < 16; i ++) { pContext->m_Block[i] = (uint8_t)rand(); } CRYPT_AESSetIV(pContext->m_Context, pContext->m_Block); } return pContext; } void* pContext = FX_Alloc(uint8_t, 1040); CRYPT_ArcFourSetup(pContext, realkey, realkeylen); return pContext; } FX_BOOL CPDF_StandardCryptoHandler::CryptStream(void* context, const uint8_t* src_buf, FX_DWORD src_size, CFX_BinaryBuf& dest_buf, FX_BOOL bEncrypt) { if (!context) { return FALSE; } if (m_Cipher == FXCIPHER_NONE) { dest_buf.AppendBlock(src_buf, src_size); return TRUE; } if (m_Cipher == FXCIPHER_RC4) { int old_size = dest_buf.GetSize(); dest_buf.AppendBlock(src_buf, src_size); CRYPT_ArcFourCrypt(context, dest_buf.GetBuffer() + old_size, src_size); return TRUE; } AESCryptContext* pContext = (AESCryptContext*)context; if (pContext->m_bIV && bEncrypt) { dest_buf.AppendBlock(pContext->m_Block, 16); pContext->m_bIV = FALSE; } FX_DWORD src_off = 0; FX_DWORD src_left = src_size; while (1) { FX_DWORD copy_size = 16 - pContext->m_BlockOffset; if (copy_size > src_left) { copy_size = src_left; } FXSYS_memcpy32(pContext->m_Block + pContext->m_BlockOffset, src_buf + src_off, copy_size); src_off += copy_size; src_left -= copy_size; pContext->m_BlockOffset += copy_size; if (pContext->m_BlockOffset == 16) { if (!bEncrypt && pContext->m_bIV) { CRYPT_AESSetIV(pContext->m_Context, pContext->m_Block); pContext->m_bIV = FALSE; pContext->m_BlockOffset = 0; } else if (src_off < src_size) { uint8_t block_buf[16]; if (bEncrypt) { CRYPT_AESEncrypt(pContext->m_Context, block_buf, pContext->m_Block, 16); } else { CRYPT_AESDecrypt(pContext->m_Context, block_buf, pContext->m_Block, 16); } dest_buf.AppendBlock(block_buf, 16); pContext->m_BlockOffset = 0; } } if (!src_left) { break; } } return TRUE; } FX_BOOL CPDF_StandardCryptoHandler::CryptFinish(void* context, CFX_BinaryBuf& dest_buf, FX_BOOL bEncrypt) { if (!context) { return FALSE; } if (m_Cipher == FXCIPHER_NONE) { return TRUE; } if (m_Cipher == FXCIPHER_RC4) { FX_Free(context); return TRUE; } AESCryptContext* pContext = (AESCryptContext*)context; if (bEncrypt) { uint8_t block_buf[16]; if (pContext->m_BlockOffset == 16) { CRYPT_AESEncrypt(pContext->m_Context, block_buf, pContext->m_Block, 16); dest_buf.AppendBlock(block_buf, 16); pContext->m_BlockOffset = 0; } FXSYS_memset8(pContext->m_Block + pContext->m_BlockOffset, (uint8_t)(16 - pContext->m_BlockOffset), 16 - pContext->m_BlockOffset); CRYPT_AESEncrypt(pContext->m_Context, block_buf, pContext->m_Block, 16); dest_buf.AppendBlock(block_buf, 16); } else if (pContext->m_BlockOffset == 16) { uint8_t block_buf[16]; CRYPT_AESDecrypt(pContext->m_Context, block_buf, pContext->m_Block, 16); if (block_buf[15] <= 16) { dest_buf.AppendBlock(block_buf, 16 - block_buf[15]); } } FX_Free(pContext); return TRUE; } void* CPDF_StandardCryptoHandler::DecryptStart(FX_DWORD objnum, FX_DWORD gennum) { return CryptStart(objnum, gennum, FALSE); } FX_DWORD CPDF_StandardCryptoHandler::DecryptGetSize(FX_DWORD src_size) { return m_Cipher == FXCIPHER_AES ? src_size - 16 : src_size; } FX_BOOL CPDF_StandardCryptoHandler::Init(CPDF_Dictionary* pEncryptDict, CPDF_SecurityHandler* pSecurityHandler) { const uint8_t* key; if (!pSecurityHandler->GetCryptInfo(m_Cipher, key, m_KeyLen)) { return FALSE; } if (m_KeyLen > 32 || m_KeyLen < 0) { return FALSE; } if (m_Cipher != FXCIPHER_NONE) { FXSYS_memcpy32(m_EncryptKey, key, m_KeyLen); } if (m_Cipher == FXCIPHER_AES) { m_pAESContext = FX_Alloc(uint8_t, 2048); } return TRUE; } FX_BOOL CPDF_StandardCryptoHandler::Init(int cipher, const uint8_t* key, int keylen) { if (cipher == FXCIPHER_AES) { switch(keylen) { case 16: case 24: case 32: break; default: return FALSE; } } else if (cipher == FXCIPHER_AES2) { if (keylen != 32) { return FALSE; } } else if (cipher == FXCIPHER_RC4) { if (keylen < 5 || keylen > 16) { return FALSE; } } else { if (keylen > 32) { keylen = 32; } } m_Cipher = cipher; m_KeyLen = keylen; FXSYS_memcpy32(m_EncryptKey, key, keylen); if (m_Cipher == FXCIPHER_AES) { m_pAESContext = FX_Alloc(uint8_t, 2048); } return TRUE; } FX_BOOL CPDF_StandardCryptoHandler::DecryptStream(void* context, const uint8_t* src_buf, FX_DWORD src_size, CFX_BinaryBuf& dest_buf) { return CryptStream(context, src_buf, src_size, dest_buf, FALSE); } FX_BOOL CPDF_StandardCryptoHandler::DecryptFinish(void* context, CFX_BinaryBuf& dest_buf) { return CryptFinish(context, dest_buf, FALSE); } FX_DWORD CPDF_StandardCryptoHandler::EncryptGetSize(FX_DWORD objnum, FX_DWORD version, const uint8_t* src_buf, FX_DWORD src_size) { if (m_Cipher == FXCIPHER_AES) { return src_size + 32; } return src_size; } FX_BOOL CPDF_StandardCryptoHandler::EncryptContent(FX_DWORD objnum, FX_DWORD gennum, const uint8_t* src_buf, FX_DWORD src_size, uint8_t* dest_buf, FX_DWORD& dest_size) { CryptBlock(TRUE, objnum, gennum, src_buf, src_size, dest_buf, dest_size); return TRUE; } void CPDF_CryptoHandler::Decrypt(FX_DWORD objnum, FX_DWORD gennum, CFX_ByteString& str) { CFX_BinaryBuf dest_buf; void* context = DecryptStart(objnum, gennum); DecryptStream(context, (const uint8_t*)str, str.GetLength(), dest_buf); DecryptFinish(context, dest_buf); str = dest_buf; } CPDF_StandardCryptoHandler::CPDF_StandardCryptoHandler() { m_pAESContext = NULL; m_Cipher = FXCIPHER_NONE; m_KeyLen = 0; } CPDF_StandardCryptoHandler::~CPDF_StandardCryptoHandler() { if (m_pAESContext) { FX_Free(m_pAESContext); } }