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|
// 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 "core/fpdfapi/fpdf_parser/cpdf_security_handler.h"
#include <time.h>
#include "core/fdrm/crypto/include/fx_crypt.h"
#include "core/fpdfapi/fpdf_parser/cpdf_crypto_handler.h"
#include "core/fpdfapi/fpdf_parser/include/cpdf_array.h"
#include "core/fpdfapi/fpdf_parser/include/cpdf_dictionary.h"
#include "core/fpdfapi/fpdf_parser/include/cpdf_object.h"
#include "core/fpdfapi/fpdf_parser/include/cpdf_parser.h"
namespace {
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,
uint32_t pass_size,
uint8_t* key,
int keylen,
FX_BOOL bIgnoreMeta,
CPDF_Array* pIdArray) {
int revision = pEncrypt->GetIntegerBy("R");
uint8_t passcode[32];
for (uint32_t 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->GetStringBy("O");
CRYPT_MD5Update(md5, (uint8_t*)okey.c_str(), okey.GetLength());
uint32_t perm = pEncrypt->GetIntegerBy("P");
CRYPT_MD5Update(md5, (uint8_t*)&perm, 4);
if (pIdArray) {
CFX_ByteString id = pIdArray->GetStringAt(0);
CRYPT_MD5Update(md5, (uint8_t*)id.c_str(), id.GetLength());
}
if (!bIgnoreMeta && revision >= 3 &&
!pEncrypt->GetIntegerBy("EncryptMetadata", 1)) {
uint32_t tag = (uint32_t)-1;
CRYPT_MD5Update(md5, (uint8_t*)&tag, 4);
}
uint8_t digest[16];
CRYPT_MD5Finish(md5, digest);
uint32_t 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_memset(key, 0, keylen);
FXSYS_memcpy(key, digest, copy_len);
}
} // namespace
CPDF_SecurityHandler::CPDF_SecurityHandler() {
m_Version = 0;
m_Revision = 0;
m_pParser = NULL;
m_pEncryptDict = NULL;
m_Permissions = 0;
m_Cipher = FXCIPHER_NONE;
m_KeyLen = 0;
}
CPDF_SecurityHandler::~CPDF_SecurityHandler() {}
CPDF_CryptoHandler* CPDF_SecurityHandler::CreateCryptoHandler() {
return new CPDF_CryptoHandler;
}
FX_BOOL CPDF_SecurityHandler::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_SecurityHandler::CheckSecurity(int32_t key_len) {
CFX_ByteString password = m_pParser->GetPassword();
if (CheckPassword(password.raw_str(), password.GetLength(), TRUE,
m_EncryptKey, key_len)) {
if (password.IsEmpty()) {
if (!CheckPassword(password.raw_str(), password.GetLength(), FALSE,
m_EncryptKey, key_len)) {
return FALSE;
}
}
return TRUE;
}
return CheckPassword(password.raw_str(), password.GetLength(), FALSE,
m_EncryptKey, key_len);
}
uint32_t CPDF_SecurityHandler::GetPermissions() {
return m_Permissions;
}
static FX_BOOL LoadCryptInfo(CPDF_Dictionary* pEncryptDict,
const CFX_ByteString& name,
int& cipher,
int& keylen) {
int Version = pEncryptDict->GetIntegerBy("V");
cipher = FXCIPHER_RC4;
keylen = 0;
if (Version >= 4) {
CPDF_Dictionary* pCryptFilters = pEncryptDict->GetDictBy("CF");
if (!pCryptFilters) {
return FALSE;
}
if (name == "Identity") {
cipher = FXCIPHER_NONE;
} else {
CPDF_Dictionary* pDefFilter = pCryptFilters->GetDictBy(name);
if (!pDefFilter) {
return FALSE;
}
int nKeyBits = 0;
if (Version == 4) {
nKeyBits = pDefFilter->GetIntegerBy("Length", 0);
if (nKeyBits == 0) {
nKeyBits = pEncryptDict->GetIntegerBy("Length", 128);
}
} else {
nKeyBits = pEncryptDict->GetIntegerBy("Length", 256);
}
if (nKeyBits < 40) {
nKeyBits *= 8;
}
keylen = nKeyBits / 8;
CFX_ByteString cipher_name = pDefFilter->GetStringBy("CFM");
if (cipher_name == "AESV2" || cipher_name == "AESV3") {
cipher = FXCIPHER_AES;
}
}
} else {
keylen = Version > 1 ? pEncryptDict->GetIntegerBy("Length", 40) / 8 : 5;
}
if (keylen > 32 || keylen < 0) {
return FALSE;
}
return TRUE;
}
FX_BOOL CPDF_SecurityHandler::LoadDict(CPDF_Dictionary* pEncryptDict) {
m_pEncryptDict = pEncryptDict;
m_Version = pEncryptDict->GetIntegerBy("V");
m_Revision = pEncryptDict->GetIntegerBy("R");
m_Permissions = pEncryptDict->GetIntegerBy("P", -1);
if (m_Version < 4)
return LoadCryptInfo(pEncryptDict, CFX_ByteString(), m_Cipher, m_KeyLen);
CFX_ByteString stmf_name = pEncryptDict->GetStringBy("StmF");
CFX_ByteString strf_name = pEncryptDict->GetStringBy("StrF");
if (stmf_name != strf_name)
return FALSE;
return LoadCryptInfo(pEncryptDict, strf_name, m_Cipher, m_KeyLen);
}
FX_BOOL CPDF_SecurityHandler::LoadDict(CPDF_Dictionary* pEncryptDict,
uint32_t type,
int& cipher,
int& key_len) {
m_pEncryptDict = pEncryptDict;
m_Version = pEncryptDict->GetIntegerBy("V");
m_Revision = pEncryptDict->GetIntegerBy("R");
m_Permissions = pEncryptDict->GetIntegerBy("P", -1);
CFX_ByteString strf_name;
CFX_ByteString stmf_name;
if (m_Version >= 4) {
stmf_name = pEncryptDict->GetStringBy("StmF");
strf_name = pEncryptDict->GetStringBy("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;
}
FX_BOOL CPDF_SecurityHandler::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) = (uint32_t)( \
((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) {
uint32_t value;
FX_GET_32WORD(value, data, 4 * i);
ret <<= 32;
ret |= value;
ret %= 3;
}
return (int)ret;
}
void Revision6_Hash(const uint8_t* password,
uint32_t 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_memcpy(hash, input, 32);
}
}
FX_BOOL CPDF_SecurityHandler::AES256_CheckPassword(const uint8_t* password,
uint32_t size,
FX_BOOL bOwner,
uint8_t* key) {
CFX_ByteString okey =
m_pEncryptDict ? m_pEncryptDict->GetStringBy("O") : CFX_ByteString();
if (okey.GetLength() < 48) {
return FALSE;
}
CFX_ByteString ukey =
m_pEncryptDict ? m_pEncryptDict->GetStringBy("U") : CFX_ByteString();
if (ukey.GetLength() < 48) {
return FALSE;
}
const uint8_t* pkey = (bOwner ? okey : ukey).raw_str();
uint8_t sha[128];
uint8_t digest[32];
if (m_Revision >= 6) {
Revision6_Hash(password, size, (const uint8_t*)pkey + 32,
bOwner ? ukey.raw_str() : nullptr, digest);
} else {
CRYPT_SHA256Start(sha);
CRYPT_SHA256Update(sha, password, size);
CRYPT_SHA256Update(sha, pkey + 32, 8);
if (bOwner) {
CRYPT_SHA256Update(sha, ukey.raw_str(), 48);
}
CRYPT_SHA256Finish(sha, digest);
}
if (FXSYS_memcmp(digest, pkey, 32) != 0) {
return FALSE;
}
if (!key) {
return TRUE;
}
if (m_Revision >= 6) {
Revision6_Hash(password, size, (const uint8_t*)pkey + 40,
bOwner ? ukey.raw_str() : nullptr, digest);
} else {
CRYPT_SHA256Start(sha);
CRYPT_SHA256Update(sha, password, size);
CRYPT_SHA256Update(sha, pkey + 40, 8);
if (bOwner) {
CRYPT_SHA256Update(sha, ukey.raw_str(), 48);
}
CRYPT_SHA256Finish(sha, digest);
}
CFX_ByteString ekey = m_pEncryptDict
? m_pEncryptDict->GetStringBy(bOwner ? "OE" : "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_memset(iv, 0, 16);
CRYPT_AESSetIV(aes, iv);
CRYPT_AESDecrypt(aes, key, ekey.raw_str(), 32);
CRYPT_AESSetKey(aes, 16, key, 32, FALSE);
CRYPT_AESSetIV(aes, iv);
CFX_ByteString perms = m_pEncryptDict->GetStringBy("Perms");
if (perms.IsEmpty()) {
return FALSE;
}
uint8_t perms_buf[16];
FXSYS_memset(perms_buf, 0, sizeof(perms_buf));
uint32_t copy_len = sizeof(perms_buf);
if (copy_len > (uint32_t)perms.GetLength()) {
copy_len = perms.GetLength();
}
FXSYS_memcpy(perms_buf, perms.raw_str(), 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_SecurityHandler::CheckPassword(const uint8_t* password,
uint32_t 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) {
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_SecurityHandler::CheckUserPassword(const uint8_t* password,
uint32_t 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->GetStringBy("U") : CFX_ByteString();
if (ukey.GetLength() < 16) {
return FALSE;
}
uint8_t ukeybuf[32];
if (m_Revision == 2) {
FXSYS_memcpy(ukeybuf, defpasscode, 32);
CRYPT_ArcFourCryptBlock(ukeybuf, 32, key, key_len);
} else {
uint8_t test[32], tmpkey[32];
uint32_t copy_len = sizeof(test);
if (copy_len > (uint32_t)ukey.GetLength()) {
copy_len = ukey.GetLength();
}
FXSYS_memset(test, 0, sizeof(test));
FXSYS_memset(tmpkey, 0, sizeof(tmpkey));
FXSYS_memcpy(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->GetStringAt(0);
CRYPT_MD5Update(md5, (uint8_t*)id.c_str(), id.GetLength());
}
CRYPT_MD5Finish(md5, ukeybuf);
return FXSYS_memcmp(test, ukeybuf, 16) == 0;
}
if (FXSYS_memcmp((void*)ukey.c_str(), ukeybuf, 16) == 0) {
return TRUE;
}
return FALSE;
}
CFX_ByteString CPDF_SecurityHandler::GetUserPassword(const uint8_t* owner_pass,
uint32_t pass_size,
int32_t key_len) {
CFX_ByteString okey = m_pEncryptDict->GetStringBy("O");
uint8_t passcode[32];
uint32_t 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_memset(enckey, 0, sizeof(enckey));
uint32_t copy_len = key_len;
if (copy_len > sizeof(digest)) {
copy_len = sizeof(digest);
}
FXSYS_memcpy(enckey, digest, copy_len);
int okeylen = okey.GetLength();
if (okeylen > 32) {
okeylen = 32;
}
uint8_t okeybuf[64];
FXSYS_memset(okeybuf, 0, sizeof(okeybuf));
FXSYS_memcpy(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_memset(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_SecurityHandler::CheckOwnerPassword(const uint8_t* password,
uint32_t pass_size,
uint8_t* key,
int32_t key_len) {
CFX_ByteString user_pass = GetUserPassword(password, pass_size, key_len);
if (CheckUserPassword(user_pass.raw_str(), user_pass.GetLength(), FALSE, key,
key_len)) {
return TRUE;
}
return CheckUserPassword(user_pass.raw_str(), user_pass.GetLength(), TRUE,
key, key_len);
}
FX_BOOL CPDF_SecurityHandler::IsMetadataEncrypted() {
return m_pEncryptDict->GetBooleanBy("EncryptMetadata", TRUE);
}
void CPDF_SecurityHandler::OnCreate(CPDF_Dictionary* pEncryptDict,
CPDF_Array* pIdArray,
const uint8_t* user_pass,
uint32_t user_size,
const uint8_t* owner_pass,
uint32_t owner_size,
FX_BOOL bDefault,
uint32_t type) {
int cipher = 0, key_len = 0;
if (!LoadDict(pEncryptDict, type, cipher, key_len)) {
return;
}
if (bDefault && (!owner_pass || 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->GetBooleanBy("EncryptMetadata", TRUE),
m_EncryptKey);
}
return;
}
if (bDefault) {
uint8_t passcode[32];
uint32_t 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_memcpy(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("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_memcpy(tempbuf, defpasscode, 32);
CRYPT_ArcFourCryptBlock(tempbuf, 32, m_EncryptKey, key_len);
pEncryptDict->SetAtString("U", CFX_ByteString(tempbuf, 32));
} else {
uint8_t md5[100];
CRYPT_MD5Start(md5);
CRYPT_MD5Update(md5, defpasscode, 32);
if (pIdArray) {
CFX_ByteString id = pIdArray->GetStringAt(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("U", CFX_ByteString(digest, 32));
}
}
void CPDF_SecurityHandler::OnCreate(CPDF_Dictionary* pEncryptDict,
CPDF_Array* pIdArray,
const uint8_t* user_pass,
uint32_t user_size,
const uint8_t* owner_pass,
uint32_t owner_size,
uint32_t type) {
OnCreate(pEncryptDict, pIdArray, user_pass, user_size, owner_pass, owner_size,
TRUE, type);
}
void CPDF_SecurityHandler::OnCreate(CPDF_Dictionary* pEncryptDict,
CPDF_Array* pIdArray,
const uint8_t* user_pass,
uint32_t user_size,
uint32_t type) {
OnCreate(pEncryptDict, pIdArray, user_pass, user_size, NULL, 0, FALSE, type);
}
void CPDF_SecurityHandler::AES256_SetPassword(CPDF_Dictionary* pEncryptDict,
const uint8_t* password,
uint32_t 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->GetStringBy("U");
uint8_t digest1[48];
if (m_Revision >= 6) {
Revision6_Hash(password, size, digest, bOwner ? ukey.raw_str() : nullptr,
digest1);
} else {
CRYPT_SHA256Start(sha);
CRYPT_SHA256Update(sha, password, size);
CRYPT_SHA256Update(sha, digest, 8);
if (bOwner) {
CRYPT_SHA256Update(sha, ukey.raw_str(), ukey.GetLength());
}
CRYPT_SHA256Finish(sha, digest1);
}
FXSYS_memcpy(digest1 + 32, digest, 16);
pEncryptDict->SetAtString(bOwner ? "O" : "U", CFX_ByteString(digest1, 48));
if (m_Revision >= 6) {
Revision6_Hash(password, size, digest + 8,
bOwner ? ukey.raw_str() : nullptr, digest1);
} else {
CRYPT_SHA256Start(sha);
CRYPT_SHA256Update(sha, password, size);
CRYPT_SHA256Update(sha, digest + 8, 8);
if (bOwner) {
CRYPT_SHA256Update(sha, ukey.raw_str(), 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_memset(iv, 0, 16);
CRYPT_AESSetIV(aes, iv);
CRYPT_AESEncrypt(aes, digest1, key, 32);
FX_Free(aes);
pEncryptDict->SetAtString(bOwner ? "OE" : "UE", CFX_ByteString(digest1, 32));
}
void CPDF_SecurityHandler::AES256_SetPerms(CPDF_Dictionary* pEncryptDict,
uint32_t 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_memset(iv, 0, 16);
CRYPT_AESSetIV(aes, iv);
CRYPT_AESEncrypt(aes, buf1, buf, 16);
FX_Free(aes);
pEncryptDict->SetAtString("Perms", CFX_ByteString(buf1, 16));
}
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