// This file implements methods from the QPDF class that involve // encryption. #include #include #include #include #include #include #include #include #include #include #include #include #include static unsigned char const padding_string[] = { 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}; static unsigned int const key_bytes = 32; // V4 key lengths apply to V <= 4 static unsigned int const OU_key_bytes_V4 = sizeof(MD5::Digest); static unsigned int const OU_key_bytes_V5 = 48; static unsigned int const OUE_key_bytes_V5 = 32; static unsigned int const Perms_key_bytes_V5 = 16; int QPDF::EncryptionData::getV() const { return this->V; } int QPDF::EncryptionData::getR() const { return this->R; } int QPDF::EncryptionData::getLengthBytes() const { return this->Length_bytes; } int QPDF::EncryptionData::getP() const { return this->P; } std::string const& QPDF::EncryptionData::getO() const { return this->O; } std::string const& QPDF::EncryptionData::getU() const { return this->U; } std::string const& QPDF::EncryptionData::getOE() const { return this->OE; } std::string const& QPDF::EncryptionData::getUE() const { return this->UE; } std::string const& QPDF::EncryptionData::getPerms() const { return this->Perms; } std::string const& QPDF::EncryptionData::getId1() const { return this->id1; } bool QPDF::EncryptionData::getEncryptMetadata() const { return this->encrypt_metadata; } void QPDF::EncryptionData::setO(std::string const& O) { this->O = O; } void QPDF::EncryptionData::setU(std::string const& U) { this->U = U; } void QPDF::EncryptionData::setV5EncryptionParameters( std::string const& O, std::string const& OE, std::string const& U, std::string const& UE, std::string const& Perms) { this->O = O; this->OE = OE; this->U = U; this->UE = UE; this->Perms = Perms; } static void pad_or_truncate_password_V4(std::string const& password, char k1[key_bytes]) { size_t password_bytes = std::min(QIntC::to_size(key_bytes), password.length()); size_t pad_bytes = key_bytes - password_bytes; memcpy(k1, password.c_str(), password_bytes); memcpy(k1 + password_bytes, padding_string, pad_bytes); } void QPDF::trim_user_password(std::string& user_password) { // Although unnecessary, this routine trims the padding string from the end of a user password. // Its only purpose is for recovery of user passwords which is done in the test suite. char const* cstr = user_password.c_str(); size_t len = user_password.length(); if (len < key_bytes) { return; } char const* p1 = cstr; char const* p2 = nullptr; while ((p2 = strchr(p1, '\x28')) != nullptr) { size_t idx = toS(p2 - cstr); if (memcmp(p2, padding_string, len - idx) == 0) { user_password = user_password.substr(0, idx); return; } else { QTC::TC("qpdf", "QPDF_encryption skip 0x28"); p1 = p2 + 1; } } } static std::string pad_or_truncate_password_V4(std::string const& password) { char k1[key_bytes]; pad_or_truncate_password_V4(password, k1); return {k1, key_bytes}; } static std::string truncate_password_V5(std::string const& password) { return password.substr(0, std::min(static_cast(127), password.length())); } static void iterate_md5_digest(MD5& md5, MD5::Digest& digest, int iterations, int key_len) { md5.digest(digest); for (int i = 0; i < iterations; ++i) { MD5 m; m.encodeDataIncrementally(reinterpret_cast(digest), QIntC::to_size(key_len)); m.digest(digest); } } static void iterate_rc4( unsigned char* data, size_t data_len, unsigned char* okey, int key_len, int iterations, bool reverse) { auto key_ph = std::make_unique(QIntC::to_size(key_len)); unsigned char* key = key_ph.get(); for (int i = 0; i < iterations; ++i) { int const xor_value = (reverse ? iterations - 1 - i : i); for (int j = 0; j < key_len; ++j) { key[j] = static_cast(okey[j] ^ xor_value); } RC4 rc4(key, QIntC::to_int(key_len)); rc4.process(data, data_len, data); } } static std::string process_with_aes( std::string const& key, bool encrypt, std::string const& data, size_t outlength = 0, unsigned int repetitions = 1, unsigned char const* iv = nullptr, size_t iv_length = 0) { Pl_Buffer buffer("buffer"); Pl_AES_PDF aes( "aes", &buffer, encrypt, QUtil::unsigned_char_pointer(key), QIntC::to_uint(key.length())); if (iv) { aes.setIV(iv, iv_length); } else { aes.useZeroIV(); } aes.disablePadding(); for (unsigned int i = 0; i < repetitions; ++i) { aes.writeString(data); } aes.finish(); if (outlength == 0) { return buffer.getString(); } else { return buffer.getString().substr(0, outlength); } } static std::string hash_V5( std::string const& password, std::string const& salt, std::string const& udata, QPDF::EncryptionData const& data) { Pl_SHA2 hash(256); hash.writeString(password); hash.writeString(salt); hash.writeString(udata); hash.finish(); std::string K = hash.getRawDigest(); std::string result; if (data.getR() < 6) { result = K; } else { // Algorithm 2.B from ISO 32000-1 chapter 7: Computing a hash int round_number = 0; bool done = false; while (!done) { // The hash algorithm has us setting K initially to the R5 value and then repeating a // series of steps 64 times before starting with the termination case testing. The // wording of the specification is very unclear as to the exact number of times it // should be run since the wording about whether the initial setup counts as round 0 or // not is ambiguous. This code counts the initial setup (R5) value as round 0, which // appears to be correct. This was determined to be correct by increasing or decreasing // the number of rounds by 1 or 2 from this value and generating 20 test files. In this // interpretation, all the test files worked with Adobe Reader X. In the other // configurations, many of the files did not work, and we were accurately able to // predict which files didn't work by looking at the conditions under which we // terminated repetition. ++round_number; std::string K1 = password + K + udata; qpdf_assert_debug(K.length() >= 32); std::string E = process_with_aes( K.substr(0, 16), true, K1, 0, 64, QUtil::unsigned_char_pointer(K.substr(16, 16)), 16); // E_mod_3 is supposed to be mod 3 of the first 16 bytes of E taken as as a (128-bit) // big-endian number. Since (xy mod n) is equal to ((x mod n) + (y mod n)) mod n and // since 256 mod n is 1, we can just take the sums of the the mod 3s of each byte to get // the same result. int E_mod_3 = 0; for (unsigned int i = 0; i < 16; ++i) { E_mod_3 += static_cast(E.at(i)); } E_mod_3 %= 3; int next_hash = ((E_mod_3 == 0) ? 256 : (E_mod_3 == 1) ? 384 : 512); Pl_SHA2 sha2(next_hash); sha2.writeString(E); sha2.finish(); K = sha2.getRawDigest(); if (round_number >= 64) { unsigned int ch = static_cast(*(E.rbegin())); if (ch <= QIntC::to_uint(round_number - 32)) { done = true; } } } result = K.substr(0, 32); } return result; } static void pad_short_parameter(std::string& param, size_t max_len) { if (param.length() < max_len) { QTC::TC("qpdf", "QPDF_encryption pad short parameter"); param.append(max_len - param.length(), '\0'); } } std::string QPDF::compute_data_key( std::string const& encryption_key, int objid, int generation, bool use_aes, int encryption_V, int encryption_R) { // Algorithm 3.1 from the PDF 1.7 Reference Manual std::string result = encryption_key; if (encryption_V >= 5) { // Algorithm 3.1a (PDF 1.7 extension level 3): just use encryption key straight. return result; } // Append low three bytes of object ID and low two bytes of generation result.append(1, static_cast(objid & 0xff)); result.append(1, static_cast((objid >> 8) & 0xff)); result.append(1, static_cast((objid >> 16) & 0xff)); result.append(1, static_cast(generation & 0xff)); result.append(1, static_cast((generation >> 8) & 0xff)); if (use_aes) { result += "sAlT"; } MD5 md5; md5.encodeDataIncrementally(result.c_str(), result.length()); MD5::Digest digest; md5.digest(digest); return {reinterpret_cast(digest), std::min(result.length(), toS(16))}; } std::string QPDF::compute_encryption_key(std::string const& password, EncryptionData const& data) { if (data.getV() >= 5) { // For V >= 5, the encryption key is generated and stored in the file, encrypted separately // with both user and owner passwords. return recover_encryption_key_with_password(password, data); } else { // For V < 5, the encryption key is derived from the user // password. return compute_encryption_key_from_password(password, data); } } std::string QPDF::compute_encryption_key_from_password(std::string const& password, EncryptionData const& data) { // Algorithm 3.2 from the PDF 1.7 Reference Manual // This code does not properly handle Unicode passwords. Passwords are supposed to be converted // from OS codepage characters to PDFDocEncoding. Unicode passwords are supposed to be // converted to OS codepage before converting to PDFDocEncoding. We instead require the // password to be presented in its final form. MD5 md5; md5.encodeDataIncrementally(pad_or_truncate_password_V4(password).c_str(), key_bytes); md5.encodeDataIncrementally(data.getO().c_str(), key_bytes); char pbytes[4]; int P = data.getP(); pbytes[0] = static_cast(P & 0xff); pbytes[1] = static_cast((P >> 8) & 0xff); pbytes[2] = static_cast((P >> 16) & 0xff); pbytes[3] = static_cast((P >> 24) & 0xff); md5.encodeDataIncrementally(pbytes, 4); md5.encodeDataIncrementally(data.getId1().c_str(), data.getId1().length()); if ((data.getR() >= 4) && (!data.getEncryptMetadata())) { char bytes[4]; memset(bytes, 0xff, 4); md5.encodeDataIncrementally(bytes, 4); } MD5::Digest digest; int key_len = std::min(toI(sizeof(digest)), data.getLengthBytes()); iterate_md5_digest(md5, digest, ((data.getR() >= 3) ? 50 : 0), key_len); return {reinterpret_cast(digest), toS(key_len)}; } static void compute_O_rc4_key( std::string const& user_password, std::string const& owner_password, QPDF::EncryptionData const& data, unsigned char key[OU_key_bytes_V4]) { if (data.getV() >= 5) { throw std::logic_error("compute_O_rc4_key called for file with V >= 5"); } std::string password = owner_password; if (password.empty()) { password = user_password; } MD5 md5; md5.encodeDataIncrementally(pad_or_truncate_password_V4(password).c_str(), key_bytes); MD5::Digest digest; int key_len = std::min(QIntC::to_int(sizeof(digest)), data.getLengthBytes()); iterate_md5_digest(md5, digest, ((data.getR() >= 3) ? 50 : 0), key_len); memcpy(key, digest, OU_key_bytes_V4); } static std::string compute_O_value( std::string const& user_password, std::string const& owner_password, QPDF::EncryptionData const& data) { // Algorithm 3.3 from the PDF 1.7 Reference Manual unsigned char O_key[OU_key_bytes_V4]; compute_O_rc4_key(user_password, owner_password, data, O_key); char upass[key_bytes]; pad_or_truncate_password_V4(user_password, upass); std::string k1(reinterpret_cast(O_key), OU_key_bytes_V4); pad_short_parameter(k1, QIntC::to_size(data.getLengthBytes())); iterate_rc4( QUtil::unsigned_char_pointer(upass), key_bytes, O_key, data.getLengthBytes(), (data.getR() >= 3) ? 20 : 1, false); return {upass, key_bytes}; } static std::string compute_U_value_R2(std::string const& user_password, QPDF::EncryptionData const& data) { // Algorithm 3.4 from the PDF 1.7 Reference Manual std::string k1 = QPDF::compute_encryption_key(user_password, data); char udata[key_bytes]; pad_or_truncate_password_V4("", udata); pad_short_parameter(k1, QIntC::to_size(data.getLengthBytes())); iterate_rc4( QUtil::unsigned_char_pointer(udata), key_bytes, QUtil::unsigned_char_pointer(k1), data.getLengthBytes(), 1, false); return {udata, key_bytes}; } static std::string compute_U_value_R3(std::string const& user_password, QPDF::EncryptionData const& data) { // Algorithm 3.5 from the PDF 1.7 Reference Manual std::string k1 = QPDF::compute_encryption_key(user_password, data); MD5 md5; md5.encodeDataIncrementally(pad_or_truncate_password_V4("").c_str(), key_bytes); md5.encodeDataIncrementally(data.getId1().c_str(), data.getId1().length()); MD5::Digest digest; md5.digest(digest); pad_short_parameter(k1, QIntC::to_size(data.getLengthBytes())); iterate_rc4( digest, sizeof(MD5::Digest), QUtil::unsigned_char_pointer(k1), data.getLengthBytes(), 20, false); char result[key_bytes]; memcpy(result, digest, sizeof(MD5::Digest)); // pad with arbitrary data -- make it consistent for the sake of // testing for (unsigned int i = sizeof(MD5::Digest); i < key_bytes; ++i) { result[i] = static_cast((i * i) % 0xff); } return {result, key_bytes}; } static std::string compute_U_value(std::string const& user_password, QPDF::EncryptionData const& data) { if (data.getR() >= 3) { return compute_U_value_R3(user_password, data); } return compute_U_value_R2(user_password, data); } static bool check_user_password_V4(std::string const& user_password, QPDF::EncryptionData const& data) { // Algorithm 3.6 from the PDF 1.7 Reference Manual std::string u_value = compute_U_value(user_password, data); size_t to_compare = ((data.getR() >= 3) ? sizeof(MD5::Digest) : key_bytes); return (memcmp(data.getU().c_str(), u_value.c_str(), to_compare) == 0); } static bool check_user_password_V5(std::string const& user_password, QPDF::EncryptionData const& data) { // Algorithm 3.11 from the PDF 1.7 extension level 3 std::string user_data = data.getU().substr(0, 32); std::string validation_salt = data.getU().substr(32, 8); std::string password = truncate_password_V5(user_password); return (hash_V5(password, validation_salt, "", data) == user_data); } static bool check_user_password(std::string const& user_password, QPDF::EncryptionData const& data) { if (data.getV() < 5) { return check_user_password_V4(user_password, data); } else { return check_user_password_V5(user_password, data); } } static bool check_owner_password_V4( std::string& user_password, std::string const& owner_password, QPDF::EncryptionData const& data) { // Algorithm 3.7 from the PDF 1.7 Reference Manual unsigned char key[OU_key_bytes_V4]; compute_O_rc4_key(user_password, owner_password, data, key); unsigned char O_data[key_bytes]; memcpy(O_data, QUtil::unsigned_char_pointer(data.getO()), key_bytes); std::string k1(reinterpret_cast(key), OU_key_bytes_V4); pad_short_parameter(k1, QIntC::to_size(data.getLengthBytes())); iterate_rc4( O_data, key_bytes, QUtil::unsigned_char_pointer(k1), data.getLengthBytes(), (data.getR() >= 3) ? 20 : 1, true); std::string new_user_password = std::string(reinterpret_cast(O_data), key_bytes); bool result = false; if (check_user_password(new_user_password, data)) { result = true; user_password = new_user_password; } return result; } static bool check_owner_password_V5(std::string const& owner_password, QPDF::EncryptionData const& data) { // Algorithm 3.12 from the PDF 1.7 extension level 3 std::string user_data = data.getU().substr(0, 48); std::string owner_data = data.getO().substr(0, 32); std::string validation_salt = data.getO().substr(32, 8); std::string password = truncate_password_V5(owner_password); return (hash_V5(password, validation_salt, user_data, data) == owner_data); } static bool check_owner_password( std::string& user_password, std::string const& owner_password, QPDF::EncryptionData const& data) { if (data.getV() < 5) { return check_owner_password_V4(user_password, owner_password, data); } else { return check_owner_password_V5(owner_password, data); } } std::string QPDF::recover_encryption_key_with_password(std::string const& password, EncryptionData const& data) { // Disregard whether Perms is valid. bool disregard; return recover_encryption_key_with_password(password, data, disregard); } static void compute_U_UE_value_V5( std::string const& user_password, std::string const& encryption_key, QPDF::EncryptionData const& data, std::string& U, std::string& UE) { // Algorithm 3.8 from the PDF 1.7 extension level 3 char k[16]; QUtil::initializeWithRandomBytes(reinterpret_cast(k), sizeof(k)); std::string validation_salt(k, 8); std::string key_salt(k + 8, 8); U = hash_V5(user_password, validation_salt, "", data) + validation_salt + key_salt; std::string intermediate_key = hash_V5(user_password, key_salt, "", data); UE = process_with_aes(intermediate_key, true, encryption_key); } static void compute_O_OE_value_V5( std::string const& owner_password, std::string const& encryption_key, QPDF::EncryptionData const& data, std::string const& U, std::string& O, std::string& OE) { // Algorithm 3.9 from the PDF 1.7 extension level 3 char k[16]; QUtil::initializeWithRandomBytes(reinterpret_cast(k), sizeof(k)); std::string validation_salt(k, 8); std::string key_salt(k + 8, 8); O = hash_V5(owner_password, validation_salt, U, data) + validation_salt + key_salt; std::string intermediate_key = hash_V5(owner_password, key_salt, U, data); OE = process_with_aes(intermediate_key, true, encryption_key); } void compute_Perms_value_V5_clear( std::string const& encryption_key, QPDF::EncryptionData const& data, unsigned char k[16]) { // From algorithm 3.10 from the PDF 1.7 extension level 3 unsigned long long extended_perms = 0xffffffff00000000LL | static_cast(data.getP()); for (int i = 0; i < 8; ++i) { k[i] = static_cast(extended_perms & 0xff); extended_perms >>= 8; } k[8] = data.getEncryptMetadata() ? 'T' : 'F'; k[9] = 'a'; k[10] = 'd'; k[11] = 'b'; QUtil::initializeWithRandomBytes(k + 12, 4); } static std::string compute_Perms_value_V5(std::string const& encryption_key, QPDF::EncryptionData const& data) { // Algorithm 3.10 from the PDF 1.7 extension level 3 unsigned char k[16]; compute_Perms_value_V5_clear(encryption_key, data, k); return process_with_aes( encryption_key, true, std::string(reinterpret_cast(k), sizeof(k))); } std::string QPDF::recover_encryption_key_with_password( std::string const& password, EncryptionData const& data, bool& perms_valid) { // Algorithm 3.2a from the PDF 1.7 extension level 3 // This code does not handle Unicode passwords correctly. Empirical evidence suggests that most // viewers don't. We are supposed to process the input string with the SASLprep (RFC 4013) // profile of stringprep (RFC 3454) and then convert the result to UTF-8. perms_valid = false; std::string key_password = truncate_password_V5(password); std::string key_salt; std::string user_data; std::string encrypted_file_key; if (check_owner_password_V5(key_password, data)) { key_salt = data.getO().substr(40, 8); user_data = data.getU().substr(0, 48); encrypted_file_key = data.getOE().substr(0, 32); } else if (check_user_password_V5(key_password, data)) { key_salt = data.getU().substr(40, 8); encrypted_file_key = data.getUE().substr(0, 32); } std::string intermediate_key = hash_V5(key_password, key_salt, user_data, data); std::string file_key = process_with_aes(intermediate_key, false, encrypted_file_key); // Decrypt Perms and check against expected value std::string perms_check = process_with_aes(file_key, false, data.getPerms(), 12); unsigned char k[16]; compute_Perms_value_V5_clear(file_key, data, k); perms_valid = (memcmp(perms_check.c_str(), k, 12) == 0); return file_key; } QPDF::encryption_method_e QPDF::interpretCF(std::shared_ptr encp, QPDFObjectHandle cf) { if (cf.isName()) { std::string filter = cf.getName(); if (encp->crypt_filters.count(filter) != 0) { return encp->crypt_filters[filter]; } else if (filter == "/Identity") { return e_none; } else { return e_unknown; } } else { // Default: /Identity return e_none; } } void QPDF::initializeEncryption() { if (m->encp->encryption_initialized) { return; } m->encp->encryption_initialized = true; // After we initialize encryption parameters, we must use stored key information and never look // at /Encrypt again. Otherwise, things could go wrong if someone mutates the encryption // dictionary. if (!m->xref_table.trailer().hasKey("/Encrypt")) { return; } // Go ahead and set m->encrypted here. That way, isEncrypted will return true even if there // were errors reading the encryption dictionary. m->encp->encrypted = true; std::string id1; QPDFObjectHandle id_obj = m->xref_table.trailer().getKey("/ID"); if ((id_obj.isArray() && (id_obj.getArrayNItems() == 2) && id_obj.getArrayItem(0).isString())) { id1 = id_obj.getArrayItem(0).getStringValue(); } else { // Treating a missing ID as the empty string enables qpdf to decrypt some invalid encrypted // files with no /ID that poppler can read but Adobe Reader can't. warn(damagedPDF("trailer", "invalid /ID in trailer dictionary")); } QPDFObjectHandle encryption_dict = m->xref_table.trailer().getKey("/Encrypt"); if (!encryption_dict.isDictionary()) { throw damagedPDF("/Encrypt in trailer dictionary is not a dictionary"); } if (!(encryption_dict.getKey("/Filter").isName() && (encryption_dict.getKey("/Filter").getName() == "/Standard"))) { throw QPDFExc( qpdf_e_unsupported, m->file->getName(), "encryption dictionary", m->file->getLastOffset(), "unsupported encryption filter"); } if (!encryption_dict.getKey("/SubFilter").isNull()) { warn( qpdf_e_unsupported, "encryption dictionary", m->file->getLastOffset(), "file uses encryption SubFilters, which qpdf does not support"); } if (!(encryption_dict.getKey("/V").isInteger() && encryption_dict.getKey("/R").isInteger() && encryption_dict.getKey("/O").isString() && encryption_dict.getKey("/U").isString() && encryption_dict.getKey("/P").isInteger())) { throw damagedPDF( "encryption dictionary", "some encryption dictionary parameters are missing or the wrong " "type"); } int V = encryption_dict.getKey("/V").getIntValueAsInt(); int R = encryption_dict.getKey("/R").getIntValueAsInt(); std::string O = encryption_dict.getKey("/O").getStringValue(); std::string U = encryption_dict.getKey("/U").getStringValue(); int P = static_cast(encryption_dict.getKey("/P").getIntValue()); // If supporting new encryption R/V values, remember to update error message inside this if // statement. if (!(((R >= 2) && (R <= 6)) && ((V == 1) || (V == 2) || (V == 4) || (V == 5)))) { throw QPDFExc( qpdf_e_unsupported, m->file->getName(), "encryption dictionary", m->file->getLastOffset(), "Unsupported /R or /V in encryption dictionary; R = " + std::to_string(R) + " (max 6), V = " + std::to_string(V) + " (max 5)"); } m->encp->encryption_V = V; m->encp->encryption_R = R; // OE, UE, and Perms are only present if V >= 5. std::string OE; std::string UE; std::string Perms; if (V < 5) { // These must be exactly the right number of bytes. pad_short_parameter(O, key_bytes); pad_short_parameter(U, key_bytes); if (!((O.length() == key_bytes) && (U.length() == key_bytes))) { throw damagedPDF( "encryption dictionary", "incorrect length for /O and/or /U in encryption dictionary"); } } else { if (!(encryption_dict.getKey("/OE").isString() && encryption_dict.getKey("/UE").isString() && encryption_dict.getKey("/Perms").isString())) { throw damagedPDF( "encryption dictionary", "some V=5 encryption dictionary parameters are missing or the " "wrong type"); } OE = encryption_dict.getKey("/OE").getStringValue(); UE = encryption_dict.getKey("/UE").getStringValue(); Perms = encryption_dict.getKey("/Perms").getStringValue(); // These may be longer than the minimum number of bytes. pad_short_parameter(O, OU_key_bytes_V5); pad_short_parameter(U, OU_key_bytes_V5); pad_short_parameter(OE, OUE_key_bytes_V5); pad_short_parameter(UE, OUE_key_bytes_V5); pad_short_parameter(Perms, Perms_key_bytes_V5); } int Length = 0; if (V <= 1) { Length = 40; } else if (V == 4) { Length = 128; } else if (V == 5) { Length = 256; } else { if (encryption_dict.getKey("/Length").isInteger()) { Length = encryption_dict.getKey("/Length").getIntValueAsInt(); if ((Length % 8) || (Length < 40) || (Length > 128)) { Length = 0; } } } if (Length == 0) { // Still no Length? Just take a guess. Length = 128; } m->encp->encrypt_metadata = true; if ((V >= 4) && (encryption_dict.getKey("/EncryptMetadata").isBool())) { m->encp->encrypt_metadata = encryption_dict.getKey("/EncryptMetadata").getBoolValue(); } if ((V == 4) || (V == 5)) { QPDFObjectHandle CF = encryption_dict.getKey("/CF"); for (auto const& filter: CF.getKeys()) { QPDFObjectHandle cdict = CF.getKey(filter); if (cdict.isDictionary()) { encryption_method_e method = e_none; if (cdict.getKey("/CFM").isName()) { std::string method_name = cdict.getKey("/CFM").getName(); if (method_name == "/V2") { QTC::TC("qpdf", "QPDF_encryption CFM V2"); method = e_rc4; } else if (method_name == "/AESV2") { QTC::TC("qpdf", "QPDF_encryption CFM AESV2"); method = e_aes; } else if (method_name == "/AESV3") { QTC::TC("qpdf", "QPDF_encryption CFM AESV3"); method = e_aesv3; } else { // Don't complain now -- maybe we won't need to reference this type. method = e_unknown; } } m->encp->crypt_filters[filter] = method; } } QPDFObjectHandle StmF = encryption_dict.getKey("/StmF"); QPDFObjectHandle StrF = encryption_dict.getKey("/StrF"); QPDFObjectHandle EFF = encryption_dict.getKey("/EFF"); m->encp->cf_stream = interpretCF(m->encp, StmF); m->encp->cf_string = interpretCF(m->encp, StrF); if (EFF.isName()) { // qpdf does not use this for anything other than informational purposes. This is // intended to instruct conforming writers on which crypt filter should be used when new // file attachments are added to a PDF file, but qpdf never generates encrypted files // with non-default crypt filters. Prior to 10.2, I was under the mistaken impression // that this was supposed to be used for decrypting attachments, but the code was wrong // in a way that turns out not to have mattered because no writers were generating files // the way I was imagining. Still, providing this information could be useful when // looking at a file generated by something else, such as Acrobat when specifying that // only attachments should be encrypted. m->encp->cf_file = interpretCF(m->encp, EFF); } else { m->encp->cf_file = m->encp->cf_stream; } } EncryptionData data(V, R, Length / 8, P, O, U, OE, UE, Perms, id1, m->encp->encrypt_metadata); if (m->provided_password_is_hex_key) { // ignore passwords in file } else { m->encp->owner_password_matched = check_owner_password(m->encp->user_password, m->encp->provided_password, data); if (m->encp->owner_password_matched && (V < 5)) { // password supplied was owner password; user_password has been initialized for V < 5 if (getTrimmedUserPassword() == m->encp->provided_password) { m->encp->user_password_matched = true; QTC::TC("qpdf", "QPDF_encryption user matches owner V < 5"); } } else { m->encp->user_password_matched = check_user_password(m->encp->provided_password, data); if (m->encp->user_password_matched) { m->encp->user_password = m->encp->provided_password; } } if (m->encp->user_password_matched && m->encp->owner_password_matched) { QTC::TC("qpdf", "QPDF_encryption same password", (V < 5) ? 0 : 1); } if (!(m->encp->owner_password_matched || m->encp->user_password_matched)) { throw QPDFExc(qpdf_e_password, m->file->getName(), "", 0, "invalid password"); } } if (m->provided_password_is_hex_key) { m->encp->encryption_key = QUtil::hex_decode(m->encp->provided_password); } else if (V < 5) { // For V < 5, the user password is encrypted with the owner password, and the user password // is always used for computing the encryption key. m->encp->encryption_key = compute_encryption_key(m->encp->user_password, data); } else { // For V >= 5, either password can be used independently to compute the encryption key, and // neither password can be used to recover the other. bool perms_valid; m->encp->encryption_key = recover_encryption_key_with_password(m->encp->provided_password, data, perms_valid); if (!perms_valid) { warn(damagedPDF( "encryption dictionary", "/Perms field in encryption dictionary doesn't match expected " "value")); } } } std::string QPDF::getKeyForObject( std::shared_ptr encp, QPDFObjGen const& og, bool use_aes) { if (!encp->encrypted) { throw std::logic_error("request for encryption key in non-encrypted PDF"); } if (og != encp->cached_key_og) { encp->cached_object_encryption_key = compute_data_key( encp->encryption_key, og.getObj(), og.getGen(), use_aes, encp->encryption_V, encp->encryption_R); encp->cached_key_og = og; } return encp->cached_object_encryption_key; } void QPDF::decryptString(std::string& str, QPDFObjGen const& og) { if (!og.isIndirect()) { return; } bool use_aes = false; if (m->encp->encryption_V >= 4) { switch (m->encp->cf_string) { case e_none: return; case e_aes: use_aes = true; break; case e_aesv3: use_aes = true; break; case e_rc4: break; default: warn(damagedPDF("unknown encryption filter for strings (check /StrF in " "/Encrypt dictionary); strings may be decrypted improperly")); // To avoid repeated warnings, reset cf_string. Assume we'd want to use AES if V == 4. m->encp->cf_string = e_aes; use_aes = true; break; } } std::string key = getKeyForObject(m->encp, og, use_aes); try { if (use_aes) { QTC::TC("qpdf", "QPDF_encryption aes decode string"); Pl_Buffer bufpl("decrypted string"); Pl_AES_PDF pl( "aes decrypt string", &bufpl, false, QUtil::unsigned_char_pointer(key), key.length()); pl.writeString(str); pl.finish(); str = bufpl.getString(); } else { QTC::TC("qpdf", "QPDF_encryption rc4 decode string"); size_t vlen = str.length(); // Using std::shared_ptr guarantees that tmp will be freed even if rc4.process throws an // exception. auto tmp = QUtil::make_unique_cstr(str); RC4 rc4(QUtil::unsigned_char_pointer(key), toI(key.length())); auto data = QUtil::unsigned_char_pointer(tmp.get()); rc4.process(data, vlen, data); str = std::string(tmp.get(), vlen); } } catch (QPDFExc&) { throw; } catch (std::runtime_error& e) { throw damagedPDF("error decrypting string for object " + og.unparse() + ": " + e.what()); } } // Prepend a decryption pipeline to 'pipeline'. The decryption pipeline (returned as // 'decrypt_pipeline' must be owned by the caller to ensure that it stays alive while the pipeline // is in use. void QPDF::decryptStream( std::shared_ptr encp, std::shared_ptr file, QPDF& qpdf_for_warning, Pipeline*& pipeline, QPDFObjGen const& og, QPDFObjectHandle& stream_dict, std::unique_ptr& decrypt_pipeline) { std::string type; if (stream_dict.getKey("/Type").isName()) { type = stream_dict.getKey("/Type").getName(); } if (type == "/XRef") { QTC::TC("qpdf", "QPDF_encryption xref stream from encrypted file"); return; } bool use_aes = false; if (encp->encryption_V >= 4) { encryption_method_e method = e_unknown; std::string method_source = "/StmF from /Encrypt dictionary"; if (stream_dict.getKey("/Filter").isOrHasName("/Crypt")) { if (stream_dict.getKey("/DecodeParms").isDictionary()) { QPDFObjectHandle decode_parms = stream_dict.getKey("/DecodeParms"); if (decode_parms.isDictionaryOfType("/CryptFilterDecodeParms")) { QTC::TC("qpdf", "QPDF_encryption stream crypt filter"); method = interpretCF(encp, decode_parms.getKey("/Name")); method_source = "stream's Crypt decode parameters"; } } else if ( stream_dict.getKey("/DecodeParms").isArray() && stream_dict.getKey("/Filter").isArray()) { QPDFObjectHandle filter = stream_dict.getKey("/Filter"); QPDFObjectHandle decode = stream_dict.getKey("/DecodeParms"); if (filter.getArrayNItems() == decode.getArrayNItems()) { for (int i = 0; i < filter.getArrayNItems(); ++i) { if (filter.getArrayItem(i).isNameAndEquals("/Crypt")) { QPDFObjectHandle crypt_params = decode.getArrayItem(i); if (crypt_params.isDictionary() && crypt_params.getKey("/Name").isName()) { QTC::TC("qpdf", "QPDF_encrypt crypt array"); method = interpretCF(encp, crypt_params.getKey("/Name")); method_source = "stream's Crypt decode parameters (array)"; } } } } } } if (method == e_unknown) { if ((!encp->encrypt_metadata) && (type == "/Metadata")) { QTC::TC("qpdf", "QPDF_encryption cleartext metadata"); method = e_none; } else { method = encp->cf_stream; } } use_aes = false; switch (method) { case e_none: return; break; case e_aes: use_aes = true; break; case e_aesv3: use_aes = true; break; case e_rc4: break; default: // filter local to this stream. qpdf_for_warning.warn(QPDFExc( qpdf_e_damaged_pdf, file->getName(), "", file->getLastOffset(), "unknown encryption filter for streams (check " + method_source + "); streams may be decrypted improperly")); // To avoid repeated warnings, reset cf_stream. Assume we'd want to use AES if V == 4. encp->cf_stream = e_aes; use_aes = true; break; } } std::string key = getKeyForObject(encp, og, use_aes); if (use_aes) { QTC::TC("qpdf", "QPDF_encryption aes decode stream"); decrypt_pipeline = std::make_unique( "AES stream decryption", pipeline, false, QUtil::unsigned_char_pointer(key), key.length()); } else { QTC::TC("qpdf", "QPDF_encryption rc4 decode stream"); decrypt_pipeline = std::make_unique( "RC4 stream decryption", pipeline, QUtil::unsigned_char_pointer(key), toI(key.length())); } pipeline = decrypt_pipeline.get(); } void QPDF::compute_encryption_O_U( char const* user_password, char const* owner_password, int V, int R, int key_len, int P, bool encrypt_metadata, std::string const& id1, std::string& O, std::string& U) { if (V >= 5) { throw std::logic_error("compute_encryption_O_U called for file with V >= 5"); } EncryptionData data(V, R, key_len, P, "", "", "", "", "", id1, encrypt_metadata); data.setO(compute_O_value(user_password, owner_password, data)); O = data.getO(); data.setU(compute_U_value(user_password, data)); U = data.getU(); } void QPDF::compute_encryption_parameters_V5( char const* user_password, char const* owner_password, int V, int R, int key_len, int P, bool encrypt_metadata, std::string const& id1, std::string& encryption_key, std::string& O, std::string& U, std::string& OE, std::string& UE, std::string& Perms) { EncryptionData data(V, R, key_len, P, "", "", "", "", "", id1, encrypt_metadata); unsigned char k[key_bytes]; QUtil::initializeWithRandomBytes(k, key_bytes); encryption_key = std::string(reinterpret_cast(k), key_bytes); compute_U_UE_value_V5(user_password, encryption_key, data, U, UE); compute_O_OE_value_V5(owner_password, encryption_key, data, U, O, OE); Perms = compute_Perms_value_V5(encryption_key, data); data.setV5EncryptionParameters(O, OE, U, UE, Perms); } std::string const& QPDF::getPaddedUserPassword() const { return m->encp->user_password; } std::string QPDF::getTrimmedUserPassword() const { std::string result = m->encp->user_password; trim_user_password(result); return result; } std::string QPDF::getEncryptionKey() const { return m->encp->encryption_key; } bool QPDF::isEncrypted() const { return m->encp->encrypted; } bool QPDF::isEncrypted(int& R, int& P) { int V; encryption_method_e stream, string, file; return isEncrypted(R, P, V, stream, string, file); } bool QPDF::isEncrypted( int& R, int& P, int& V, encryption_method_e& stream_method, encryption_method_e& string_method, encryption_method_e& file_method) { if (m->encp->encrypted) { QPDFObjectHandle trailer = getTrailer(); QPDFObjectHandle encrypt = trailer.getKey("/Encrypt"); QPDFObjectHandle Pkey = encrypt.getKey("/P"); QPDFObjectHandle Rkey = encrypt.getKey("/R"); QPDFObjectHandle Vkey = encrypt.getKey("/V"); P = static_cast(Pkey.getIntValue()); R = Rkey.getIntValueAsInt(); V = Vkey.getIntValueAsInt(); stream_method = m->encp->cf_stream; string_method = m->encp->cf_string; file_method = m->encp->cf_file; return true; } else { return false; } } bool QPDF::ownerPasswordMatched() const { return m->encp->owner_password_matched; } bool QPDF::userPasswordMatched() const { return m->encp->user_password_matched; } static bool is_bit_set(int P, int bit) { // Bits in P are numbered from 1 in the spec return ((P & (1 << (bit - 1))) != 0); } bool QPDF::allowAccessibility() { int R = 0; int P = 0; bool status = true; if (isEncrypted(R, P)) { if (R < 3) { status = is_bit_set(P, 5); } else { status = is_bit_set(P, 10); } } return status; } bool QPDF::allowExtractAll() { int R = 0; int P = 0; bool status = true; if (isEncrypted(R, P)) { status = is_bit_set(P, 5); } return status; } bool QPDF::allowPrintLowRes() { int R = 0; int P = 0; bool status = true; if (isEncrypted(R, P)) { status = is_bit_set(P, 3); } return status; } bool QPDF::allowPrintHighRes() { int R = 0; int P = 0; bool status = true; if (isEncrypted(R, P)) { status = is_bit_set(P, 3); if ((R >= 3) && (!is_bit_set(P, 12))) { status = false; } } return status; } bool QPDF::allowModifyAssembly() { int R = 0; int P = 0; bool status = true; if (isEncrypted(R, P)) { if (R < 3) { status = is_bit_set(P, 4); } else { status = is_bit_set(P, 11); } } return status; } bool QPDF::allowModifyForm() { int R = 0; int P = 0; bool status = true; if (isEncrypted(R, P)) { if (R < 3) { status = is_bit_set(P, 6); } else { status = is_bit_set(P, 9); } } return status; } bool QPDF::allowModifyAnnotation() { int R = 0; int P = 0; bool status = true; if (isEncrypted(R, P)) { status = is_bit_set(P, 6); } return status; } bool QPDF::allowModifyOther() { int R = 0; int P = 0; bool status = true; if (isEncrypted(R, P)) { status = is_bit_set(P, 4); } return status; } bool QPDF::allowModifyAll() { int R = 0; int P = 0; bool status = true; if (isEncrypted(R, P)) { status = (is_bit_set(P, 4) && is_bit_set(P, 6)); if (R >= 3) { status = status && (is_bit_set(P, 9) && is_bit_set(P, 11)); } } return status; }