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/*
* Copyright (c) 2020, Ali Mohammad Pur <mpfard@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Debug.h>
#include <AK/Endian.h>
#include <AK/MemoryStream.h>
#include <LibCore/Timer.h>
#include <LibCrypto/PK/Code/EMSA_PSS.h>
#include <LibTLS/TLSv12.h>
namespace TLS {
ByteBuffer TLSv12::build_alert(bool critical, u8 code)
{
PacketBuilder builder(MessageType::Alert, (u16)m_context.options.version);
builder.append((u8)(critical ? AlertLevel::Critical : AlertLevel::Warning));
builder.append(code);
if (critical)
m_context.critical_error = code;
auto packet = builder.build();
update_packet(packet);
return packet;
}
void TLSv12::alert(AlertLevel level, AlertDescription code)
{
auto the_alert = build_alert(level == AlertLevel::Critical, (u8)code);
write_packet(the_alert);
flush();
}
void TLSv12::write_packet(ByteBuffer& packet)
{
m_context.tls_buffer.append(packet.data(), packet.size());
if (m_context.connection_status > ConnectionStatus::Disconnected) {
if (!m_has_scheduled_write_flush) {
dbgln_if(TLS_DEBUG, "Scheduling write of {}", m_context.tls_buffer.size());
deferred_invoke([this](auto&) { write_into_socket(); });
m_has_scheduled_write_flush = true;
} else {
// multiple packet are available, let's flush some out
dbgln_if(TLS_DEBUG, "Flushing scheduled write of {}", m_context.tls_buffer.size());
write_into_socket();
// the deferred invoke is still in place
m_has_scheduled_write_flush = true;
}
}
}
void TLSv12::update_packet(ByteBuffer& packet)
{
u32 header_size = 5;
ByteReader::store(packet.offset_pointer(3), AK::convert_between_host_and_network_endian((u16)(packet.size() - header_size)));
if (packet[0] != (u8)MessageType::ChangeCipher) {
if (packet[0] == (u8)MessageType::Handshake && packet.size() > header_size) {
u8 handshake_type = packet[header_size];
if (handshake_type != HandshakeType::HelloRequest && handshake_type != HandshakeType::HelloVerifyRequest) {
update_hash(packet.bytes(), header_size);
}
}
if (m_context.cipher_spec_set && m_context.crypto.created) {
size_t length = packet.size() - header_size;
size_t block_size = 0;
size_t padding = 0;
size_t mac_size = 0;
m_cipher_local.visit(
[&](Empty&) { VERIFY_NOT_REACHED(); },
[&](Crypto::Cipher::AESCipher::GCMMode& gcm) {
VERIFY(is_aead());
block_size = gcm.cipher().block_size();
padding = 0;
mac_size = 0; // AEAD provides its own authentication scheme.
},
[&](Crypto::Cipher::AESCipher::CBCMode& cbc) {
VERIFY(!is_aead());
block_size = cbc.cipher().block_size();
// If the length is already a multiple a block_size,
// an entire block of padding is added.
// In short, we _never_ have no padding.
mac_size = mac_length();
length += mac_size;
padding = block_size - length % block_size;
length += padding;
});
if (m_context.crypto.created == 1) {
// `buffer' will continue to be encrypted
auto buffer = ByteBuffer::create_uninitialized(length);
size_t buffer_position = 0;
auto iv_size = iv_length();
// copy the packet, sans the header
buffer.overwrite(buffer_position, packet.offset_pointer(header_size), packet.size() - header_size);
buffer_position += packet.size() - header_size;
ByteBuffer ct;
m_cipher_local.visit(
[&](Empty&) { VERIFY_NOT_REACHED(); },
[&](Crypto::Cipher::AESCipher::GCMMode& gcm) {
VERIFY(is_aead());
// We need enough space for a header, the data, a tag, and the IV
ct = ByteBuffer::create_uninitialized(length + header_size + iv_size + 16);
// copy the header over
ct.overwrite(0, packet.data(), header_size - 2);
// AEAD AAD (13)
// Seq. no (8)
// content type (1)
// version (2)
// length (2)
u8 aad[13];
Bytes aad_bytes { aad, 13 };
OutputMemoryStream aad_stream { aad_bytes };
u64 seq_no = AK::convert_between_host_and_network_endian(m_context.local_sequence_number);
u16 len = AK::convert_between_host_and_network_endian((u16)(packet.size() - header_size));
aad_stream.write({ &seq_no, sizeof(seq_no) });
aad_stream.write(packet.bytes().slice(0, 3)); // content-type + version
aad_stream.write({ &len, sizeof(len) }); // length
VERIFY(aad_stream.is_end());
// AEAD IV (12)
// IV (4)
// (Nonce) (8)
// -- Our GCM impl takes 16 bytes
// zero (4)
u8 iv[16];
Bytes iv_bytes { iv, 16 };
Bytes { m_context.crypto.local_aead_iv, 4 }.copy_to(iv_bytes);
fill_with_random(iv_bytes.offset(4), 8);
memset(iv_bytes.offset(12), 0, 4);
// write the random part of the iv out
iv_bytes.slice(4, 8).copy_to(ct.bytes().slice(header_size));
// Write the encrypted data and the tag
gcm.encrypt(
packet.bytes().slice(header_size, length),
ct.bytes().slice(header_size + 8, length),
iv_bytes,
aad_bytes,
ct.bytes().slice(header_size + 8 + length, 16));
VERIFY(header_size + 8 + length + 16 == ct.size());
},
[&](Crypto::Cipher::AESCipher::CBCMode& cbc) {
VERIFY(!is_aead());
// We need enough space for a header, iv_length bytes of IV and whatever the packet contains
ct = ByteBuffer::create_uninitialized(length + header_size + iv_size);
// copy the header over
ct.overwrite(0, packet.data(), header_size - 2);
// get the appropricate HMAC value for the entire packet
auto mac = hmac_message(packet, {}, mac_size, true);
// write the MAC
buffer.overwrite(buffer_position, mac.data(), mac.size());
buffer_position += mac.size();
// Apply the padding (a packet MUST always be padded)
memset(buffer.offset_pointer(buffer_position), padding - 1, padding);
buffer_position += padding;
VERIFY(buffer_position == buffer.size());
auto iv = ByteBuffer::create_uninitialized(iv_size);
fill_with_random(iv.data(), iv.size());
// write it into the ciphertext portion of the message
ct.overwrite(header_size, iv.data(), iv.size());
VERIFY(header_size + iv_size + length == ct.size());
VERIFY(length % block_size == 0);
// get a block to encrypt into
auto view = ct.bytes().slice(header_size + iv_size, length);
cbc.encrypt(buffer, view, iv);
});
// store the correct ciphertext length into the packet
u16 ct_length = (u16)ct.size() - header_size;
ByteReader::store(ct.offset_pointer(header_size - 2), AK::convert_between_host_and_network_endian(ct_length));
// replace the packet with the ciphertext
packet = ct;
}
}
}
++m_context.local_sequence_number;
}
void TLSv12::update_hash(ReadonlyBytes message, size_t header_size)
{
dbgln_if(TLS_DEBUG, "Update hash with message of size {}", message.size());
m_context.handshake_hash.update(message.slice(header_size));
}
void TLSv12::ensure_hmac(size_t digest_size, bool local)
{
if (local && m_hmac_local)
return;
if (!local && m_hmac_remote)
return;
auto hash_kind = Crypto::Hash::HashKind::None;
switch (digest_size) {
case Crypto::Hash::SHA1::DigestSize:
hash_kind = Crypto::Hash::HashKind::SHA1;
break;
case Crypto::Hash::SHA256::DigestSize:
hash_kind = Crypto::Hash::HashKind::SHA256;
break;
case Crypto::Hash::SHA384::DigestSize:
hash_kind = Crypto::Hash::HashKind::SHA384;
break;
case Crypto::Hash::SHA512::DigestSize:
hash_kind = Crypto::Hash::HashKind::SHA512;
break;
default:
dbgln("Failed to find a suitable hash for size {}", digest_size);
break;
}
auto hmac = make<Crypto::Authentication::HMAC<Crypto::Hash::Manager>>(ReadonlyBytes { local ? m_context.crypto.local_mac : m_context.crypto.remote_mac, digest_size }, hash_kind);
if (local)
m_hmac_local = move(hmac);
else
m_hmac_remote = move(hmac);
}
ByteBuffer TLSv12::hmac_message(const ReadonlyBytes& buf, const Optional<ReadonlyBytes> buf2, size_t mac_length, bool local)
{
u64 sequence_number = AK::convert_between_host_and_network_endian(local ? m_context.local_sequence_number : m_context.remote_sequence_number);
ensure_hmac(mac_length, local);
auto& hmac = local ? *m_hmac_local : *m_hmac_remote;
if constexpr (TLS_DEBUG) {
dbgln("========================= PACKET DATA ==========================");
print_buffer((const u8*)&sequence_number, sizeof(u64));
print_buffer(buf.data(), buf.size());
if (buf2.has_value())
print_buffer(buf2.value().data(), buf2.value().size());
dbgln("========================= PACKET DATA ==========================");
}
hmac.update((const u8*)&sequence_number, sizeof(u64));
hmac.update(buf);
if (buf2.has_value() && buf2.value().size()) {
hmac.update(buf2.value());
}
auto digest = hmac.digest();
auto mac = ByteBuffer::copy(digest.immutable_data(), digest.data_length());
if constexpr (TLS_DEBUG) {
dbgln("HMAC of the block for sequence number {}", sequence_number);
print_buffer(mac);
}
return mac;
}
ssize_t TLSv12::handle_message(ReadonlyBytes buffer)
{
auto res { 5ll };
size_t header_size = res;
ssize_t payload_res = 0;
dbgln_if(TLS_DEBUG, "buffer size: {}", buffer.size());
if (buffer.size() < 5) {
return (i8)Error::NeedMoreData;
}
auto type = (MessageType)buffer[0];
size_t buffer_position { 1 };
// FIXME: Read the version and verify it
if constexpr (TLS_DEBUG) {
auto version = ByteReader::load16(buffer.offset_pointer(buffer_position));
dbgln("type={}, version={}", (u8)type, (u16)version);
}
buffer_position += 2;
auto length = AK::convert_between_host_and_network_endian(ByteReader::load16(buffer.offset_pointer(buffer_position)));
dbgln_if(TLS_DEBUG, "record length: {} at offset: {}", length, buffer_position);
buffer_position += 2;
if (buffer_position + length > buffer.size()) {
dbgln_if(TLS_DEBUG, "record length more than what we have: {}", buffer.size());
return (i8)Error::NeedMoreData;
}
dbgln_if(TLS_DEBUG, "message type: {}, length: {}", (u8)type, length);
auto plain = buffer.slice(buffer_position, buffer.size() - buffer_position);
ByteBuffer decrypted;
if (m_context.cipher_spec_set && type != MessageType::ChangeCipher) {
if constexpr (TLS_DEBUG) {
dbgln("Encrypted: ");
print_buffer(buffer.slice(header_size, length));
}
Error return_value = Error::NoError;
m_cipher_remote.visit(
[&](Empty&) { VERIFY_NOT_REACHED(); },
[&](Crypto::Cipher::AESCipher::GCMMode& gcm) {
VERIFY(is_aead());
if (length < 24) {
dbgln("Invalid packet length");
auto packet = build_alert(true, (u8)AlertDescription::DecryptError);
write_packet(packet);
return_value = Error::BrokenPacket;
return;
}
auto packet_length = length - iv_length() - 16;
auto payload = plain;
decrypted = ByteBuffer::create_uninitialized(packet_length);
// AEAD AAD (13)
// Seq. no (8)
// content type (1)
// version (2)
// length (2)
u8 aad[13];
Bytes aad_bytes { aad, 13 };
OutputMemoryStream aad_stream { aad_bytes };
u64 seq_no = AK::convert_between_host_and_network_endian(m_context.remote_sequence_number);
u16 len = AK::convert_between_host_and_network_endian((u16)packet_length);
aad_stream.write({ &seq_no, sizeof(seq_no) }); // Sequence number
aad_stream.write(buffer.slice(0, header_size - 2)); // content-type + version
aad_stream.write({ &len, sizeof(u16) });
VERIFY(aad_stream.is_end());
auto nonce = payload.slice(0, iv_length());
payload = payload.slice(iv_length());
// AEAD IV (12)
// IV (4)
// (Nonce) (8)
// -- Our GCM impl takes 16 bytes
// zero (4)
u8 iv[16];
Bytes iv_bytes { iv, 16 };
Bytes { m_context.crypto.remote_aead_iv, 4 }.copy_to(iv_bytes);
nonce.copy_to(iv_bytes.slice(4));
memset(iv_bytes.offset(12), 0, 4);
auto ciphertext = payload.slice(0, payload.size() - 16);
auto tag = payload.slice(ciphertext.size());
auto consistency = gcm.decrypt(
ciphertext,
decrypted,
iv_bytes,
aad_bytes,
tag);
if (consistency != Crypto::VerificationConsistency::Consistent) {
dbgln("integrity check failed (tag length {})", tag.size());
auto packet = build_alert(true, (u8)AlertDescription::BadRecordMAC);
write_packet(packet);
return_value = Error::IntegrityCheckFailed;
return;
}
plain = decrypted;
},
[&](Crypto::Cipher::AESCipher::CBCMode& cbc) {
VERIFY(!is_aead());
auto iv_size = iv_length();
decrypted = cbc.create_aligned_buffer(length - iv_size);
auto iv = buffer.slice(header_size, iv_size);
Bytes decrypted_span = decrypted;
cbc.decrypt(buffer.slice(header_size + iv_size, length - iv_size), decrypted_span, iv);
length = decrypted_span.size();
if constexpr (TLS_DEBUG) {
dbgln("Decrypted: ");
print_buffer(decrypted);
}
auto mac_size = mac_length();
if (length < mac_size) {
dbgln("broken packet");
auto packet = build_alert(true, (u8)AlertDescription::DecryptError);
write_packet(packet);
return_value = Error::BrokenPacket;
return;
}
length -= mac_size;
const u8* message_hmac = decrypted_span.offset(length);
u8 temp_buf[5];
memcpy(temp_buf, buffer.offset_pointer(0), 3);
*(u16*)(temp_buf + 3) = AK::convert_between_host_and_network_endian(length);
auto hmac = hmac_message({ temp_buf, 5 }, decrypted_span.slice(0, length), mac_size);
auto message_mac = ReadonlyBytes { message_hmac, mac_size };
if (hmac != message_mac) {
dbgln("integrity check failed (mac length {})", mac_size);
dbgln("mac received:");
print_buffer(message_mac);
dbgln("mac computed:");
print_buffer(hmac);
auto packet = build_alert(true, (u8)AlertDescription::BadRecordMAC);
write_packet(packet);
return_value = Error::IntegrityCheckFailed;
return;
}
plain = decrypted.bytes().slice(0, length);
});
if (return_value != Error::NoError) {
return (i8)return_value;
}
}
m_context.remote_sequence_number++;
switch (type) {
case MessageType::ApplicationData:
if (m_context.connection_status != ConnectionStatus::Established) {
dbgln("unexpected application data");
payload_res = (i8)Error::UnexpectedMessage;
auto packet = build_alert(true, (u8)AlertDescription::UnexpectedMessage);
write_packet(packet);
} else {
dbgln_if(TLS_DEBUG, "application data message of size {}", plain.size());
m_context.application_buffer.append(plain.data(), plain.size());
}
break;
case MessageType::Handshake:
dbgln_if(TLS_DEBUG, "tls handshake message");
payload_res = handle_handshake_payload(plain);
break;
case MessageType::ChangeCipher:
if (m_context.connection_status != ConnectionStatus::KeyExchange) {
dbgln("unexpected change cipher message");
auto packet = build_alert(true, (u8)AlertDescription::UnexpectedMessage);
write_packet(packet);
payload_res = (i8)Error::UnexpectedMessage;
} else {
dbgln_if(TLS_DEBUG, "change cipher spec message");
m_context.cipher_spec_set = true;
m_context.remote_sequence_number = 0;
}
break;
case MessageType::Alert:
dbgln_if(TLS_DEBUG, "alert message of length {}", length);
if (length >= 2) {
if constexpr (TLS_DEBUG)
print_buffer(plain);
auto level = plain[0];
auto code = plain[1];
dbgln_if(TLS_DEBUG, "Alert received with level {}, code {}", level, code);
if (level == (u8)AlertLevel::Critical) {
dbgln("We were alerted of a critical error: {} ({})", code, alert_name((AlertDescription)code));
m_context.critical_error = code;
try_disambiguate_error();
res = (i8)Error::UnknownError;
}
if (code == (u8)AlertDescription::CloseNotify) {
res += 2;
alert(AlertLevel::Critical, AlertDescription::CloseNotify);
m_context.connection_finished = true;
if (!m_context.cipher_spec_set) {
// AWS CloudFront hits this.
dbgln("Server sent a close notify and we haven't agreed on a cipher suite. Treating it as a handshake failure.");
m_context.critical_error = (u8)AlertDescription::HandshakeFailure;
try_disambiguate_error();
}
}
m_context.error_code = (Error)code;
}
break;
default:
dbgln("message not understood");
return (i8)Error::NotUnderstood;
}
if (payload_res < 0)
return payload_res;
if (res > 0)
return header_size + length;
return res;
}
}
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