esphome/esphome/components/api/api_frame_helper.cpp
2022-06-27 18:02:46 -03:00

1024 lines
32 KiB
C++

#include "api_frame_helper.h"
#include "esphome/core/log.h"
#include "esphome/core/hal.h"
#include "esphome/core/helpers.h"
#include "esphome/core/application.h"
#include "proto.h"
#include <cstring>
namespace esphome {
namespace api {
static const char *const TAG = "api.socket";
/// Is the given return value (from write syscalls) a wouldblock error?
bool is_would_block(ssize_t ret) {
if (ret == -1) {
return errno == EWOULDBLOCK || errno == EAGAIN;
}
return ret == 0;
}
const char *api_error_to_str(APIError err) {
// not using switch to ensure compiler doesn't try to build a big table out of it
if (err == APIError::OK) {
return "OK";
} else if (err == APIError::WOULD_BLOCK) {
return "WOULD_BLOCK";
} else if (err == APIError::BAD_HANDSHAKE_PACKET_LEN) {
return "BAD_HANDSHAKE_PACKET_LEN";
} else if (err == APIError::BAD_INDICATOR) {
return "BAD_INDICATOR";
} else if (err == APIError::BAD_DATA_PACKET) {
return "BAD_DATA_PACKET";
} else if (err == APIError::TCP_NODELAY_FAILED) {
return "TCP_NODELAY_FAILED";
} else if (err == APIError::TCP_NONBLOCKING_FAILED) {
return "TCP_NONBLOCKING_FAILED";
} else if (err == APIError::CLOSE_FAILED) {
return "CLOSE_FAILED";
} else if (err == APIError::SHUTDOWN_FAILED) {
return "SHUTDOWN_FAILED";
} else if (err == APIError::BAD_STATE) {
return "BAD_STATE";
} else if (err == APIError::BAD_ARG) {
return "BAD_ARG";
} else if (err == APIError::SOCKET_READ_FAILED) {
return "SOCKET_READ_FAILED";
} else if (err == APIError::SOCKET_WRITE_FAILED) {
return "SOCKET_WRITE_FAILED";
} else if (err == APIError::HANDSHAKESTATE_READ_FAILED) {
return "HANDSHAKESTATE_READ_FAILED";
} else if (err == APIError::HANDSHAKESTATE_WRITE_FAILED) {
return "HANDSHAKESTATE_WRITE_FAILED";
} else if (err == APIError::HANDSHAKESTATE_BAD_STATE) {
return "HANDSHAKESTATE_BAD_STATE";
} else if (err == APIError::CIPHERSTATE_DECRYPT_FAILED) {
return "CIPHERSTATE_DECRYPT_FAILED";
} else if (err == APIError::CIPHERSTATE_ENCRYPT_FAILED) {
return "CIPHERSTATE_ENCRYPT_FAILED";
} else if (err == APIError::OUT_OF_MEMORY) {
return "OUT_OF_MEMORY";
} else if (err == APIError::HANDSHAKESTATE_SETUP_FAILED) {
return "HANDSHAKESTATE_SETUP_FAILED";
} else if (err == APIError::HANDSHAKESTATE_SPLIT_FAILED) {
return "HANDSHAKESTATE_SPLIT_FAILED";
} else if (err == APIError::BAD_HANDSHAKE_ERROR_BYTE) {
return "BAD_HANDSHAKE_ERROR_BYTE";
} else if (err == APIError::CONNECTION_CLOSED) {
return "CONNECTION_CLOSED";
}
return "UNKNOWN";
}
#define HELPER_LOG(msg, ...) ESP_LOGVV(TAG, "%s: " msg, info_.c_str(), ##__VA_ARGS__)
// uncomment to log raw packets
//#define HELPER_LOG_PACKETS
#ifdef USE_API_NOISE
static const char *const PROLOGUE_INIT = "NoiseAPIInit";
/// Convert a noise error code to a readable error
std::string noise_err_to_str(int err) {
if (err == NOISE_ERROR_NO_MEMORY)
return "NO_MEMORY";
if (err == NOISE_ERROR_UNKNOWN_ID)
return "UNKNOWN_ID";
if (err == NOISE_ERROR_UNKNOWN_NAME)
return "UNKNOWN_NAME";
if (err == NOISE_ERROR_MAC_FAILURE)
return "MAC_FAILURE";
if (err == NOISE_ERROR_NOT_APPLICABLE)
return "NOT_APPLICABLE";
if (err == NOISE_ERROR_SYSTEM)
return "SYSTEM";
if (err == NOISE_ERROR_REMOTE_KEY_REQUIRED)
return "REMOTE_KEY_REQUIRED";
if (err == NOISE_ERROR_LOCAL_KEY_REQUIRED)
return "LOCAL_KEY_REQUIRED";
if (err == NOISE_ERROR_PSK_REQUIRED)
return "PSK_REQUIRED";
if (err == NOISE_ERROR_INVALID_LENGTH)
return "INVALID_LENGTH";
if (err == NOISE_ERROR_INVALID_PARAM)
return "INVALID_PARAM";
if (err == NOISE_ERROR_INVALID_STATE)
return "INVALID_STATE";
if (err == NOISE_ERROR_INVALID_NONCE)
return "INVALID_NONCE";
if (err == NOISE_ERROR_INVALID_PRIVATE_KEY)
return "INVALID_PRIVATE_KEY";
if (err == NOISE_ERROR_INVALID_PUBLIC_KEY)
return "INVALID_PUBLIC_KEY";
if (err == NOISE_ERROR_INVALID_FORMAT)
return "INVALID_FORMAT";
if (err == NOISE_ERROR_INVALID_SIGNATURE)
return "INVALID_SIGNATURE";
return to_string(err);
}
/// Initialize the frame helper, returns OK if successful.
APIError APINoiseFrameHelper::init() {
if (state_ != State::INITIALIZE || socket_ == nullptr) {
HELPER_LOG("Bad state for init %d", (int) state_);
return APIError::BAD_STATE;
}
int err = socket_->setblocking(false);
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("Setting nonblocking failed with errno %d", errno);
return APIError::TCP_NONBLOCKING_FAILED;
}
int enable = 1;
err = socket_->setsockopt(IPPROTO_TCP, TCP_NODELAY, &enable, sizeof(int));
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("Setting nodelay failed with errno %d", errno);
return APIError::TCP_NODELAY_FAILED;
}
// init prologue
prologue_.insert(prologue_.end(), PROLOGUE_INIT, PROLOGUE_INIT + strlen(PROLOGUE_INIT));
state_ = State::CLIENT_HELLO;
return APIError::OK;
}
/// Run through handshake messages (if in that phase)
APIError APINoiseFrameHelper::loop() {
APIError err = state_action_();
if (err == APIError::WOULD_BLOCK)
return APIError::OK;
if (err != APIError::OK)
return err;
if (!tx_buf_.empty()) {
err = try_send_tx_buf_();
if (err != APIError::OK) {
return err;
}
}
return APIError::OK;
}
/** Read a packet into the rx_buf_. If successful, stores frame data in the frame parameter
*
* @param frame: The struct to hold the frame information in.
* msg_start: points to the start of the payload - this pointer is only valid until the next
* try_receive_raw_ call
*
* @return 0 if a full packet is in rx_buf_
* @return -1 if error, check errno.
*
* errno EWOULDBLOCK: Packet could not be read without blocking. Try again later.
* errno ENOMEM: Not enough memory for reading packet.
* errno API_ERROR_BAD_INDICATOR: Bad indicator byte at start of frame.
* errno API_ERROR_HANDSHAKE_PACKET_LEN: Packet too big for this phase.
*/
APIError APINoiseFrameHelper::try_read_frame_(ParsedFrame *frame) {
if (frame == nullptr) {
HELPER_LOG("Bad argument for try_read_frame_");
return APIError::BAD_ARG;
}
// read header
if (rx_header_buf_len_ < 3) {
// no header information yet
size_t to_read = 3 - rx_header_buf_len_;
ssize_t received = socket_->read(&rx_header_buf_[rx_header_buf_len_], to_read);
if (received == -1) {
if (errno == EWOULDBLOCK || errno == EAGAIN) {
return APIError::WOULD_BLOCK;
}
state_ = State::FAILED;
HELPER_LOG("Socket read failed with errno %d", errno);
return APIError::SOCKET_READ_FAILED;
} else if (received == 0) {
state_ = State::FAILED;
HELPER_LOG("Connection closed");
return APIError::CONNECTION_CLOSED;
}
rx_header_buf_len_ += received;
if ((size_t) received != to_read) {
// not a full read
return APIError::WOULD_BLOCK;
}
// header reading done
}
// read body
uint8_t indicator = rx_header_buf_[0];
if (indicator != 0x01) {
state_ = State::FAILED;
HELPER_LOG("Bad indicator byte %u", indicator);
return APIError::BAD_INDICATOR;
}
uint16_t msg_size = (((uint16_t) rx_header_buf_[1]) << 8) | rx_header_buf_[2];
if (state_ != State::DATA && msg_size > 128) {
// for handshake message only permit up to 128 bytes
state_ = State::FAILED;
HELPER_LOG("Bad packet len for handshake: %d", msg_size);
return APIError::BAD_HANDSHAKE_PACKET_LEN;
}
// reserve space for body
if (rx_buf_.size() != msg_size) {
rx_buf_.resize(msg_size);
}
if (rx_buf_len_ < msg_size) {
// more data to read
size_t to_read = msg_size - rx_buf_len_;
ssize_t received = socket_->read(&rx_buf_[rx_buf_len_], to_read);
if (received == -1) {
if (errno == EWOULDBLOCK || errno == EAGAIN) {
return APIError::WOULD_BLOCK;
}
state_ = State::FAILED;
HELPER_LOG("Socket read failed with errno %d", errno);
return APIError::SOCKET_READ_FAILED;
} else if (received == 0) {
state_ = State::FAILED;
HELPER_LOG("Connection closed");
return APIError::CONNECTION_CLOSED;
}
rx_buf_len_ += received;
if ((size_t) received != to_read) {
// not all read
return APIError::WOULD_BLOCK;
}
}
// uncomment for even more debugging
#ifdef HELPER_LOG_PACKETS
ESP_LOGVV(TAG, "Received frame: %s", format_hex_pretty(rx_buf_).c_str());
#endif
frame->msg = std::move(rx_buf_);
// consume msg
rx_buf_ = {};
rx_buf_len_ = 0;
rx_header_buf_len_ = 0;
return APIError::OK;
}
/** To be called from read/write methods.
*
* This method runs through the internal handshake methods, if in that state.
*
* If the handshake is still active when this method returns and a read/write can't take place at
* the moment, returns WOULD_BLOCK.
* If an error occurred, returns that error. Only returns OK if the transport is ready for data
* traffic.
*/
APIError APINoiseFrameHelper::state_action_() {
int err;
APIError aerr;
if (state_ == State::INITIALIZE) {
HELPER_LOG("Bad state for method: %d", (int) state_);
return APIError::BAD_STATE;
}
if (state_ == State::CLIENT_HELLO) {
// waiting for client hello
ParsedFrame frame;
aerr = try_read_frame_(&frame);
if (aerr == APIError::BAD_INDICATOR) {
send_explicit_handshake_reject_("Bad indicator byte");
return aerr;
}
if (aerr == APIError::BAD_HANDSHAKE_PACKET_LEN) {
send_explicit_handshake_reject_("Bad handshake packet len");
return aerr;
}
if (aerr != APIError::OK)
return aerr;
// ignore contents, may be used in future for flags
prologue_.push_back((uint8_t)(frame.msg.size() >> 8));
prologue_.push_back((uint8_t) frame.msg.size());
prologue_.insert(prologue_.end(), frame.msg.begin(), frame.msg.end());
state_ = State::SERVER_HELLO;
}
if (state_ == State::SERVER_HELLO) {
// send server hello
std::vector<uint8_t> msg;
// chosen proto
msg.push_back(0x01);
// node name, terminated by null byte
const std::string &name = App.get_name();
const uint8_t *name_ptr = reinterpret_cast<const uint8_t *>(name.c_str());
msg.insert(msg.end(), name_ptr, name_ptr + name.size() + 1);
aerr = write_frame_(msg.data(), msg.size());
if (aerr != APIError::OK)
return aerr;
// start handshake
aerr = init_handshake_();
if (aerr != APIError::OK)
return aerr;
state_ = State::HANDSHAKE;
}
if (state_ == State::HANDSHAKE) {
int action = noise_handshakestate_get_action(handshake_);
if (action == NOISE_ACTION_READ_MESSAGE) {
// waiting for handshake msg
ParsedFrame frame;
aerr = try_read_frame_(&frame);
if (aerr == APIError::BAD_INDICATOR) {
send_explicit_handshake_reject_("Bad indicator byte");
return aerr;
}
if (aerr == APIError::BAD_HANDSHAKE_PACKET_LEN) {
send_explicit_handshake_reject_("Bad handshake packet len");
return aerr;
}
if (aerr != APIError::OK)
return aerr;
if (frame.msg.empty()) {
send_explicit_handshake_reject_("Empty handshake message");
return APIError::BAD_HANDSHAKE_ERROR_BYTE;
} else if (frame.msg[0] != 0x00) {
HELPER_LOG("Bad handshake error byte: %u", frame.msg[0]);
send_explicit_handshake_reject_("Bad handshake error byte");
return APIError::BAD_HANDSHAKE_ERROR_BYTE;
}
NoiseBuffer mbuf;
noise_buffer_init(mbuf);
noise_buffer_set_input(mbuf, frame.msg.data() + 1, frame.msg.size() - 1);
err = noise_handshakestate_read_message(handshake_, &mbuf, nullptr);
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("noise_handshakestate_read_message failed: %s", noise_err_to_str(err).c_str());
if (err == NOISE_ERROR_MAC_FAILURE) {
send_explicit_handshake_reject_("Handshake MAC failure");
} else {
send_explicit_handshake_reject_("Handshake error");
}
return APIError::HANDSHAKESTATE_READ_FAILED;
}
aerr = check_handshake_finished_();
if (aerr != APIError::OK)
return aerr;
} else if (action == NOISE_ACTION_WRITE_MESSAGE) {
uint8_t buffer[65];
NoiseBuffer mbuf;
noise_buffer_init(mbuf);
noise_buffer_set_output(mbuf, buffer + 1, sizeof(buffer) - 1);
err = noise_handshakestate_write_message(handshake_, &mbuf, nullptr);
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("noise_handshakestate_write_message failed: %s", noise_err_to_str(err).c_str());
return APIError::HANDSHAKESTATE_WRITE_FAILED;
}
buffer[0] = 0x00; // success
aerr = write_frame_(buffer, mbuf.size + 1);
if (aerr != APIError::OK)
return aerr;
aerr = check_handshake_finished_();
if (aerr != APIError::OK)
return aerr;
} else {
// bad state for action
state_ = State::FAILED;
HELPER_LOG("Bad action for handshake: %d", action);
return APIError::HANDSHAKESTATE_BAD_STATE;
}
}
if (state_ == State::CLOSED || state_ == State::FAILED) {
return APIError::BAD_STATE;
}
return APIError::OK;
}
void APINoiseFrameHelper::send_explicit_handshake_reject_(const std::string &reason) {
std::vector<uint8_t> data;
data.resize(reason.length() + 1);
data[0] = 0x01; // failure
for (size_t i = 0; i < reason.length(); i++) {
data[i + 1] = (uint8_t) reason[i];
}
// temporarily remove failed state
auto orig_state = state_;
state_ = State::EXPLICIT_REJECT;
write_frame_(data.data(), data.size());
state_ = orig_state;
}
APIError APINoiseFrameHelper::read_packet(ReadPacketBuffer *buffer) {
int err;
APIError aerr;
aerr = state_action_();
if (aerr != APIError::OK) {
return aerr;
}
if (state_ != State::DATA) {
return APIError::WOULD_BLOCK;
}
ParsedFrame frame;
aerr = try_read_frame_(&frame);
if (aerr != APIError::OK)
return aerr;
NoiseBuffer mbuf;
noise_buffer_init(mbuf);
noise_buffer_set_inout(mbuf, frame.msg.data(), frame.msg.size(), frame.msg.size());
err = noise_cipherstate_decrypt(recv_cipher_, &mbuf);
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("noise_cipherstate_decrypt failed: %s", noise_err_to_str(err).c_str());
return APIError::CIPHERSTATE_DECRYPT_FAILED;
}
size_t msg_size = mbuf.size;
uint8_t *msg_data = frame.msg.data();
if (msg_size < 4) {
state_ = State::FAILED;
HELPER_LOG("Bad data packet: size %d too short", msg_size);
return APIError::BAD_DATA_PACKET;
}
// uint16_t type;
// uint16_t data_len;
// uint8_t *data;
// uint8_t *padding; zero or more bytes to fill up the rest of the packet
uint16_t type = (((uint16_t) msg_data[0]) << 8) | msg_data[1];
uint16_t data_len = (((uint16_t) msg_data[2]) << 8) | msg_data[3];
if (data_len > msg_size - 4) {
state_ = State::FAILED;
HELPER_LOG("Bad data packet: data_len %u greater than msg_size %u", data_len, msg_size);
return APIError::BAD_DATA_PACKET;
}
buffer->container = std::move(frame.msg);
buffer->data_offset = 4;
buffer->data_len = data_len;
buffer->type = type;
return APIError::OK;
}
bool APINoiseFrameHelper::can_write_without_blocking() { return state_ == State::DATA && tx_buf_.empty(); }
APIError APINoiseFrameHelper::write_packet(uint16_t type, const uint8_t *payload, size_t payload_len) {
int err;
APIError aerr;
aerr = state_action_();
if (aerr != APIError::OK) {
return aerr;
}
if (state_ != State::DATA) {
return APIError::WOULD_BLOCK;
}
size_t padding = 0;
size_t msg_len = 4 + payload_len + padding;
size_t frame_len = 3 + msg_len + noise_cipherstate_get_mac_length(send_cipher_);
auto tmpbuf = std::unique_ptr<uint8_t[]>{new (std::nothrow) uint8_t[frame_len]};
if (tmpbuf == nullptr) {
HELPER_LOG("Could not allocate for writing packet");
return APIError::OUT_OF_MEMORY;
}
tmpbuf[0] = 0x01; // indicator
// tmpbuf[1], tmpbuf[2] to be set later
const uint8_t msg_offset = 3;
const uint8_t payload_offset = msg_offset + 4;
tmpbuf[msg_offset + 0] = (uint8_t)(type >> 8); // type
tmpbuf[msg_offset + 1] = (uint8_t) type;
tmpbuf[msg_offset + 2] = (uint8_t)(payload_len >> 8); // data_len
tmpbuf[msg_offset + 3] = (uint8_t) payload_len;
// copy data
std::copy(payload, payload + payload_len, &tmpbuf[payload_offset]);
// fill padding with zeros
std::fill(&tmpbuf[payload_offset + payload_len], &tmpbuf[frame_len], 0);
NoiseBuffer mbuf;
noise_buffer_init(mbuf);
noise_buffer_set_inout(mbuf, &tmpbuf[msg_offset], msg_len, frame_len - msg_offset);
err = noise_cipherstate_encrypt(send_cipher_, &mbuf);
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("noise_cipherstate_encrypt failed: %s", noise_err_to_str(err).c_str());
return APIError::CIPHERSTATE_ENCRYPT_FAILED;
}
size_t total_len = 3 + mbuf.size;
tmpbuf[1] = (uint8_t)(mbuf.size >> 8);
tmpbuf[2] = (uint8_t) mbuf.size;
struct iovec iov;
iov.iov_base = &tmpbuf[0];
iov.iov_len = total_len;
// write raw to not have two packets sent if NAGLE disabled
return write_raw_(&iov, 1);
}
APIError APINoiseFrameHelper::try_send_tx_buf_() {
// try send from tx_buf
while (state_ != State::CLOSED && !tx_buf_.empty()) {
ssize_t sent = socket_->write(tx_buf_.data(), tx_buf_.size());
if (sent == -1) {
if (errno == EWOULDBLOCK || errno == EAGAIN)
break;
state_ = State::FAILED;
HELPER_LOG("Socket write failed with errno %d", errno);
return APIError::SOCKET_WRITE_FAILED;
} else if (sent == 0) {
break;
}
// TODO: inefficient if multiple packets in txbuf
// replace with deque of buffers
tx_buf_.erase(tx_buf_.begin(), tx_buf_.begin() + sent);
}
return APIError::OK;
}
/** Write the data to the socket, or buffer it a write would block
*
* @param data The data to write
* @param len The length of data
*/
APIError APINoiseFrameHelper::write_raw_(const struct iovec *iov, int iovcnt) {
if (iovcnt == 0)
return APIError::OK;
APIError aerr;
size_t total_write_len = 0;
for (int i = 0; i < iovcnt; i++) {
#ifdef HELPER_LOG_PACKETS
ESP_LOGVV(TAG, "Sending raw: %s",
format_hex_pretty(reinterpret_cast<uint8_t *>(iov[i].iov_base), iov[i].iov_len).c_str());
#endif
total_write_len += iov[i].iov_len;
}
if (!tx_buf_.empty()) {
// try to empty tx_buf_ first
aerr = try_send_tx_buf_();
if (aerr != APIError::OK && aerr != APIError::WOULD_BLOCK)
return aerr;
}
if (!tx_buf_.empty()) {
// tx buf not empty, can't write now because then stream would be inconsistent
for (int i = 0; i < iovcnt; i++) {
tx_buf_.insert(tx_buf_.end(), reinterpret_cast<uint8_t *>(iov[i].iov_base),
reinterpret_cast<uint8_t *>(iov[i].iov_base) + iov[i].iov_len);
}
return APIError::OK;
}
ssize_t sent = socket_->writev(iov, iovcnt);
if (is_would_block(sent)) {
// operation would block, add buffer to tx_buf
for (int i = 0; i < iovcnt; i++) {
tx_buf_.insert(tx_buf_.end(), reinterpret_cast<uint8_t *>(iov[i].iov_base),
reinterpret_cast<uint8_t *>(iov[i].iov_base) + iov[i].iov_len);
}
return APIError::OK;
} else if (sent == -1) {
// an error occurred
state_ = State::FAILED;
HELPER_LOG("Socket write failed with errno %d", errno);
return APIError::SOCKET_WRITE_FAILED;
} else if ((size_t) sent != total_write_len) {
// partially sent, add end to tx_buf
size_t to_consume = sent;
for (int i = 0; i < iovcnt; i++) {
if (to_consume >= iov[i].iov_len) {
to_consume -= iov[i].iov_len;
} else {
tx_buf_.insert(tx_buf_.end(), reinterpret_cast<uint8_t *>(iov[i].iov_base) + to_consume,
reinterpret_cast<uint8_t *>(iov[i].iov_base) + iov[i].iov_len);
to_consume = 0;
}
}
return APIError::OK;
}
// fully sent
return APIError::OK;
}
APIError APINoiseFrameHelper::write_frame_(const uint8_t *data, size_t len) {
uint8_t header[3];
header[0] = 0x01; // indicator
header[1] = (uint8_t)(len >> 8);
header[2] = (uint8_t) len;
struct iovec iov[2];
iov[0].iov_base = header;
iov[0].iov_len = 3;
iov[1].iov_base = const_cast<uint8_t *>(data);
iov[1].iov_len = len;
return write_raw_(iov, 2);
}
/** Initiate the data structures for the handshake.
*
* @return 0 on success, -1 on error (check errno)
*/
APIError APINoiseFrameHelper::init_handshake_() {
int err;
memset(&nid_, 0, sizeof(nid_));
// const char *proto = "Noise_NNpsk0_25519_ChaChaPoly_SHA256";
// err = noise_protocol_name_to_id(&nid_, proto, strlen(proto));
nid_.pattern_id = NOISE_PATTERN_NN;
nid_.cipher_id = NOISE_CIPHER_CHACHAPOLY;
nid_.dh_id = NOISE_DH_CURVE25519;
nid_.prefix_id = NOISE_PREFIX_STANDARD;
nid_.hybrid_id = NOISE_DH_NONE;
nid_.hash_id = NOISE_HASH_SHA256;
nid_.modifier_ids[0] = NOISE_MODIFIER_PSK0;
err = noise_handshakestate_new_by_id(&handshake_, &nid_, NOISE_ROLE_RESPONDER);
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("noise_handshakestate_new_by_id failed: %s", noise_err_to_str(err).c_str());
return APIError::HANDSHAKESTATE_SETUP_FAILED;
}
const auto &psk = ctx_->get_psk();
err = noise_handshakestate_set_pre_shared_key(handshake_, psk.data(), psk.size());
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("noise_handshakestate_set_pre_shared_key failed: %s", noise_err_to_str(err).c_str());
return APIError::HANDSHAKESTATE_SETUP_FAILED;
}
err = noise_handshakestate_set_prologue(handshake_, prologue_.data(), prologue_.size());
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("noise_handshakestate_set_prologue failed: %s", noise_err_to_str(err).c_str());
return APIError::HANDSHAKESTATE_SETUP_FAILED;
}
// set_prologue copies it into handshakestate, so we can get rid of it now
prologue_ = {};
err = noise_handshakestate_start(handshake_);
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("noise_handshakestate_start failed: %s", noise_err_to_str(err).c_str());
return APIError::HANDSHAKESTATE_SETUP_FAILED;
}
return APIError::OK;
}
APIError APINoiseFrameHelper::check_handshake_finished_() {
assert(state_ == State::HANDSHAKE);
int action = noise_handshakestate_get_action(handshake_);
if (action == NOISE_ACTION_READ_MESSAGE || action == NOISE_ACTION_WRITE_MESSAGE)
return APIError::OK;
if (action != NOISE_ACTION_SPLIT) {
state_ = State::FAILED;
HELPER_LOG("Bad action for handshake: %d", action);
return APIError::HANDSHAKESTATE_BAD_STATE;
}
int err = noise_handshakestate_split(handshake_, &send_cipher_, &recv_cipher_);
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("noise_handshakestate_split failed: %s", noise_err_to_str(err).c_str());
return APIError::HANDSHAKESTATE_SPLIT_FAILED;
}
HELPER_LOG("Handshake complete!");
noise_handshakestate_free(handshake_);
handshake_ = nullptr;
state_ = State::DATA;
return APIError::OK;
}
APINoiseFrameHelper::~APINoiseFrameHelper() {
if (handshake_ != nullptr) {
noise_handshakestate_free(handshake_);
handshake_ = nullptr;
}
if (send_cipher_ != nullptr) {
noise_cipherstate_free(send_cipher_);
send_cipher_ = nullptr;
}
if (recv_cipher_ != nullptr) {
noise_cipherstate_free(recv_cipher_);
recv_cipher_ = nullptr;
}
}
APIError APINoiseFrameHelper::close() {
state_ = State::CLOSED;
int err = socket_->close();
if (err == -1)
return APIError::CLOSE_FAILED;
return APIError::OK;
}
APIError APINoiseFrameHelper::shutdown(int how) {
int err = socket_->shutdown(how);
if (err == -1)
return APIError::SHUTDOWN_FAILED;
if (how == SHUT_RDWR) {
state_ = State::CLOSED;
}
return APIError::OK;
}
extern "C" {
// declare how noise generates random bytes (here with a good HWRNG based on the RF system)
void noise_rand_bytes(void *output, size_t len) {
if (!esphome::random_bytes(reinterpret_cast<uint8_t *>(output), len)) {
ESP_LOGE(TAG, "Failed to acquire random bytes, rebooting!");
arch_restart();
}
}
}
#endif // USE_API_NOISE
#ifdef USE_API_PLAINTEXT
/// Initialize the frame helper, returns OK if successful.
APIError APIPlaintextFrameHelper::init() {
if (state_ != State::INITIALIZE || socket_ == nullptr) {
HELPER_LOG("Bad state for init %d", (int) state_);
return APIError::BAD_STATE;
}
int err = socket_->setblocking(false);
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("Setting nonblocking failed with errno %d", errno);
return APIError::TCP_NONBLOCKING_FAILED;
}
int enable = 1;
err = socket_->setsockopt(IPPROTO_TCP, TCP_NODELAY, &enable, sizeof(int));
if (err != 0) {
state_ = State::FAILED;
HELPER_LOG("Setting nodelay failed with errno %d", errno);
return APIError::TCP_NODELAY_FAILED;
}
state_ = State::DATA;
return APIError::OK;
}
/// Not used for plaintext
APIError APIPlaintextFrameHelper::loop() {
if (state_ != State::DATA) {
return APIError::BAD_STATE;
}
// try send pending TX data
if (!tx_buf_.empty()) {
APIError err = try_send_tx_buf_();
if (err != APIError::OK) {
return err;
}
}
return APIError::OK;
}
/** Read a packet into the rx_buf_. If successful, stores frame data in the frame parameter
*
* @param frame: The struct to hold the frame information in.
* msg: store the parsed frame in that struct
*
* @return See APIError
*
* error API_ERROR_BAD_INDICATOR: Bad indicator byte at start of frame.
*/
APIError APIPlaintextFrameHelper::try_read_frame_(ParsedFrame *frame) {
if (frame == nullptr) {
HELPER_LOG("Bad argument for try_read_frame_");
return APIError::BAD_ARG;
}
// read header
while (!rx_header_parsed_) {
uint8_t data;
ssize_t received = socket_->read(&data, 1);
if (received == -1) {
if (errno == EWOULDBLOCK || errno == EAGAIN) {
return APIError::WOULD_BLOCK;
}
state_ = State::FAILED;
HELPER_LOG("Socket read failed with errno %d", errno);
return APIError::SOCKET_READ_FAILED;
} else if (received == 0) {
state_ = State::FAILED;
HELPER_LOG("Connection closed");
return APIError::CONNECTION_CLOSED;
}
rx_header_buf_.push_back(data);
// try parse header
if (rx_header_buf_[0] != 0x00) {
state_ = State::FAILED;
HELPER_LOG("Bad indicator byte %u", rx_header_buf_[0]);
return APIError::BAD_INDICATOR;
}
size_t i = 1;
uint32_t consumed = 0;
auto msg_size_varint = ProtoVarInt::parse(&rx_header_buf_[i], rx_header_buf_.size() - i, &consumed);
if (!msg_size_varint.has_value()) {
// not enough data there yet
continue;
}
i += consumed;
rx_header_parsed_len_ = msg_size_varint->as_uint32();
auto msg_type_varint = ProtoVarInt::parse(&rx_header_buf_[i], rx_header_buf_.size() - i, &consumed);
if (!msg_type_varint.has_value()) {
// not enough data there yet
continue;
}
rx_header_parsed_type_ = msg_type_varint->as_uint32();
rx_header_parsed_ = true;
}
// header reading done
// reserve space for body
if (rx_buf_.size() != rx_header_parsed_len_) {
rx_buf_.resize(rx_header_parsed_len_);
}
if (rx_buf_len_ < rx_header_parsed_len_) {
// more data to read
size_t to_read = rx_header_parsed_len_ - rx_buf_len_;
ssize_t received = socket_->read(&rx_buf_[rx_buf_len_], to_read);
if (received == -1) {
if (errno == EWOULDBLOCK || errno == EAGAIN) {
return APIError::WOULD_BLOCK;
}
state_ = State::FAILED;
HELPER_LOG("Socket read failed with errno %d", errno);
return APIError::SOCKET_READ_FAILED;
} else if (received == 0) {
state_ = State::FAILED;
HELPER_LOG("Connection closed");
return APIError::CONNECTION_CLOSED;
}
rx_buf_len_ += received;
if ((size_t) received != to_read) {
// not all read
return APIError::WOULD_BLOCK;
}
}
// uncomment for even more debugging
#ifdef HELPER_LOG_PACKETS
ESP_LOGVV(TAG, "Received frame: %s", format_hex_pretty(rx_buf_).c_str());
#endif
frame->msg = std::move(rx_buf_);
// consume msg
rx_buf_ = {};
rx_buf_len_ = 0;
rx_header_buf_.clear();
rx_header_parsed_ = false;
return APIError::OK;
}
APIError APIPlaintextFrameHelper::read_packet(ReadPacketBuffer *buffer) {
APIError aerr;
if (state_ != State::DATA) {
return APIError::WOULD_BLOCK;
}
ParsedFrame frame;
aerr = try_read_frame_(&frame);
if (aerr != APIError::OK)
return aerr;
buffer->container = std::move(frame.msg);
buffer->data_offset = 0;
buffer->data_len = rx_header_parsed_len_;
buffer->type = rx_header_parsed_type_;
return APIError::OK;
}
bool APIPlaintextFrameHelper::can_write_without_blocking() { return state_ == State::DATA && tx_buf_.empty(); }
APIError APIPlaintextFrameHelper::write_packet(uint16_t type, const uint8_t *payload, size_t payload_len) {
if (state_ != State::DATA) {
return APIError::BAD_STATE;
}
std::vector<uint8_t> header;
header.push_back(0x00);
ProtoVarInt(payload_len).encode(header);
ProtoVarInt(type).encode(header);
struct iovec iov[2];
iov[0].iov_base = &header[0];
iov[0].iov_len = header.size();
iov[1].iov_base = const_cast<uint8_t *>(payload);
iov[1].iov_len = payload_len;
return write_raw_(iov, 2);
}
APIError APIPlaintextFrameHelper::try_send_tx_buf_() {
// try send from tx_buf
while (state_ != State::CLOSED && !tx_buf_.empty()) {
ssize_t sent = socket_->write(tx_buf_.data(), tx_buf_.size());
if (is_would_block(sent)) {
break;
} else if (sent == -1) {
state_ = State::FAILED;
HELPER_LOG("Socket write failed with errno %d", errno);
return APIError::SOCKET_WRITE_FAILED;
}
// TODO: inefficient if multiple packets in txbuf
// replace with deque of buffers
tx_buf_.erase(tx_buf_.begin(), tx_buf_.begin() + sent);
}
return APIError::OK;
}
/** Write the data to the socket, or buffer it a write would block
*
* @param data The data to write
* @param len The length of data
*/
APIError APIPlaintextFrameHelper::write_raw_(const struct iovec *iov, int iovcnt) {
if (iovcnt == 0)
return APIError::OK;
APIError aerr;
size_t total_write_len = 0;
for (int i = 0; i < iovcnt; i++) {
#ifdef HELPER_LOG_PACKETS
ESP_LOGVV(TAG, "Sending raw: %s",
format_hex_pretty(reinterpret_cast<uint8_t *>(iov[i].iov_base), iov[i].iov_len).c_str());
#endif
total_write_len += iov[i].iov_len;
}
if (!tx_buf_.empty()) {
// try to empty tx_buf_ first
aerr = try_send_tx_buf_();
if (aerr != APIError::OK && aerr != APIError::WOULD_BLOCK)
return aerr;
}
if (!tx_buf_.empty()) {
// tx buf not empty, can't write now because then stream would be inconsistent
for (int i = 0; i < iovcnt; i++) {
tx_buf_.insert(tx_buf_.end(), reinterpret_cast<uint8_t *>(iov[i].iov_base),
reinterpret_cast<uint8_t *>(iov[i].iov_base) + iov[i].iov_len);
}
return APIError::OK;
}
ssize_t sent = socket_->writev(iov, iovcnt);
if (is_would_block(sent)) {
// operation would block, add buffer to tx_buf
for (int i = 0; i < iovcnt; i++) {
tx_buf_.insert(tx_buf_.end(), reinterpret_cast<uint8_t *>(iov[i].iov_base),
reinterpret_cast<uint8_t *>(iov[i].iov_base) + iov[i].iov_len);
}
return APIError::OK;
} else if (sent == -1) {
// an error occurred
state_ = State::FAILED;
HELPER_LOG("Socket write failed with errno %d", errno);
return APIError::SOCKET_WRITE_FAILED;
} else if ((size_t) sent != total_write_len) {
// partially sent, add end to tx_buf
size_t to_consume = sent;
for (int i = 0; i < iovcnt; i++) {
if (to_consume >= iov[i].iov_len) {
to_consume -= iov[i].iov_len;
} else {
tx_buf_.insert(tx_buf_.end(), reinterpret_cast<uint8_t *>(iov[i].iov_base) + to_consume,
reinterpret_cast<uint8_t *>(iov[i].iov_base) + iov[i].iov_len);
to_consume = 0;
}
}
return APIError::OK;
}
// fully sent
return APIError::OK;
}
APIError APIPlaintextFrameHelper::close() {
state_ = State::CLOSED;
int err = socket_->close();
if (err == -1)
return APIError::CLOSE_FAILED;
return APIError::OK;
}
APIError APIPlaintextFrameHelper::shutdown(int how) {
int err = socket_->shutdown(how);
if (err == -1)
return APIError::SHUTDOWN_FAILED;
if (how == SHUT_RDWR) {
state_ = State::CLOSED;
}
return APIError::OK;
}
#endif // USE_API_PLAINTEXT
} // namespace api
} // namespace esphome