openethereum/hw/src/trezor.rs
Marek Kotewicz e95b093483 dissolve util (#7460)
* ethereum-types refactor in progress

* ethereum-types refactor in progress

* ethereum-types refactor in progress

* ethereum-types refactor in progress

* ethereum-types refactor finished

* removed obsolete util/src/lib.rs

* removed commented out code
2018-01-10 15:35:18 +03:00

441 lines
15 KiB
Rust

// Copyright 2015-2017 Parity Technologies (UK) Ltd.
// This file is part of Parity.
// Parity is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// Parity is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with Parity. If not, see <http://www.gnu.org/licenses/>.
//! Trezor hardware wallet module. Supports Trezor v1.
//! See http://doc.satoshilabs.com/trezor-tech/api-protobuf.html
//! and https://github.com/trezor/trezor-common/blob/master/protob/protocol.md
//! for protocol details.
use super::{WalletInfo, TransactionInfo, KeyPath};
use std::cmp::{min, max};
use std::fmt;
use std::sync::Arc;
use std::time::Duration;
use ethereum_types::{U256, H256, Address};
use ethkey::Signature;
use hidapi;
use parking_lot::{Mutex, RwLock};
use protobuf;
use protobuf::{Message, ProtobufEnum};
use trezor_sys::messages::{EthereumAddress, PinMatrixAck, MessageType, EthereumTxRequest, EthereumSignTx, EthereumGetAddress, EthereumTxAck, ButtonAck};
const TREZOR_VID: u16 = 0x534c;
const TREZOR_PIDS: [u16; 1] = [0x0001]; // Trezor v1, keeping this as an array to leave room for Trezor v2 which is in progress
const ETH_DERIVATION_PATH: [u32; 5] = [0x8000002C, 0x8000003C, 0x80000000, 0, 0]; // m/44'/60'/0'/0/0
const ETC_DERIVATION_PATH: [u32; 5] = [0x8000002C, 0x8000003D, 0x80000000, 0, 0]; // m/44'/61'/0'/0/0
/// Hardware wallet error.
#[derive(Debug)]
pub enum Error {
/// Ethereum wallet protocol error.
Protocol(&'static str),
/// Hidapi error.
Usb(hidapi::HidError),
/// Device with request key is not available.
KeyNotFound,
/// Signing has been cancelled by user.
UserCancel,
/// The Message Type given in the trezor RPC call is not something we recognize
BadMessageType,
/// Trying to read from a closed device at the given path
ClosedDevice(String),
}
impl fmt::Display for Error {
fn fmt(&self, f: &mut fmt::Formatter) -> Result<(), fmt::Error> {
match *self {
Error::Protocol(ref s) => write!(f, "Trezor protocol error: {}", s),
Error::Usb(ref e) => write!(f, "USB communication error: {}", e),
Error::KeyNotFound => write!(f, "Key not found"),
Error::UserCancel => write!(f, "Operation has been cancelled"),
Error::BadMessageType => write!(f, "Bad Message Type in RPC call"),
Error::ClosedDevice(ref s) => write!(f, "Device is closed, needs PIN to perform operations: {}", s),
}
}
}
impl From<hidapi::HidError> for Error {
fn from(err: hidapi::HidError) -> Error {
Error::Usb(err)
}
}
impl From<protobuf::ProtobufError> for Error {
fn from(_: protobuf::ProtobufError) -> Error {
Error::Protocol(&"Could not read response from Trezor Device")
}
}
/// Ledger device manager.
pub struct Manager {
usb: Arc<Mutex<hidapi::HidApi>>,
devices: RwLock<Vec<Device>>,
closed_devices: RwLock<Vec<String>>,
key_path: RwLock<KeyPath>,
}
#[derive(Debug)]
struct Device {
path: String,
info: WalletInfo,
}
/// HID Version used for the Trezor device
enum HidVersion {
V1,
V2,
}
impl Manager {
/// Create a new instance.
pub fn new(hidapi: Arc<Mutex<hidapi::HidApi>>) -> Manager {
Manager {
usb: hidapi,
devices: RwLock::new(Vec::new()),
closed_devices: RwLock::new(Vec::new()),
key_path: RwLock::new(KeyPath::Ethereum),
}
}
/// Re-populate device list
pub fn update_devices(&self) -> Result<usize, Error> {
let mut usb = self.usb.lock();
usb.refresh_devices();
let devices = usb.devices();
let mut new_devices = Vec::new();
let mut closed_devices = Vec::new();
let mut error = None;
for usb_device in devices {
let is_trezor = usb_device.vendor_id == TREZOR_VID;
let is_supported_product = TREZOR_PIDS.contains(&usb_device.product_id);
let is_valid = usb_device.usage_page == 0xFF00 || usb_device.interface_number == 0;
trace!(
"Checking device: {:?}, trezor: {:?}, prod: {:?}, valid: {:?}",
usb_device,
is_trezor,
is_supported_product,
is_valid,
);
if !is_trezor || !is_supported_product || !is_valid {
continue;
}
match self.read_device_info(&usb, &usb_device) {
Ok(device) => new_devices.push(device),
Err(Error::ClosedDevice(path)) => closed_devices.push(path.to_string()),
Err(e) => {
warn!("Error reading device: {:?}", e);
error = Some(e);
}
}
}
let count = new_devices.len();
trace!("Got devices: {:?}, closed: {:?}", new_devices, closed_devices);
*self.devices.write() = new_devices;
*self.closed_devices.write() = closed_devices;
match error {
Some(e) => Err(e),
None => Ok(count),
}
}
fn read_device_info(&self, usb: &hidapi::HidApi, dev_info: &hidapi::HidDeviceInfo) -> Result<Device, Error> {
let handle = self.open_path(|| usb.open_path(&dev_info.path))?;
let manufacturer = dev_info.manufacturer_string.clone().unwrap_or("Unknown".to_owned());
let name = dev_info.product_string.clone().unwrap_or("Unknown".to_owned());
let serial = dev_info.serial_number.clone().unwrap_or("Unknown".to_owned());
match self.get_address(&handle) {
Ok(Some(addr)) => {
Ok(Device {
path: dev_info.path.clone(),
info: WalletInfo {
name: name,
manufacturer: manufacturer,
serial: serial,
address: addr,
},
})
}
Ok(None) => Err(Error::ClosedDevice(dev_info.path.clone())),
Err(e) => Err(e),
}
}
/// Select key derivation path for a known chain.
pub fn set_key_path(&self, key_path: KeyPath) {
*self.key_path.write() = key_path;
}
/// List connected wallets. This only returns wallets that are ready to be used.
pub fn list_devices(&self) -> Vec<WalletInfo> {
self.devices.read().iter().map(|d| d.info.clone()).collect()
}
pub fn list_locked_devices(&self) -> Vec<String> {
(*self.closed_devices.read()).clone()
}
/// Get wallet info.
pub fn device_info(&self, address: &Address) -> Option<WalletInfo> {
self.devices.read().iter().find(|d| &d.info.address == address).map(|d| d.info.clone())
}
fn open_path<R, F>(&self, f: F) -> Result<R, Error>
where F: Fn() -> Result<R, &'static str>
{
let mut err = Error::KeyNotFound;
// Try to open device a few times.
for _ in 0..10 {
match f() {
Ok(handle) => return Ok(handle),
Err(e) => err = From::from(e),
}
::std::thread::sleep(Duration::from_millis(200));
}
Err(err)
}
pub fn pin_matrix_ack(&self, device_path: &str, pin: &str) -> Result<bool, Error> {
let unlocked = {
let usb = self.usb.lock();
let device = self.open_path(|| usb.open_path(&device_path))?;
let t = MessageType::MessageType_PinMatrixAck;
let mut m = PinMatrixAck::new();
m.set_pin(pin.to_string());
self.send_device_message(&device, &t, &m)?;
let (resp_type, _) = self.read_device_response(&device)?;
match resp_type {
// Getting an Address back means it's unlocked, this is undocumented behavior
MessageType::MessageType_EthereumAddress => Ok(true),
// Getting anything else means we didn't unlock it
_ => Ok(false),
}
};
self.update_devices()?;
unlocked
}
fn get_address(&self, device: &hidapi::HidDevice) -> Result<Option<Address>, Error> {
let typ = MessageType::MessageType_EthereumGetAddress;
let mut message = EthereumGetAddress::new();
match *self.key_path.read() {
KeyPath::Ethereum => message.set_address_n(ETH_DERIVATION_PATH.to_vec()),
KeyPath::EthereumClassic => message.set_address_n(ETC_DERIVATION_PATH.to_vec()),
}
message.set_show_display(false);
self.send_device_message(&device, &typ, &message)?;
let (resp_type, bytes) = self.read_device_response(&device)?;
match resp_type {
MessageType::MessageType_EthereumAddress => {
let response: EthereumAddress = protobuf::core::parse_from_bytes(&bytes)?;
Ok(Some(From::from(response.get_address())))
}
_ => Ok(None),
}
}
/// Sign transaction data with wallet managing `address`.
pub fn sign_transaction(&self, address: &Address, t_info: &TransactionInfo) -> Result<Signature, Error> {
let usb = self.usb.lock();
let devices = self.devices.read();
let device = devices.iter().find(|d| &d.info.address == address).ok_or(Error::KeyNotFound)?;
let handle = self.open_path(|| usb.open_path(&device.path))?;
let msg_type = MessageType::MessageType_EthereumSignTx;
let mut message = EthereumSignTx::new();
match *self.key_path.read() {
KeyPath::Ethereum => message.set_address_n(ETH_DERIVATION_PATH.to_vec()),
KeyPath::EthereumClassic => message.set_address_n(ETC_DERIVATION_PATH.to_vec()),
}
message.set_nonce(self.u256_to_be_vec(&t_info.nonce));
message.set_gas_limit(self.u256_to_be_vec(&t_info.gas_limit));
message.set_gas_price(self.u256_to_be_vec(&t_info.gas_price));
message.set_value(self.u256_to_be_vec(&t_info.value));
match t_info.to {
Some(addr) => {
message.set_to(addr.to_vec())
}
None => (),
}
let first_chunk_length = min(t_info.data.len(), 1024);
let chunk = &t_info.data[0..first_chunk_length];
message.set_data_initial_chunk(chunk.to_vec());
message.set_data_length(t_info.data.len() as u32);
if let Some(c_id) = t_info.chain_id {
message.set_chain_id(c_id as u32);
}
self.send_device_message(&handle, &msg_type, &message)?;
self.signing_loop(&handle, &t_info.chain_id, &t_info.data[first_chunk_length..])
}
fn u256_to_be_vec(&self, val: &U256) -> Vec<u8> {
let mut buf = [0u8; 32];
val.to_big_endian(&mut buf);
buf.iter().skip_while(|x| **x == 0).cloned().collect()
}
fn signing_loop(&self, handle: &hidapi::HidDevice, chain_id: &Option<u64>, data: &[u8]) -> Result<Signature, Error> {
let (resp_type, bytes) = self.read_device_response(&handle)?;
match resp_type {
MessageType::MessageType_Cancel => Err(Error::UserCancel),
MessageType::MessageType_ButtonRequest => {
self.send_device_message(handle, &MessageType::MessageType_ButtonAck, &ButtonAck::new())?;
// Signing loop goes back to the top and reading blocks
// for up to 5 minutes waiting for response from the device
// if the user doesn't click any button within 5 minutes you
// get a signing error and the device sort of locks up on the signing screen
self.signing_loop(handle, chain_id, data)
}
MessageType::MessageType_EthereumTxRequest => {
let resp: EthereumTxRequest = protobuf::core::parse_from_bytes(&bytes)?;
if resp.has_data_length() {
let mut msg = EthereumTxAck::new();
let len = resp.get_data_length() as usize;
msg.set_data_chunk(data[..len].to_vec());
self.send_device_message(handle, &MessageType::MessageType_EthereumTxAck, &msg)?;
self.signing_loop(handle, chain_id, &data[len..])
} else {
let v = resp.get_signature_v();
let r = H256::from_slice(resp.get_signature_r());
let s = H256::from_slice(resp.get_signature_s());
if let Some(c_id) = *chain_id {
// If there is a chain_id supplied, Trezor will return a v
// part of the signature that is already adjusted for EIP-155,
// so v' = v + 2 * chain_id + 35, but code further down the
// pipeline will already do this transformation, so remove it here
let adjustment = 35 + 2 * c_id as u32;
Ok(Signature::from_rsv(&r, &s, (max(v, adjustment) - adjustment) as u8))
} else {
// If there isn't a chain_id, v will be returned as v + 27
let adjusted_v = if v < 27 { v } else { v - 27 };
Ok(Signature::from_rsv(&r, &s, adjusted_v as u8))
}
}
}
MessageType::MessageType_Failure => Err(Error::Protocol("Last message sent to Trezor failed")),
_ => Err(Error::Protocol("Unexpected response from Trezor device.")),
}
}
fn send_device_message(&self, device: &hidapi::HidDevice, msg_type: &MessageType, msg: &Message) -> Result<usize, Error> {
let msg_id = *msg_type as u16;
let mut message = msg.write_to_bytes()?;
let msg_size = message.len();
let mut data = Vec::new();
let hid_version = self.probe_hid_version(device)?;
// Magic constants
data.push('#' as u8);
data.push('#' as u8);
// Convert msg_id to BE and split into bytes
data.push(((msg_id >> 8) & 0xFF) as u8);
data.push((msg_id & 0xFF) as u8);
// Convert msg_size to BE and split into bytes
data.push(((msg_size >> 24) & 0xFF) as u8);
data.push(((msg_size >> 16) & 0xFF) as u8);
data.push(((msg_size >> 8) & 0xFF) as u8);
data.push((msg_size & 0xFF) as u8);
data.append(&mut message);
while data.len() % 63 > 0 {
data.push(0);
}
let mut total_written = 0;
for chunk in data.chunks(63) {
let mut padded_chunk = match hid_version {
HidVersion::V1 => vec!['?' as u8],
HidVersion::V2 => vec![0, '?' as u8],
};
padded_chunk.extend_from_slice(&chunk);
total_written += device.write(&padded_chunk)?;
}
Ok(total_written)
}
fn probe_hid_version(&self, device: &hidapi::HidDevice) -> Result<HidVersion, Error> {
let mut buf2 = [0xFFu8; 65];
buf2[0] = 0;
buf2[1] = 63;
let mut buf1 = [0xFFu8; 64];
buf1[0] = 63;
if device.write(&buf2)? == 65 {
Ok(HidVersion::V2)
} else if device.write(&buf1)? == 64 {
Ok(HidVersion::V1)
} else {
Err(Error::Usb("Unable to determine HID Version"))
}
}
fn read_device_response(&self, device: &hidapi::HidDevice) -> Result<(MessageType, Vec<u8>), Error> {
let protocol_err = Error::Protocol(&"Unexpected wire response from Trezor Device");
let mut buf = vec![0; 64];
let first_chunk = device.read_timeout(&mut buf, 300_000)?;
if first_chunk < 9 || buf[0] != '?' as u8 || buf[1] != '#' as u8 || buf[2] != '#' as u8 {
return Err(protocol_err);
}
let msg_type = MessageType::from_i32(((buf[3] as i32 & 0xFF) << 8) + (buf[4] as i32 & 0xFF)).ok_or(protocol_err)?;
let msg_size = ((buf[5] as u32 & 0xFF) << 24) + ((buf[6] as u32 & 0xFF) << 16) + ((buf[7] as u32 & 0xFF) << 8) + (buf[8] as u32 & 0xFF);
let mut data = Vec::new();
data.extend_from_slice(&buf[9..]);
while data.len() < (msg_size as usize) {
device.read_timeout(&mut buf, 10_000)?;
data.extend_from_slice(&buf[1..]);
}
Ok((msg_type, data[..msg_size as usize].to_vec()))
}
}
#[test]
#[ignore]
/// This test can't be run without an actual trezor device connected
/// (and unlocked) attached to the machine that's running the test
fn test_signature() {
use ethereum_types::{H160, H256, U256};
let hidapi = Arc::new(Mutex::new(hidapi::HidApi::new().unwrap()));
let manager = Manager::new(hidapi.clone());
let addr: Address = H160::from("some_addr");
manager.update_devices().unwrap();
let t_info = TransactionInfo {
nonce: U256::from(1),
gas_price: U256::from(100),
gas_limit: U256::from(21_000),
to: Some(H160::from("some_other_addr")),
chain_id: Some(17),
value: U256::from(1_000_000),
data: (&[1u8; 3000]).to_vec(),
};
let signature = manager.sign_transaction(&addr, &t_info).unwrap();
let expected = Signature::from_rsv(
&H256::from("device_specific_r"),
&H256::from("device_specific_s"),
0x01
);
assert_eq!(signature, expected)
}