Transaction Hash:
Block:
17326725 at May-24-2023 04:37:47 AM +UTC
Transaction Fee:
0.00105134219073382 ETH
$2.09
Gas Used:
31,093 Gas / 33.81282574 Gwei
Emitted Events:
| 168 |
EthCustodian.Deposited( sender=[Sender] 0x112bb5dd677ec044f24c045db1a0ab3b167841ea, recipient=aurora:112bb5dd677ec044f24c045db1a0ab3b167841ea, amount=50000000000000000, fee=0 )
|
Account State Difference:
| Address | Before | After | State Difference | ||
|---|---|---|---|---|---|
| 0x112bB5dD...b167841eA |
0.070425480896362934 Eth
Nonce: 363
|
0.019374138705629114 Eth
Nonce: 364
| 0.05105134219073382 | ||
| 0x6BFaD42c...A8B89FA52 | 9,540.284158245336056702 Eth | 9,540.334158245336056702 Eth | 0.05 | ||
|
0xDAFEA492...692c98Bc5
Miner
| (Flashbots: Builder) | 0.053570829584656528 Eth | 0.053573938884656528 Eth | 0.0000031093 |
Execution Trace
ETH 0.05
EthCustodian.depositToEVM( ethRecipientOnNear=112bb5dd677ec044f24c045db1a0ab3b167841ea, fee=0 )
depositToEVM[EthCustodian (ln:45)]
Deposited[EthCustodian (ln:64)]
// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.6.12;
import 'rainbow-bridge/contracts/eth/nearbridge/contracts/AdminControlled.sol';
import 'rainbow-bridge/contracts/eth/nearbridge/contracts/Borsh.sol';
import 'rainbow-bridge/contracts/eth/nearprover/contracts/ProofDecoder.sol';
import { INearProver, ProofKeeper } from './ProofKeeper.sol';
contract EthCustodian is ProofKeeper, AdminControlled {
uint constant UNPAUSED_ALL = 0;
uint constant PAUSED_DEPOSIT_TO_EVM = 1 << 0;
uint constant PAUSED_DEPOSIT_TO_NEAR = 1 << 1;
uint constant PAUSED_WITHDRAW = 1 << 2;
event Deposited (
address indexed sender,
string recipient,
uint256 amount,
uint256 fee
);
event Withdrawn(
address indexed recipient,
uint128 amount
);
// Function output from burning nETH on Near side.
struct BurnResult {
uint128 amount;
address recipient;
address ethCustodian;
}
/// EthCustodian is linked to the EVM on NEAR side.
/// It also links to the prover that it uses to withdraw the tokens.
constructor(
bytes memory nearEvm,
INearProver prover,
uint64 minBlockAcceptanceHeight,
address _admin,
uint pausedFlags
)
AdminControlled(_admin, pausedFlags)
ProofKeeper(nearEvm, prover, minBlockAcceptanceHeight)
public
{
}
/// Deposits the specified amount of provided ETH (except from the relayer's fee) into the smart contract.
/// `ethRecipientOnNear` - the ETH address of the recipient in NEAR EVM
/// `fee` - the amount of fee that will be paid to the near-relayer in nETH.
function depositToEVM(
string memory ethRecipientOnNear,
uint256 fee
)
external
payable
pausable(PAUSED_DEPOSIT_TO_EVM)
{
require(
fee < msg.value,
'The fee cannot be bigger than the transferred amount.'
);
string memory separator = ':';
string memory protocolMessage = string(
abi.encodePacked(
string(nearProofProducerAccount_),
separator, ethRecipientOnNear
)
);
emit Deposited(
msg.sender,
protocolMessage,
msg.value,
fee
);
}
/// Deposits the specified amount of provided ETH (except from the relayer's fee) into the smart contract.
/// `nearRecipientAccountId` - the AccountID of the recipient in NEAR
/// `fee` - the amount of fee that will be paid to the near-relayer in nETH.
function depositToNear(
string memory nearRecipientAccountId,
uint256 fee
)
external
payable
pausable(PAUSED_DEPOSIT_TO_NEAR)
{
require(
fee < msg.value,
'The fee cannot be bigger than the transferred amount.'
);
emit Deposited(
msg.sender,
nearRecipientAccountId,
msg.value,
fee
);
}
/// Withdraws the appropriate amount of ETH which is encoded in `proofData`
function withdraw(
bytes calldata proofData,
uint64 proofBlockHeight
)
external
pausable(PAUSED_WITHDRAW)
{
ProofDecoder.ExecutionStatus memory status = _parseAndConsumeProof(proofData, proofBlockHeight);
BurnResult memory result = _decodeBurnResult(status.successValue);
require(
result.ethCustodian == address(this),
'Can only withdraw coins that were expected for the current contract'
);
payable(result.recipient).transfer(result.amount);
emit Withdrawn(
result.recipient,
result.amount
);
}
function _decodeBurnResult(bytes memory data)
internal
pure
returns (BurnResult memory result)
{
Borsh.Data memory borshData = Borsh.from(data);
result.amount = borshData.decodeU128();
bytes20 recipient = borshData.decodeBytes20();
result.recipient = address(uint160(recipient));
bytes20 ethCustodian = borshData.decodeBytes20();
result.ethCustodian = address(uint160(ethCustodian));
}
}
pragma solidity ^0.6;
contract AdminControlled {
address public admin;
uint public paused;
constructor(address _admin, uint flags) public {
admin = _admin;
paused = flags;
}
modifier onlyAdmin {
require(msg.sender == admin);
_;
}
modifier pausable(uint flag) {
require((paused & flag) == 0 || msg.sender == admin);
_;
}
function adminPause(uint flags) public onlyAdmin {
paused = flags;
}
function adminSstore(uint key, uint value) public onlyAdmin {
assembly {
sstore(key, value)
}
}
function adminSstoreWithMask(
uint key,
uint value,
uint mask
) public onlyAdmin {
assembly {
let oldval := sload(key)
sstore(key, xor(and(xor(value, oldval), mask), oldval))
}
}
function adminSendEth(address payable destination, uint amount) public onlyAdmin {
destination.transfer(amount);
}
function adminReceiveEth() public payable onlyAdmin {}
function adminDelegatecall(address target, bytes memory data) public payable onlyAdmin returns (bytes memory) {
(bool success, bytes memory rdata) = target.delegatecall(data);
require(success);
return rdata;
}
}
pragma solidity ^0.6;
import "@openzeppelin/contracts/math/SafeMath.sol";
library Borsh {
using SafeMath for uint256;
struct Data {
uint256 offset;
bytes raw;
}
function from(bytes memory data) internal pure returns (Data memory) {
return Data({offset: 0, raw: data});
}
modifier shift(Data memory data, uint256 size) {
require(data.raw.length >= data.offset + size, "Borsh: Out of range");
_;
data.offset += size;
}
function finished(Data memory data) internal pure returns (bool) {
return data.offset == data.raw.length;
}
function peekKeccak256(Data memory data, uint256 length) internal pure returns (bytes32 res) {
return bytesKeccak256(data.raw, data.offset, length);
}
function bytesKeccak256(
bytes memory ptr,
uint256 offset,
uint256 length
) internal pure returns (bytes32 res) {
// solium-disable-next-line security/no-inline-assembly
assembly {
res := keccak256(add(add(ptr, 32), offset), length)
}
}
function peekSha256(Data memory data, uint256 length) internal view returns (bytes32) {
return bytesSha256(data.raw, data.offset, length);
}
function bytesSha256(
bytes memory ptr,
uint256 offset,
uint256 length
) internal view returns (bytes32) {
bytes32[1] memory result;
// solium-disable-next-line security/no-inline-assembly
assembly {
pop(staticcall(gas(), 0x02, add(add(ptr, 32), offset), length, result, 32))
}
return result[0];
}
function decodeU8(Data memory data) internal pure shift(data, 1) returns (uint8 value) {
value = uint8(data.raw[data.offset]);
}
function decodeI8(Data memory data) internal pure shift(data, 1) returns (int8 value) {
value = int8(data.raw[data.offset]);
}
function decodeU16(Data memory data) internal pure returns (uint16 value) {
value = uint16(decodeU8(data));
value |= (uint16(decodeU8(data)) << 8);
}
function decodeI16(Data memory data) internal pure returns (int16 value) {
value = int16(decodeI8(data));
value |= (int16(decodeI8(data)) << 8);
}
function decodeU32(Data memory data) internal pure returns (uint32 value) {
value = uint32(decodeU16(data));
value |= (uint32(decodeU16(data)) << 16);
}
function decodeI32(Data memory data) internal pure returns (int32 value) {
value = int32(decodeI16(data));
value |= (int32(decodeI16(data)) << 16);
}
function decodeU64(Data memory data) internal pure returns (uint64 value) {
value = uint64(decodeU32(data));
value |= (uint64(decodeU32(data)) << 32);
}
function decodeI64(Data memory data) internal pure returns (int64 value) {
value = int64(decodeI32(data));
value |= (int64(decodeI32(data)) << 32);
}
function decodeU128(Data memory data) internal pure returns (uint128 value) {
value = uint128(decodeU64(data));
value |= (uint128(decodeU64(data)) << 64);
}
function decodeI128(Data memory data) internal pure returns (int128 value) {
value = int128(decodeI64(data));
value |= (int128(decodeI64(data)) << 64);
}
function decodeU256(Data memory data) internal pure returns (uint256 value) {
value = uint256(decodeU128(data));
value |= (uint256(decodeU128(data)) << 128);
}
function decodeI256(Data memory data) internal pure returns (int256 value) {
value = int256(decodeI128(data));
value |= (int256(decodeI128(data)) << 128);
}
function decodeBool(Data memory data) internal pure returns (bool value) {
value = (decodeU8(data) != 0);
}
function decodeBytes(Data memory data) internal pure returns (bytes memory value) {
value = new bytes(decodeU32(data));
for (uint i = 0; i < value.length; i++) {
value[i] = byte(decodeU8(data));
}
}
function decodeBytes32(Data memory data) internal pure shift(data, 32) returns (bytes32 value) {
bytes memory raw = data.raw;
uint256 offset = data.offset;
// solium-disable-next-line security/no-inline-assembly
assembly {
value := mload(add(add(raw, 32), offset))
}
}
function decodeBytes20(Data memory data) internal pure returns (bytes20 value) {
for (uint i = 0; i < 20; i++) {
value |= bytes20(byte(decodeU8(data)) & 0xFF) >> (i * 8);
}
}
// Public key
struct SECP256K1PublicKey {
uint256 x;
uint256 y;
}
function decodeSECP256K1PublicKey(Borsh.Data memory data) internal pure returns (SECP256K1PublicKey memory key) {
key.x = decodeU256(data);
key.y = decodeU256(data);
}
struct ED25519PublicKey {
bytes32 xy;
}
function decodeED25519PublicKey(Borsh.Data memory data) internal pure returns (ED25519PublicKey memory key) {
key.xy = decodeBytes32(data);
}
// Signature
struct SECP256K1Signature {
bytes32 r;
bytes32 s;
uint8 v;
}
function decodeSECP256K1Signature(Borsh.Data memory data) internal pure returns (SECP256K1Signature memory sig) {
sig.r = decodeBytes32(data);
sig.s = decodeBytes32(data);
sig.v = decodeU8(data);
}
struct ED25519Signature {
bytes32[2] rs;
}
function decodeED25519Signature(Borsh.Data memory data) internal pure returns (ED25519Signature memory sig) {
sig.rs[0] = decodeBytes32(data);
sig.rs[1] = decodeBytes32(data);
}
}
pragma solidity ^0.6;
import "../../nearbridge/contracts/Borsh.sol";
import "../../nearbridge/contracts/NearDecoder.sol";
library ProofDecoder {
using Borsh for Borsh.Data;
using ProofDecoder for Borsh.Data;
using NearDecoder for Borsh.Data;
struct FullOutcomeProof {
ExecutionOutcomeWithIdAndProof outcome_proof;
MerklePath outcome_root_proof; // TODO: now empty array
BlockHeaderLight block_header_lite;
MerklePath block_proof;
}
function decodeFullOutcomeProof(Borsh.Data memory data) internal view returns (FullOutcomeProof memory proof) {
proof.outcome_proof = data.decodeExecutionOutcomeWithIdAndProof();
proof.outcome_root_proof = data.decodeMerklePath();
proof.block_header_lite = data.decodeBlockHeaderLight();
proof.block_proof = data.decodeMerklePath();
}
struct BlockHeaderLight {
bytes32 prev_block_hash;
bytes32 inner_rest_hash;
NearDecoder.BlockHeaderInnerLite inner_lite;
bytes32 hash; // Computable
}
function decodeBlockHeaderLight(Borsh.Data memory data) internal view returns (BlockHeaderLight memory header) {
header.prev_block_hash = data.decodeBytes32();
header.inner_rest_hash = data.decodeBytes32();
header.inner_lite = data.decodeBlockHeaderInnerLite();
header.hash = sha256(
abi.encodePacked(
sha256(abi.encodePacked(header.inner_lite.hash, header.inner_rest_hash)),
header.prev_block_hash
)
);
}
struct ExecutionStatus {
uint8 enumIndex;
bool unknown;
bool failed;
bytes successValue; /// The final action succeeded and returned some value or an empty vec.
bytes32 successReceiptId; /// The final action of the receipt returned a promise or the signed
/// transaction was converted to a receipt. Contains the receipt_id of the generated receipt.
}
function decodeExecutionStatus(Borsh.Data memory data)
internal
pure
returns (ExecutionStatus memory executionStatus)
{
executionStatus.enumIndex = data.decodeU8();
if (executionStatus.enumIndex == 0) {
executionStatus.unknown = true;
} else if (executionStatus.enumIndex == 1) {
//revert("NearDecoder: decodeExecutionStatus failure case not implemented yet");
// Can avoid revert since ExecutionStatus is latest field in all parent structures
executionStatus.failed = true;
} else if (executionStatus.enumIndex == 2) {
executionStatus.successValue = data.decodeBytes();
} else if (executionStatus.enumIndex == 3) {
executionStatus.successReceiptId = data.decodeBytes32();
} else {
revert("NearDecoder: decodeExecutionStatus index out of range");
}
}
struct ExecutionOutcome {
bytes[] logs; /// Logs from this transaction or receipt.
bytes32[] receipt_ids; /// Receipt IDs generated by this transaction or receipt.
uint64 gas_burnt; /// The amount of the gas burnt by the given transaction or receipt.
uint128 tokens_burnt; /// The total number of the tokens burnt by the given transaction or receipt.
bytes executor_id; /// Hash of the transaction or receipt id that produced this outcome.
ExecutionStatus status; /// Execution status. Contains the result in case of successful execution.
bytes32[] merkelization_hashes;
}
function decodeExecutionOutcome(Borsh.Data memory data) internal view returns (ExecutionOutcome memory outcome) {
outcome.logs = new bytes[](data.decodeU32());
for (uint i = 0; i < outcome.logs.length; i++) {
outcome.logs[i] = data.decodeBytes();
}
uint256 start = data.offset;
outcome.receipt_ids = new bytes32[](data.decodeU32());
for (uint i = 0; i < outcome.receipt_ids.length; i++) {
outcome.receipt_ids[i] = data.decodeBytes32();
}
outcome.gas_burnt = data.decodeU64();
outcome.tokens_burnt = data.decodeU128();
outcome.executor_id = data.decodeBytes();
outcome.status = data.decodeExecutionStatus();
uint256 stop = data.offset;
outcome.merkelization_hashes = new bytes32[](1 + outcome.logs.length);
data.offset = start;
outcome.merkelization_hashes[0] = data.peekSha256(stop - start);
data.offset = stop;
for (uint i = 0; i < outcome.logs.length; i++) {
outcome.merkelization_hashes[i + 1] = sha256(outcome.logs[i]);
}
}
struct ExecutionOutcomeWithId {
bytes32 id; /// The transaction hash or the receipt ID.
ExecutionOutcome outcome;
bytes32 hash;
}
function decodeExecutionOutcomeWithId(Borsh.Data memory data)
internal
view
returns (ExecutionOutcomeWithId memory outcome)
{
outcome.id = data.decodeBytes32();
outcome.outcome = data.decodeExecutionOutcome();
uint256 len = 1 + outcome.outcome.merkelization_hashes.length;
outcome.hash = sha256(
abi.encodePacked(
uint8((len >> 0) & 0xFF),
uint8((len >> 8) & 0xFF),
uint8((len >> 16) & 0xFF),
uint8((len >> 24) & 0xFF),
outcome.id,
outcome.outcome.merkelization_hashes
)
);
}
struct MerklePathItem {
bytes32 hash;
uint8 direction; // 0 = left, 1 = right
}
function decodeMerklePathItem(Borsh.Data memory data) internal pure returns (MerklePathItem memory item) {
item.hash = data.decodeBytes32();
item.direction = data.decodeU8();
require(item.direction < 2, "ProofDecoder: MerklePathItem direction should be 0 or 1");
}
struct MerklePath {
MerklePathItem[] items;
}
function decodeMerklePath(Borsh.Data memory data) internal pure returns (MerklePath memory path) {
path.items = new MerklePathItem[](data.decodeU32());
for (uint i = 0; i < path.items.length; i++) {
path.items[i] = data.decodeMerklePathItem();
}
}
struct ExecutionOutcomeWithIdAndProof {
MerklePath proof;
bytes32 block_hash;
ExecutionOutcomeWithId outcome_with_id;
}
function decodeExecutionOutcomeWithIdAndProof(Borsh.Data memory data)
internal
view
returns (ExecutionOutcomeWithIdAndProof memory outcome)
{
outcome.proof = data.decodeMerklePath();
outcome.block_hash = data.decodeBytes32();
outcome.outcome_with_id = data.decodeExecutionOutcomeWithId();
}
}
// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity ^0.6.12;
import 'rainbow-bridge/contracts/eth/nearprover/contracts/INearProver.sol';
import 'rainbow-bridge/contracts/eth/nearprover/contracts/ProofDecoder.sol';
import 'rainbow-bridge/contracts/eth/nearbridge/contracts/Borsh.sol';
contract ProofKeeper {
using Borsh for Borsh.Data;
using ProofDecoder for Borsh.Data;
INearProver public prover_;
bytes public nearProofProducerAccount_;
/// Proofs from blocks that are below the acceptance height will be rejected.
// If `minBlockAcceptanceHeight_` value is zero - proofs from block with any height are accepted.
uint64 public minBlockAcceptanceHeight_;
// OutcomeReciptId -> Used
mapping(bytes32 => bool) public usedEvents_;
constructor(
bytes memory nearProofProducerAccount,
INearProver prover,
uint64 minBlockAcceptanceHeight
)
public
{
require(
nearProofProducerAccount.length > 0,
'Invalid Near ProofProducer address'
);
require(
address(prover) != address(0),
'Invalid Near prover address'
);
nearProofProducerAccount_ = nearProofProducerAccount;
prover_ = prover;
minBlockAcceptanceHeight_ = minBlockAcceptanceHeight;
}
/// Parses the provided proof and consumes it if it's not already used.
/// The consumed event cannot be reused for future calls.
function _parseAndConsumeProof(
bytes memory proofData,
uint64 proofBlockHeight
)
internal
returns(ProofDecoder.ExecutionStatus memory result)
{
require(
proofBlockHeight >= minBlockAcceptanceHeight_,
'Proof is from the ancient block'
);
require(
prover_.proveOutcome(proofData,proofBlockHeight),
'Proof should be valid'
);
// Unpack the proof and extract the execution outcome.
Borsh.Data memory borshData = Borsh.from(proofData);
ProofDecoder.FullOutcomeProof memory fullOutcomeProof =
borshData.decodeFullOutcomeProof();
require(
borshData.finished(),
'Argument should be exact borsh serialization'
);
bytes32 receiptId =
fullOutcomeProof.outcome_proof.outcome_with_id.outcome.receipt_ids[0];
require(
!usedEvents_[receiptId],
'The burn event cannot be reused'
);
usedEvents_[receiptId] = true;
require(
keccak256(fullOutcomeProof.outcome_proof.outcome_with_id.outcome.executor_id) ==
keccak256(nearProofProducerAccount_),
'Can only withdraw coins from the linked proof producer on Near blockchain'
);
result = fullOutcomeProof.outcome_proof.outcome_with_id.outcome.status;
require(
!result.failed,
'Cannot use failed execution outcome for unlocking the tokens'
);
require(
!result.unknown,
'Cannot use unknown execution outcome for unlocking the tokens'
);
}
}
// SPDX-License-Identifier: MIT
pragma solidity >=0.6.0 <0.8.0;
/**
* @dev Wrappers over Solidity's arithmetic operations with added overflow
* checks.
*
* Arithmetic operations in Solidity wrap on overflow. This can easily result
* in bugs, because programmers usually assume that an overflow raises an
* error, which is the standard behavior in high level programming languages.
* `SafeMath` restores this intuition by reverting the transaction when an
* operation overflows.
*
* Using this library instead of the unchecked operations eliminates an entire
* class of bugs, so it's recommended to use it always.
*/
library SafeMath {
/**
* @dev Returns the addition of two unsigned integers, with an overflow flag.
*
* _Available since v3.4._
*/
function tryAdd(uint256 a, uint256 b) internal pure returns (bool, uint256) {
uint256 c = a + b;
if (c < a) return (false, 0);
return (true, c);
}
/**
* @dev Returns the substraction of two unsigned integers, with an overflow flag.
*
* _Available since v3.4._
*/
function trySub(uint256 a, uint256 b) internal pure returns (bool, uint256) {
if (b > a) return (false, 0);
return (true, a - b);
}
/**
* @dev Returns the multiplication of two unsigned integers, with an overflow flag.
*
* _Available since v3.4._
*/
function tryMul(uint256 a, uint256 b) internal pure returns (bool, uint256) {
// Gas optimization: this is cheaper than requiring 'a' not being zero, but the
// benefit is lost if 'b' is also tested.
// See: https://github.com/OpenZeppelin/openzeppelin-contracts/pull/522
if (a == 0) return (true, 0);
uint256 c = a * b;
if (c / a != b) return (false, 0);
return (true, c);
}
/**
* @dev Returns the division of two unsigned integers, with a division by zero flag.
*
* _Available since v3.4._
*/
function tryDiv(uint256 a, uint256 b) internal pure returns (bool, uint256) {
if (b == 0) return (false, 0);
return (true, a / b);
}
/**
* @dev Returns the remainder of dividing two unsigned integers, with a division by zero flag.
*
* _Available since v3.4._
*/
function tryMod(uint256 a, uint256 b) internal pure returns (bool, uint256) {
if (b == 0) return (false, 0);
return (true, a % b);
}
/**
* @dev Returns the addition of two unsigned integers, reverting on
* overflow.
*
* Counterpart to Solidity's `+` operator.
*
* Requirements:
*
* - Addition cannot overflow.
*/
function add(uint256 a, uint256 b) internal pure returns (uint256) {
uint256 c = a + b;
require(c >= a, "SafeMath: addition overflow");
return c;
}
/**
* @dev Returns the subtraction of two unsigned integers, reverting on
* overflow (when the result is negative).
*
* Counterpart to Solidity's `-` operator.
*
* Requirements:
*
* - Subtraction cannot overflow.
*/
function sub(uint256 a, uint256 b) internal pure returns (uint256) {
require(b <= a, "SafeMath: subtraction overflow");
return a - b;
}
/**
* @dev Returns the multiplication of two unsigned integers, reverting on
* overflow.
*
* Counterpart to Solidity's `*` operator.
*
* Requirements:
*
* - Multiplication cannot overflow.
*/
function mul(uint256 a, uint256 b) internal pure returns (uint256) {
if (a == 0) return 0;
uint256 c = a * b;
require(c / a == b, "SafeMath: multiplication overflow");
return c;
}
/**
* @dev Returns the integer division of two unsigned integers, reverting on
* division by zero. The result is rounded towards zero.
*
* Counterpart to Solidity's `/` operator. Note: this function uses a
* `revert` opcode (which leaves remaining gas untouched) while Solidity
* uses an invalid opcode to revert (consuming all remaining gas).
*
* Requirements:
*
* - The divisor cannot be zero.
*/
function div(uint256 a, uint256 b) internal pure returns (uint256) {
require(b > 0, "SafeMath: division by zero");
return a / b;
}
/**
* @dev Returns the remainder of dividing two unsigned integers. (unsigned integer modulo),
* reverting when dividing by zero.
*
* Counterpart to Solidity's `%` operator. This function uses a `revert`
* opcode (which leaves remaining gas untouched) while Solidity uses an
* invalid opcode to revert (consuming all remaining gas).
*
* Requirements:
*
* - The divisor cannot be zero.
*/
function mod(uint256 a, uint256 b) internal pure returns (uint256) {
require(b > 0, "SafeMath: modulo by zero");
return a % b;
}
/**
* @dev Returns the subtraction of two unsigned integers, reverting with custom message on
* overflow (when the result is negative).
*
* CAUTION: This function is deprecated because it requires allocating memory for the error
* message unnecessarily. For custom revert reasons use {trySub}.
*
* Counterpart to Solidity's `-` operator.
*
* Requirements:
*
* - Subtraction cannot overflow.
*/
function sub(uint256 a, uint256 b, string memory errorMessage) internal pure returns (uint256) {
require(b <= a, errorMessage);
return a - b;
}
/**
* @dev Returns the integer division of two unsigned integers, reverting with custom message on
* division by zero. The result is rounded towards zero.
*
* CAUTION: This function is deprecated because it requires allocating memory for the error
* message unnecessarily. For custom revert reasons use {tryDiv}.
*
* Counterpart to Solidity's `/` operator. Note: this function uses a
* `revert` opcode (which leaves remaining gas untouched) while Solidity
* uses an invalid opcode to revert (consuming all remaining gas).
*
* Requirements:
*
* - The divisor cannot be zero.
*/
function div(uint256 a, uint256 b, string memory errorMessage) internal pure returns (uint256) {
require(b > 0, errorMessage);
return a / b;
}
/**
* @dev Returns the remainder of dividing two unsigned integers. (unsigned integer modulo),
* reverting with custom message when dividing by zero.
*
* CAUTION: This function is deprecated because it requires allocating memory for the error
* message unnecessarily. For custom revert reasons use {tryMod}.
*
* Counterpart to Solidity's `%` operator. This function uses a `revert`
* opcode (which leaves remaining gas untouched) while Solidity uses an
* invalid opcode to revert (consuming all remaining gas).
*
* Requirements:
*
* - The divisor cannot be zero.
*/
function mod(uint256 a, uint256 b, string memory errorMessage) internal pure returns (uint256) {
require(b > 0, errorMessage);
return a % b;
}
}
pragma solidity ^0.6;
import "@openzeppelin/contracts/math/SafeMath.sol";
import "./Borsh.sol";
library NearDecoder {
using Borsh for Borsh.Data;
using NearDecoder for Borsh.Data;
struct PublicKey {
uint8 enumIndex;
Borsh.ED25519PublicKey ed25519;
Borsh.SECP256K1PublicKey secp256k1;
}
function decodePublicKey(Borsh.Data memory data) internal pure returns (PublicKey memory key) {
key.enumIndex = data.decodeU8();
if (key.enumIndex == 0) {
key.ed25519 = data.decodeED25519PublicKey();
} else if (key.enumIndex == 1) {
key.secp256k1 = data.decodeSECP256K1PublicKey();
} else {
revert("NearBridge: Only ED25519 and SECP256K1 public keys are supported");
}
}
struct ValidatorStake {
string account_id;
PublicKey public_key;
uint128 stake;
}
function decodeValidatorStake(Borsh.Data memory data) internal pure returns (ValidatorStake memory validatorStake) {
validatorStake.account_id = string(data.decodeBytes());
validatorStake.public_key = data.decodePublicKey();
validatorStake.stake = data.decodeU128();
}
struct OptionalValidatorStakes {
bool none;
ValidatorStake[] validatorStakes;
bytes32 hash; // Additional computable element
}
function decodeOptionalValidatorStakes(Borsh.Data memory data)
internal
view
returns (OptionalValidatorStakes memory stakes)
{
stakes.none = (data.decodeU8() == 0);
if (!stakes.none) {
uint256 start = data.offset;
stakes.validatorStakes = new ValidatorStake[](data.decodeU32());
for (uint i = 0; i < stakes.validatorStakes.length; i++) {
stakes.validatorStakes[i] = data.decodeValidatorStake();
}
uint256 stop = data.offset;
data.offset = start;
stakes.hash = data.peekSha256(stop - start);
data.offset = stop;
}
}
struct Signature {
uint8 enumIndex;
Borsh.ED25519Signature ed25519;
Borsh.SECP256K1Signature secp256k1;
}
function decodeSignature(Borsh.Data memory data) internal pure returns (Signature memory sig) {
sig.enumIndex = data.decodeU8();
if (sig.enumIndex == 0) {
sig.ed25519 = data.decodeED25519Signature();
} else if (sig.enumIndex == 1) {
sig.secp256k1 = data.decodeSECP256K1Signature();
} else {
revert("NearBridge: Only ED25519 and SECP256K1 signatures are supported");
}
}
struct OptionalSignature {
bool none;
Signature signature;
}
function decodeOptionalSignature(Borsh.Data memory data) internal pure returns (OptionalSignature memory sig) {
sig.none = (data.decodeU8() == 0);
if (!sig.none) {
sig.signature = data.decodeSignature();
}
}
struct LightClientBlock {
bytes32 prev_block_hash;
bytes32 next_block_inner_hash;
BlockHeaderInnerLite inner_lite;
bytes32 inner_rest_hash;
OptionalValidatorStakes next_bps;
OptionalSignature[] approvals_after_next;
bytes32 hash;
bytes32 next_hash;
}
struct InitialValidators {
ValidatorStake[] validator_stakes;
}
function decodeInitialValidators(Borsh.Data memory data)
internal
view
returns (InitialValidators memory validators)
{
validators.validator_stakes = new ValidatorStake[](data.decodeU32());
for (uint i = 0; i < validators.validator_stakes.length; i++) {
validators.validator_stakes[i] = data.decodeValidatorStake();
}
}
function decodeLightClientBlock(Borsh.Data memory data) internal view returns (LightClientBlock memory header) {
header.prev_block_hash = data.decodeBytes32();
header.next_block_inner_hash = data.decodeBytes32();
header.inner_lite = data.decodeBlockHeaderInnerLite();
header.inner_rest_hash = data.decodeBytes32();
header.next_bps = data.decodeOptionalValidatorStakes();
header.approvals_after_next = new OptionalSignature[](data.decodeU32());
for (uint i = 0; i < header.approvals_after_next.length; i++) {
header.approvals_after_next[i] = data.decodeOptionalSignature();
}
header.hash = sha256(
abi.encodePacked(
sha256(abi.encodePacked(header.inner_lite.hash, header.inner_rest_hash)),
header.prev_block_hash
)
);
header.next_hash = sha256(abi.encodePacked(header.next_block_inner_hash, header.hash));
}
struct BlockHeaderInnerLite {
uint64 height; /// Height of this block since the genesis block (height 0).
bytes32 epoch_id; /// Epoch start hash of this block's epoch. Used for retrieving validator information
bytes32 next_epoch_id;
bytes32 prev_state_root; /// Root hash of the state at the previous block.
bytes32 outcome_root; /// Root of the outcomes of transactions and receipts.
uint64 timestamp; /// Timestamp at which the block was built.
bytes32 next_bp_hash; /// Hash of the next epoch block producers set
bytes32 block_merkle_root;
bytes32 hash; // Additional computable element
}
function decodeBlockHeaderInnerLite(Borsh.Data memory data)
internal
view
returns (BlockHeaderInnerLite memory header)
{
header.hash = data.peekSha256(208);
header.height = data.decodeU64();
header.epoch_id = data.decodeBytes32();
header.next_epoch_id = data.decodeBytes32();
header.prev_state_root = data.decodeBytes32();
header.outcome_root = data.decodeBytes32();
header.timestamp = data.decodeU64();
header.next_bp_hash = data.decodeBytes32();
header.block_merkle_root = data.decodeBytes32();
}
}
pragma solidity ^0.6;
interface INearProver {
function proveOutcome(bytes calldata proofData, uint64 blockHeight) external view returns (bool);
}