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Gnosis
A reentrancy vulnerability exists, since checkSignatures
is called before nonce
is incremented:
https://github.com/gnosis/safe-contracts/blob/v0.1.0/contracts/GnosisSafe.sol#L90-L92
Here checkSignatures
can call an external contract, ISignatureValidator.isValidSignature()
:
https://github.com/gnosis/safe-contracts/blob/v0.1.0/contracts/GnosisSafe.sol#L161
which may initiate the same transaction using the same calldata, where nonce
will remain the same, and thus the same txHashData
will be generated, allowing the same signatures to be used to approve the same transaction multiple times.
At least, a malicious owner can execute a transaction multiple times, without the approval of the other owners, as long as gas remains. Moreover, if a benign owner calls another malicious contract for the signature validation, the malicious contract can exploit it even if he is not an owner.
Recommendation:
Increment nonce
before calling checkSignatures
.
- Suppose we have a Gnosis safe managed by several owners, which controls access to an account that holds ERC20 tokens. At some point they agree to transfer X tokens from the safe to the personal account of owner 1.
Conditions required for this attack to be possible: (a). Owner 1 is a contract that uses EIP-1271 signature validation mechanism. (b). All other owners use either EIP-1271 or ECSDA signatures. (See this page for the 3 types of signature validation.)
-
Owner 1 generates the transaction data for this transfer and ensures that allocated gas is 10x required amount to complete the transaction.
-
Owner 1 requests signatures for this transaction from the other owners.
-
Owner 1 registers a malicious
ISignatureValidator
contract into his own account, that once invoked, will call the Gnosis Safe with the same call data as long as there is enough gas, then return true. -
Owner 1 generates a signature for the transaction, of type EIP-1271, e.g. it will call the
ISignatureValidator
. -
Owner 1 calls the Gnosis Safe with the transaction data and all the signatures.
-
During signature verification phase, Gnosis Safe invokes the malicious ISignatureValidator, that successfully calls the safe again with the same data, recursively, 9 more times.
-
In the end, Owner 1 receives into his account 10X the amount of tokens approved by the other owners.
In this attack vector the account that initiated the transaction can consume large amounts of gas for free, unnoticed by other owners, and possibly receive a refund larger than the amount of gas consumed.
The attack is possible due to the following factors:
- At the end of
execTransaction
a refund is emitted for the amount of gas consumed during the transaction. - By default refund is sent to
tx.origin
, e.g. the non-contract account that initiated the transaction, but this can be overridden by transaction parameterrefundReceiver
. - Refund can be sent in either ether or another token, in which case token and conversion rate are given by transaction parameters
gasToken
andgasPrice
. If token is used, refund is sent throughERC20
functiontransfer
. - The gas cap for the external call managed by this transaction is given by transaction parameter
safeTxGas
. - All transaction parameters are part of transaction signature that has to be approved by the
threshold
amount of owners. - However, the external call managed by the transaction is not the only external call performed. If a signature is verified using
EIP-1271
, then an external call toISignatureValidator
will be performed duringcheckSignatures
. - The call to
ISignatureValidator
does not have a gas cap. - The total gas allocated for the transaction is not part of transaction signature.
Consequently, the transaction initiator can setup a malicious ISignatureValidator
for his own account, that consumes a large amount of gas. Let's say almost maximum gas for a block. For transactions initiated by him, he will use EIP-1271 signature validation and will allocate enough gas to cover the cost of useful payload and of malicious ISignatureValidator
. At the end of transaction he will get refunded for all the consumed gas, from the SafeContracts account. Other owners won't be aware of how much gas was consumed, because allocated gas is not part of validated signature.
Up to this point the malicious owner cannot get any financial benefit other than executing some payload for free. However, the custom refund options give room for more abuse.
One customization allows getting a refund in some different token. It is realistic to assume that gasPrice
for the refund token could be higher than the market value. For example because it was not updated for a long time and gasPrice
no longer reflects the actual market value of the token. At the same time owners might consider this discrepancy irrelevant for example because gas price was always small and there was no need to be precise. If the expensive ISignatureValidator is used combined with token refund and outdated gasPrice, the transaction initiator can get a refund many times larger than the Ethereum block size.
The other customization allows sending the refund to a different account than tx.origin
. If it is the same account that controls ISignatureValidator
actual implementation, and is not under the control of the transaction initiator, then abuse can happen without the knowledge of any owner.
The maximum gain an attacker may get from this vulnerability is block_gas_limit * (actual_token_value - gasPrice)
, so is likely small. That is why we don't classify it as critical vulnerability. However it is a valid attack vector.
One possible solution is to limit available gas when calling ISignatureValidator
to a small predetermined value.
execTransaction
does not reject the case of to
being the zero address 0x0
, which may lead to an internal transaction to the zero address, via the following function call sequence:
- https://github.com/gnosis/safe-contracts/blob/v0.1.0/contracts/GnosisSafe.sol#L95
- https://github.com/gnosis/safe-contracts/blob/v0.1.0/contracts/base/Executor.sol#L17
- https://github.com/gnosis/safe-contracts/blob/v0.1.0/contracts/base/Executor.sol#L33
Unlike a regular transaction to the zero address, which creates a new account, an internal transaction to the zero address behaves the same as other transactions to non-zero addresses, i.e., sending the ether to the zero address account (which indeed exists: https://etherscan.io/address/0x0000000000000000000000000000000000000000) and executing the code associated to it (which is empty in this case).
Although it is the users' responsibility that ensures correctness of the transaction data, it is quite possible that a certain user may not be aware of the difference between regular and internal transactions to the zero address, sending a transaction data to execTransaction
with to == 0x0
, expecting that it creates a new account. Since an internal transaction to the zero address mostly succeeds (note that it spends a little gas, without needing to pay the G_newaccount
(25,000) gas fee since the zero-address account already exists), it may cause the ether stuck at 0x0, which could be serious when the user attaches a large amount of ether as a startup fund for the new account.
Recommendation:
- reject
execTransaction
whento == address(0)
.
handlePayment
may send the ether to receiver
:
where receiver
is non-zero, since tx.origin
cannot be zero.
But, receiver
could be still a non-owned account, especially one of the precompiled (0x1 - 0x8) contract addresses.
Here receiver.send(amount)
will succeed even with the small gas stipend 2300 for some precompiled contracts (at least, for 0x2, 0x3, 0x4, and 0x6). Below is the gas cost for executing each precompiled contract.
- 0x1: ECREC: 3000
- 0x2: SHA256: 60 + 12 * (byte-size-of-call-data)
- 0x3: RIP160: 600 + 120 * (byte-size-of-call-data)
- 0x4: ID: 15 + 3 * (byte-size-of-call-data)
- 0x5: MODEXP: (complex-gas-cost-model)
- 0x6: ECADD: 500
- 0x7: ECMUL: 40000
- 0x8: ECPAIRING: 100000 + ...
checkSignatures
checks only the first threshold
number of signatures.
Thus, the validity of the remaining signatures does not matter.
Also, the sortedness of the whole signatures is not required, as long as the first threshold
number of signatures are locally sorted.
However, we have not found an attack exploiting this.
Another questionable behavior is in the case where there are threshold
valid signatures in total, but some of them at the beginning are invalid. Currently, checkSignatures
fails in this case.
A potential issue for this behavior is that a bad owner intentionally sends an invalid signature to veto the transaction. He can always veto if his address is the first (the smallest) among the owners. On the other hand, a good owner is hard to veto some bad transaction if his address is the last (the lartest) among the owners.
Is this intended?
According to the signature encoding scheme, a signature with 2 <= v <= 26
is not valid, but the code does not have an explicit check for the case, relying on ecrecover
to implicitly reject the case. It may be considered to have the explicit check for the robustness, if the additional gas cost is affordable, since we have not verified the underlying C implementation of secp256k1, and there might exist unknown zero-day vulnerabilities (especially for the unusual cases).
For the following code:
if (!ISignatureValidator(currentOwner).isValidSignature(data, contractSignature)) {
It is not clear what will happen if the external isValidSignature
function does not return at all.
Similarly, what if the currentOwner
contract does not implement isValidSignature
function at all, but have the default fallback function? (Note that the default fallback function cannot return anything.)
It depends on the bytecode behavior.
If the bytecode does not reset the return memory address, it may reuse the garbage value previously returned by the lastOwner.isValidSignature
, and it is exploitable.
Even if the current Solidity compiler generates the robust bytecode, a future version may not. Thus, it is required to re-verify the bytecode once the compiler version is updated.
In the current bytecode, it checks the existence of the return value using returndatasize
:
https://github.com/runtimeverification/verified-smart-contracts/blob/master/gnosis/generated/GnosisSafe.evm#L9704-L9721
In checkSignatures
, the argument signatures
is first loaded into the local memory from the call data (not into the stack). Then, when it calls isValidSignature
, it performs the memory-to-memory copy to prepare for the contractSignature
argument (part of the signatures
bytes). Now, it is required in the bytecode that these two memory regions do not overlap. Otherwise the memory-to-memory copy is not sound.
It also depends on the compiler version.
Considering the current max block gas limit (~8M) and the gas cost for the local memory usage (i.e., n^2/512 + 3n
for n
bytes), the size of signatures
must be (much) less than 2^16 (i.e., 64KB).
We first define the-first-invalid-signature-index
as follows:
- A1: for all
i < the-first-invalid-signature-index
,signatures[i]
is valid. - A2:
signatures[the-first-invalid-signature-index]
is NOT valid.
Now we formulate the behavior of checkSignatures
as follows:
- T1:
checkSignatures
returns true ifthe-first-invalid-signature-index >= threshold
. - T2: otherwise, returns false.
To prove that, we need the loop invariant as follows:
For some i
such that 0 <= i < threshold
and i <= the-first-invalid-signature-index
:
- L1: if
i < threshold <= the-first-invalid-signature-index
, then return true. - L1: else (i.e., if
i <= the-first-invalid-signature-index < threshold
), then return false.
====
Proof sketch.
The top level specification:
- T1: by L1 with
i = 0
. - T2: by L2 with
i = 0
.
The loop invariant:
- L1:
By A1, signatures[i] is valid. Then by M1, it goes back to the loop head, and we have two cases:
- Case 1:
i + 1 = threshold
: it jumps out of the loop, and return true. - Case 2:
i + 1 < threshold
: by circular reasoning with L1.
- Case 1:
- L2:
- Case 1:
i = the-first-invalid-signature-index
: By A2, signatures[i] is NOT valid. Then, by M2, we conclude. - Case 2:
i < the-first-invalid-signature-index
: By A1, signatures[i] is valid. Then, by M1, it goes to the loop head, and by the circular reasoning with L2, we conclude (since we know thati + 1 <= the-first-invalid-signature-index < threshold
).
- Case 1:
We need to prove the following claims, but it can be done with looking at the loop body only.
- M1: if signatures[i] is valid, it continues to the next iteration (i.e., goes back to the loop head).
- M2: if signatures[i] is NOT valid, it returns false.
[checkSignatures]
pc: PC_FUN_BEGIN => PC_FUN_END
wordStack: CONSUME_HASH : DATA_HASH : WS => RESULT : WS ; some arguments on stack (?)
localMem: MEM:IMap => storeRange(MEM, HAVOC_START, HAVOC_WIDTH, _) ; localMem is updated but we don't care (?)
proxy_storage: STORAGE:IMap ; storage is not updated (?)
+requires: ; some arguments on memory (?)
andBool selectRange(MEM, DATA_LOC, DATA_WIDTH) ==K DATA_BUF
andBool selectRange(MEM, SIGS_LOC, SIGS_WIDTH) ==K SIGS_BUF
andBool select(STORAGE, #hashedLocation({COMPILER}, {THRESHOLD}, .IntList)) ==Int THRESHOLD
[checkSignatures-success]
+requires:
andBool #fii(SIGS_BUF, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER) >=Int THRESHOLD
+ensures:
andBool RESULT ==Int 1
[checkSignatures-failure]
+requires:
andBool #fii(SIGS_BUF, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER) <Int THRESHOLD
+ensures:
andBool RESULT ==Int 0
[checkSignatures-loop]
pc: PC_LOOP_HEAD => PC_FUN_END ; no meaningful stuff after the loop
+requires:
andBool 0 <=Int I andBool I <Int THRESHOLD
andBool I <=Int #fii(SIGS_BUF, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
[checkSignatures-loop-success]
+requires:
andBool #fii(SIGS_BUF, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER) >=Int THRESHOLD
+ensures:
andBool RESULT ==Int 1
[checkSignatures-loop-failure]
+requires:
andBool #fii(SIGS_BUF, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER) <Int THRESHOLD
+ensures:
andBool RESULT ==Int 0
[checkSignatures-loop-body]
+requires:
andBool CURRENT_OWNER ==Int #signer(SIGS_BUF, I)
[checkSignatures-loop-body-success]
pc: PC_LOOP_HEAD
wordStack: (LAST_OWNER => CURRENT_OWNER) : (I => I +Int 1) : WS
+requires:
andBool #isValid(SIGS_BUF, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
[checkSignatures-loop-body-failure]
pc: PC_LOOP_HEAD => PC_FUN_END
wordStack: LAST_OWNER : I : WS
+requires:
andBool notBool #isValid(SIGS_BUF, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
+ensures:
andBool RESULT ==Int 0
; syntax Int ::= #fii ( WordStack , Int , WordStack , IMap , Int ) [function, smtlib(fii)] // first-invalid-signature-index
; syntax Bool ::= #isValid ( WordStack , Int , WordStack , IMap , Int ) [function, smtlib(isValid)]
; syntax Bool ::= #isValidSig ( WordStack , Int , WordStack , IMap , Int ) [function, smtlib(isValidSig)]
; syntax Bool ::= #isValidSignature ( Int , WordStack , WordStack ) [function, smtlib(isValidSignature)] // ISignatureValidator(currentOwner).isValidSignature(data, contractSignature)
; syntax Int ::= #signer ( WordStack , Int , WordStack ) [function]
; syntax Int ::= #sigR ( WordStack , Int ) [function]
; syntax Int ::= #sigS ( WordStack , Int ) [function]
; syntax Int ::= #sigV ( WordStack , Int ) [function]
;
; rule 0 <=Int #fii(_,_,_,_,_) => true
; rule #fii(_,_,_,_,_) <Int ??? => true
;
; // axiomatization of #fii
;
; rule #isValid(SIGS, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER) => true requires I <Int #fii(SIGS, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
; rule #isValid(SIGS, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER) => false requires I ==Int #fii(SIGS, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
;
; // axiomatization of #isValid
;
; rule #isValid (SIGS, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
; => #isValidSig(SIGS, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
; andBool #signer(SIGS, I, DATA_HASH) >Int #signer(SIGS, I -Int 1, DATA_HASH)
; andBool select(STORAGE, #hashedLocation({COMPILER}, {OWNERS}, #signer(SIGS, I, DATA_HASH))) =/=Int 0
;
; rule #signer(_, I, _) => 0 requires I <Int 0 // address lastOwner = address(0);
;
; // axiomatization of #isValidSig for each signature type
;
; rule #isValidSig(SIGS, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
; => #isValidSignature(#signer(SIGS, I, DATA_HASH), // currentOwner
; DATA_BUF, // data
; #bufSeg(SIGS, #sigS(SIGS,I) +Int 32, #asWord(#bufSeg(SIGS, #sigS(SIGS,I), 32)))) // contractSignature
; requires #sigV(SIGS, I) ==Int 0
;
; rule #isValidSig(SIGS, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
; => MSG_SENDER ==Int #sigR(SIGS, I)
; orBool select(STORAGE, #hashedLocation({COMPILER}, {APPROVED_HASHES}, #sigR(SIGS, I) DATA_HASH)) =/=Int 0
; requires #sigV(SIGS, I) ==Int 1
;
; /* in case the above doesn't work
; rule #isValidSig(SIGS, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER) => true
; requires #sigV(SIGS, I) ==Int 1 andBool MSG_SENDER ==Int #sigR(SIGS, I)
;
; rule #isValidSig(SIGS, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
; => select(STORAGE, #hashedLocation({COMPILER}, {APPROVED_HASHES}, #sigR(SIGS, I) DATA_HASH)) =/=Int 0
; requires #sigV(SIGS, I) ==Int 1 andBool MSG_SENDER =/=Int #sigR(SIGS, I)
; */
;
; rule #isValidSig(SIGS, I, DATA_HASH, DATA_BUF, STORAGE, MSG_SENDER)
; => notBool #ecrecEmpty(#ecrecData(SIGS, I, DATA_HASH))
; requires #sigV(SIGS, I) =/=Int 0
; andBool #sigV(SIGS, I) =/=Int 1
;
; // definition of #signer
;
; rule #signer(SIGS, I, DATA_HASH) => #symEcrec(#ecrecData(SIGS, I, DATA_HASH)) requires I >=Int 0 andBool #sigV(SIGS, I) =/=Int 0 andBool #sigV(SIGS, I) =/=Int 1 andBool notBool #ecrecEmpty(#ecrecData(SIGS, I, DATA_HASH))
; rule #signer(SIGS, I, DATA_HASH) => 0 requires I >=Int 0 andBool #sigV(SIGS, I) =/=Int 0 andBool #sigV(SIGS, I) =/=Int 1 andBool #ecrecEmpty(#ecrecData(SIGS, I, DATA_HASH))
; rule #signer(SIGS, I, DATA_HASH) => #sigR(SIGS, I) requires I >=Int 0 andBool ( #sigV(SIGS, I) ==Int 0 orBool #sigV(SIGS, I) ==Int 1 )
;
; syntax WordStack ::= #ecrecData ( WordStack , Int , WordStack ) [function]
; rule #ecrecData(SIGS, I, DATA_HASH) => #encodeArgs(#bytes32(DATA_HASH), #uint8(#sigV(SIGS,I)), #bytes32(#sigR(SIGS,I)), #bytes32(#sigS(SIGS,I)))
;
; // definition of #sigR, #sigS, #sigV
;
; rule #sigR(SIGS, I) => #asWord(#bufSeg(SIGS, 65 *Int I , 32))
; rule #sigS(SIGS, I) => #asWord(#bufSeg(SIGS, 65 *Int I +Int 32, 32))
; rule #sigV(SIGS, I) => #bufElm(SIGS, 65 *Int I +Int 64)
Although it is very unlikely, but if ownerCount
is corrupted (possibly due to the hash collision), ownerCount++
may have the overflow, resulting in ownerCount
being zero, provided that threshold == _threshold
. In the case of threshold != _threshold
, however, if ownerCount++
has the overflow, changeThreshold
will always revert since the following two requirements cannot be satisfied at the same time, where ownerCount
is zero:
// Validate that threshold is smaller than number of owners.
require(_threshold <= ownerCount, "Threshold cannot exceed owner count");
// There has to be at least one Safe owner.
require(_threshold >= 1, "Threshold needs to be greater than 0");
gas: #gas(INITGAS, NONMEMGAS, MEMGAS)
=> #gas(INITGAS, NONMEMGAS +Int 1061, MEMGAS +Int (Cmem(BYZANTIUM, FINAL_MEM_USAGE) -Int Cmem(BYZANTIUM, MU)))
; FINAL_MEM_USAGE ==Int #memoryUsageUpdate(MU, SIGS_LOC +Int (65 *Int I +Int 65), 32)
gas: #gas(INITGAS, NONMEMGAS, MEMGAS)
=> #gas(INITGAS, NONMEMGAS +Int 6622, MEMGAS +Int (Cmem(BYZANTIUM, FINAL_MEM_USAGE) -Int Cmem(BYZANTIUM, MU)))
; FINAL_MEM_USAGE ==Int #memoryUsageUpdate(MU, SIGS_LOC +Int (65 *Int I +Int 65), 32)
gas: #gas(INITGAS, NONMEMGAS, MEMGAS)
=> #gas(INITGAS, NONMEMGAS +Int Cgascap(..) +Int 1334 -Int Cgascap(..) +Int 3496, MEMGAS +Int (Cmem(BYZANTIUM, FINAL_MEM_USAGE) -Int Cmem(BYZANTIUM, MU)))
; == #gas(INITGAS, NONMEMGAS +Int 4830, MEMGAS +Int (Cmem(BYZANTIUM, FINAL_MEM_USAGE) -Int Cmem(BYZANTIUM, MU)))
; FINAL_MEM_USAGE ==Int #memoryUsageUpdate(MU, NEXT_LOC +Int 128 , 32)