EIP3 - Addition of CALLDEPTH opcode
# Abstract
This is a proposal to add a new opcode, CALLDEPTH
. The CALLDEPTH
opcode would return the remaining available call stack depth.
# Motivation
There is a limit specifying how deep contracts can call other contracts; the call stack. The limit is currently 256
. If a contract invokes another contract (either via CALL
or CALLCODE
), the operation will fail if the call stack depth limit has been reached.
This behaviour makes it possible to subject a contract to a "call stack attack" [1]. In such an attack, an attacker first creates a suitable depth of the stack, e.g. by recursive calls. After this step, the attacker invokes the targeted contract. If the targeted calls another contract, that call will fail. If the return value is not properly checked to see if the call was successful, the consequences could be damaging.
Example:
- Contract
A
wants to be invoked regularly, and pays Ether to the invoker in every block. - When contract
A
is invoked, it calls contractsB
andC
, which consumes a lot of gas. After invocation, contractA
pays Ether to the caller. - Malicious user
X
ensures that the stack depth is shallow before invoking A. Both calls toB
andC
fail, butX
can still collect the reward.
It is possible to defend against this in two ways:
- Check return value after invocation.
- Check call stack depth experimentally. A library [2] by Piper Merriam exists for this purpose. This method is quite costly in gas.
[1] a.k.a "shallow stack attack" and "stack attack". However, to be precise, the word ''stack'' has a different meaning within the EVM, and is not to be confused with the ''call stack''.
[2] https://github.com/pipermerriam/ethereum-stack-depth-lib
# Specification
The opcode CALLDEPTH
should return the remaining call stack depth. A value of 0
means that the call stack is exhausted, and no further calls can be made.
# Rationale
The actual call stack depth, as well as the call stack depth limit, are present in the EVM during execution, but just not available within the EVM. The implementation should be fairly simple and would provide a cheap and way to protect against call stack attacks.
# Implementation
Not implemented.