This repo is meant to be a proof of concept, investigating whether it's feasible to use exhaustive searching for optimal stack scheduling for EVM programs.

Stack scheduling is the process of turning a sequence of variable assignments into stack manipulating instructions. Unlike traditional, register-based ISAs, the EVMs stack based nature doesn't map very well to assignments.

Installation

1. Clone repo (git clone https://github.com/Philogy/balls.git)
2. cd balls
3. cargo install --path .

Run

balls -h

ERC20 transfer(address to, uint256 amount) method

Code:

// EXTERNAL
extern _REQUIRE_NOT() stack(1, 0) reads(CONTROL_FLOW)

// Define actual code
fn TRANSFER<z0>(error) -> () {
    // Define some variables
    to = calldataload(0x04)
    amount = calldataload(0x24)

    // Get from balance.
    from_bal = sload(caller())

    // Check from balance and error.
    insufficient_bal = gt(amount, from_bal)
    error' = or(insufficient_bal, error)
    _REQUIRE_NOT(error')

    // Update from balance.
    new_from_bal = sub(from_bal, amount)
    sstore(caller(), new_from_bal)

    // Update to balance.
    to_bal = sload(to)
    new_to_bal = add(to_bal, amount)
    sstore(to, new_to_bal)

    // Return success (1).
    mstore(z0, 1)
    return(z0, msize())
}

Compile with balls ./examples/transfer_ma.balls -d (-d tells BALLS to use the Dijkstra which is guaranteed to result in the optimal scheduling given the constraints).

Result:

#define macro TRANSFER(z0) = takes(1) returns(0) {
    // takes:                      [error]
    caller                      // [error, caller()]
    sload                       // [error, from_bal]
    0x24                        // [error, from_bal, 0x24]
    calldataload                // [error, from_bal, amount]
    dup1                        // [error, from_bal, amount, amount]
    dup3                        // [error, from_bal, amount, amount, from_bal]
    sub                         // [error, from_bal, amount, new_from_bal]
    caller                      // [error, from_bal, amount, new_from_bal, caller()]
    sstore                      // [error, from_bal, amount]
    0x4                         // [error, from_bal, amount, 0x4]
    calldataload                // [error, from_bal, amount, to]
    dup1                        // [error, from_bal, amount, to, to]
    sload                       // [error, from_bal, amount, to, to_bal]
    dup3                        // [error, from_bal, amount, to, to_bal, amount]
    add                         // [error, from_bal, amount, to, new_to_bal]
    swap1                       // [error, from_bal, amount, new_to_bal, to]
    sstore                      // [error, from_bal, amount]
    gt                          // [error, insufficient_bal]
    or                          // [error']
    _REQUIRE_NOT()              // []
    0x1                         // [0x1]
    <z0>                        // [0x1, z0]
    mstore                      // []
    msize                       // [msize()]
    <z0>                        // [msize(), z0]
    return                      // []
    // returns:                    []
}

What this code does on a high-level:

• Expects an external huff macro _REQUIRE_NOT that takes 0 inlined arguments, consumes 1 stack value and pushes 0 values, that's dependent on the CONTROL_FLOW dependency meaning that it shouldn't be rearranged after e.g. a stop, revert or return
• Defines a Huff macro TRANSFER that takes 1 inlined argument z0 and pops 1 stack value referencing it as "error"

Default

By default BALLS will run using the "Guessoor" scheduling algorithm, it runs quite quickly even on unconstrained schedules but is not guaranteed to result in the optimal scheduling. To tune the likelihood the result approaches the optimal scheduling you can play around with the --guess parameter. Lower will make the scheduler run slower but be more likely to output an optimal result, higher values will make the scheduling run faster with worse results.

Running the Dijkstra Scheduler

The --dijkstra flag will use the Dijstkra scheduler. Performing Dijkstra's algorithm it is guaranteed to output the optimal scheduling given the constraints, however this mode can run very slowly up to not completing at all on larger examples (such as examples/permit_ma.balls). Non-termination is especially likely when using --dijkstra when the search is otherwise unconstrained.

Constraining the search

To speed up any of the above searches you may constrain the max stack depth that the program is allowed to have at any point. The default value is the EVM's max stack depth of 1024. Too low of a value may result in a stack-too-deep error. Constraining can allow Dijkstra to terminate in reasonable times for larger examples such as permit_ma.balls.

Note that if the value is too low the scheduler may output a scheduling but it may not be the most optimal possible schedule.

BALLS is able to search for and create optimal stack schedules by going through and reordering operations. To ensure that the code remains correct the system tracks "read" and "write" dependencies. Some dependencies are quite straight forward to understand like MEMORY and STORAGE. Having a "read" dependency means that you depend on it but that it does not matter in what order it gets accessed so long as it does not get changed, "write" means that it affects the dependency and that it's order has to remain fixed relative to other writes and to its preceding e.g.

Original definition in code:

1. read A
2. write A
3. read A
4. read A
5. read A
6. write A
7. write A

Valid reordering:

1. read A
2. write A
+ 5. read A
+ 4. read A
+ 3. read A
6. write A
7. write A

Invalid reordering:

1. read A
- 3. read A
- 2. write A
4. read A
5. read A
- 7. write A
- 6. write A

The list of default dependencies, opcodes and their read/writes can be found under src/transformer/std_evm.rs.