port fibonacci example from starky docs

2 months ago · bd6f23c590
3 changed files with 196 additions and 0 deletions
--- a/.gitignore
+++ b/.gitignore
@ -0,0 +1,2 @@
 /target
 Cargo.lock
--- a/Cargo.toml
+++ b/Cargo.toml
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 [package]
 name = "starky-tmp"
 version = "0.1.0"
 edition = "2021"

 [dependencies]
 plonky2 = { git = "https://github.com/0xPolygonZero/plonky2" }
 starky = { git = "https://github.com/0xPolygonZero/plonky2" }
 anyhow = "1.0.86"
 itertools = "0.13"
 rand = "0.8.5"
--- a/src/lib.rs
+++ b/src/lib.rs
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 /// The code of this file is an adaptation from the Starky example from the plonky2 repo.
 ///
 use plonky2::field::extension::{Extendable, FieldExtension};
 use plonky2::field::packed::PackedField;
 use plonky2::field::polynomial::PolynomialValues;
 use plonky2::hash::hash_types::RichField;
 use std::marker::PhantomData;

 // Imports to define the constraints of our STARK.
 use starky::constraint_consumer::{ConstraintConsumer, RecursiveConstraintConsumer};
 use starky::evaluation_frame::{StarkEvaluationFrame, StarkFrame};
 use starky::stark::Stark;

 // Imports to define the recursive constraints of our STARK.
 use plonky2::iop::ext_target::ExtensionTarget;
 use plonky2::plonk::circuit_builder::CircuitBuilder;
 use starky::util::trace_rows_to_poly_values;

 // Imports to generate a STARK instance, compute the trace and prove it
 use plonky2::field::types::Field;
 use plonky2::plonk::config::GenericConfig;
 use plonky2::plonk::config::PoseidonGoldilocksConfig;
 use plonky2::util::timing::TimingTree;
 use starky::config::StarkConfig;
 use starky::prover::prove;
 use starky::verifier::verify_stark_proof;

 const D: usize = 2;
 const CONFIG: StarkConfig = StarkConfig::standard_fast_config();
 type C = PoseidonGoldilocksConfig;
 type F = <C as GenericConfig<D>>::F;
 type S = FibonacciStark<F, D>;

 #[derive(Copy, Clone)]
 pub struct FibonacciStark<F: RichField + Extendable<D>, const D: usize> {
    num_rows: usize,
    _phantom: PhantomData<F>,
 }
 // Define witness generation.
 impl<F: RichField + Extendable<D>, const D: usize> FibonacciStark<F, D> {
    // The first public input is `x0`.
    const PI_INDEX_X0: usize = 0;
    // The second public input is `x1`.
    const PI_INDEX_X1: usize = 1;
    // The third public input is the second element of the last row,
    // which should be equal to the `num_rows`-th Fibonacci number.
    const PI_INDEX_RES: usize = 2;

    pub(crate) fn new(num_rows: usize) -> Self {
        Self {
            num_rows,
            _phantom: PhantomData,
        }
    }

    /// Generate the trace using `x0, x1, 0` as initial state values.
    fn generate_trace(&self, x0: F, x1: F) -> Vec<PolynomialValues<F>> {
        let mut trace_rows = (0..self.num_rows)
            .scan([x0, x1, F::ZERO], |acc, _| {
                let tmp = *acc;
                acc[0] = tmp[1];
                acc[1] = tmp[0] + tmp[1];
                acc[2] = tmp[2] + F::ONE;
                Some(tmp)
            })
            .collect::<Vec<_>>();
        // Transpose the row-wise trace for the prover.
        trace_rows_to_poly_values(trace_rows)
    }
 }

 // Define constraints.
 const COLUMNS: usize = 3;
 const PUBLIC_INPUTS: usize = 3;

 impl<F: RichField + Extendable<D>, const D: usize> Stark<F, D> for FibonacciStark<F, D> {
    type EvaluationFrame<FE, P, const D2: usize>
        = StarkFrame<P, P::Scalar, COLUMNS, PUBLIC_INPUTS>
    where
        FE: FieldExtension<D2, BaseField = F>,
        P: PackedField<Scalar = FE>;

    type EvaluationFrameTarget =
        StarkFrame<ExtensionTarget<D>, ExtensionTarget<D>, COLUMNS, PUBLIC_INPUTS>;

    // Define this STARK's constraints.
    fn eval_packed_generic<FE, P, const D2: usize>(
        &self,
        vars: &Self::EvaluationFrame<FE, P, D2>,
        yield_constr: &mut ConstraintConsumer<P>,
    ) where
        FE: FieldExtension<D2, BaseField = F>,
        P: PackedField<Scalar = FE>,
    {
        let local_values = vars.get_local_values();
        let next_values = vars.get_next_values();
        let public_inputs = vars.get_public_inputs();

        // Check public inputs.
        yield_constr.constraint_first_row(local_values[0] - public_inputs[Self::PI_INDEX_X0]);
        yield_constr.constraint_first_row(local_values[1] - public_inputs[Self::PI_INDEX_X1]);
        yield_constr.constraint_last_row(local_values[1] - public_inputs[Self::PI_INDEX_RES]);

        // Enforce the Fibonacci transition constraints.
        // x0' <- x1
        yield_constr.constraint_transition(next_values[0] - local_values[1]);
        // x1' <- x0 + x1
        yield_constr.constraint_transition(next_values[1] - local_values[0] - local_values[1]);
    }

    // Define the constraints to recursively verify this STARK.
    fn eval_ext_circuit(
        &self,
        builder: &mut CircuitBuilder<F, D>,
        vars: &Self::EvaluationFrameTarget,
        yield_constr: &mut RecursiveConstraintConsumer<F, D>,
    ) {
        let local_values = vars.get_local_values();
        let next_values = vars.get_next_values();
        let public_inputs = vars.get_public_inputs();

        // Check public inputs.
        let pis_constraints = [
            builder.sub_extension(local_values[0], public_inputs[Self::PI_INDEX_X0]),
            builder.sub_extension(local_values[1], public_inputs[Self::PI_INDEX_X1]),
            builder.sub_extension(local_values[1], public_inputs[Self::PI_INDEX_RES]),
        ];

        yield_constr.constraint_first_row(builder, pis_constraints[0]);
        yield_constr.constraint_first_row(builder, pis_constraints[1]);
        yield_constr.constraint_last_row(builder, pis_constraints[2]);

        // Enforce the Fibonacci transition constraints.
        // x0' <- x1
        let first_col_constraint = builder.sub_extension(next_values[0], local_values[1]);
        yield_constr.constraint_transition(builder, first_col_constraint);
        // x1' <- x0 + x1
        let second_col_constraint = {
            let tmp = builder.sub_extension(next_values[1], local_values[0]);
            builder.sub_extension(tmp, local_values[1])
        };
        yield_constr.constraint_transition(builder, second_col_constraint);
    }

    fn constraint_degree(&self) -> usize {
        2
    }
 }

 #[cfg(test)]
 mod tests {
    use super::*;

    fn fibonacci_native<F: Field>(n: usize, x0: F, x1: F) -> F {
        (0..n).fold((x0, x1), |acc, _| (acc.1, acc.0 + acc.1)).1
    }

    // test that instantiates a new `FibonacciStark` instance, generates an associated STARK trace,
    // and generates a proof for it.
    #[test]
    fn test_fibonacci_stark() {
        let num_rows = 1 << 10;
        let x0 = F::from_canonical_u32(2);
        let x1 = F::from_canonical_u32(7);

        let public_inputs = [x0, x1, fibonacci_native(num_rows - 1, x0, x1)];
        let stark = FibonacciStark::<F, D>::new(num_rows);
        let trace = stark.generate_trace(public_inputs[0], public_inputs[1]);

        let proof = prove::<F, C, S, D>(
            stark,
            &CONFIG,
            trace,
            &public_inputs,
            None,
            &mut TimingTree::default(),
        )
        .expect("We should have a valid proof!");

        verify_stark_proof(stark, proof, &CONFIG, None)
            .expect("We should be able to verify this proof!")
    }
 }