rm outdated mimc example

phase2/.gitignore

@@ -4,3 +4,7 @@ phase1*
 Cargo.lock
 node_modules
 phase1radix2m*
+/*.json
+/*.bin
+/*.params
+/*.circom

phase2/examples/mimc.rs

@@ -1,271 +0,0 @@
-extern crate bellman;
-extern crate pairing;
-extern crate rand;
-extern crate phase2;
-
-// For randomness (during paramgen and proof generation)
-use rand::{thread_rng, Rng};
-
-// For benchmarking
-use std::time::{Duration, Instant};
-
-// Bring in some tools for using pairing-friendly curves
-use pairing::{
-    Engine,
-    Field,
-};
-
-// We're going to use the BLS12-381 pairing-friendly elliptic curve.
-use pairing::bls12_381::{
-    Bls12
-};
-
-// We'll use these interfaces to construct our circuit.
-use bellman::{
-    Circuit,
-    ConstraintSystem,
-    SynthesisError
-};
-
-// We're going to use the Groth16 proving system.
-use bellman::groth16::{
-    Proof,
-    prepare_verifying_key,
-    create_random_proof,
-    verify_proof,
-};
-
-const MIMC_ROUNDS: usize = 322;
-
-/// This is an implementation of MiMC, specifically a
-/// variant named `LongsightF322p3` for BLS12-381.
-/// See http://eprint.iacr.org/2016/492 for more 
-/// information about this construction.
-///
-/// ```
-/// function LongsightF322p3(xL ⦂ Fp, xR ⦂ Fp) {
-///     for i from 0 up to 321 {
-///         xL, xR := xR + (xL + Ci)^3, xL
-///     }
-///     return xL
-/// }
-/// ```
-fn mimc<E: Engine>(
-    mut xl: E::Fr,
-    mut xr: E::Fr,
-    constants: &[E::Fr]
-) -> E::Fr
-{
-    assert_eq!(constants.len(), MIMC_ROUNDS);
-
-    for i in 0..MIMC_ROUNDS {
-        let mut tmp1 = xl;
-        tmp1.add_assign(&constants[i]);
-        let mut tmp2 = tmp1;
-        tmp2.square();
-        tmp2.mul_assign(&tmp1);
-        tmp2.add_assign(&xr);
-        xr = xl;
-        xl = tmp2;
-    }
-
-    xl
-}
-
-/// This is our demo circuit for proving knowledge of the
-/// preimage of a MiMC hash invocation.
-struct MiMCDemo<'a, E: Engine> {
-    xl: Option<E::Fr>,
-    xr: Option<E::Fr>,
-    constants: &'a [E::Fr]
-}
-
-/// Our demo circuit implements this `Circuit` trait which
-/// is used during paramgen and proving in order to
-/// synthesize the constraint system.
-impl<'a, E: Engine> Circuit<E> for MiMCDemo<'a, E> {
-    fn synthesize<CS: ConstraintSystem<E>>(
-        self,
-        cs: &mut CS
-    ) -> Result<(), SynthesisError>
-    {
-        assert_eq!(self.constants.len(), MIMC_ROUNDS);
-
-        // Allocate the first component of the preimage.
-        let mut xl_value = self.xl;
-        let mut xl = cs.alloc(|| "preimage xl", || {
-            xl_value.ok_or(SynthesisError::AssignmentMissing)
-        })?;
-
-        // Allocate the second component of the preimage.
-        let mut xr_value = self.xr;
-        let mut xr = cs.alloc(|| "preimage xr", || {
-            xr_value.ok_or(SynthesisError::AssignmentMissing)
-        })?;
-
-        for i in 0..MIMC_ROUNDS {
-            // xL, xR := xR + (xL + Ci)^3, xL
-            let cs = &mut cs.namespace(|| format!("round {}", i));
-
-            // tmp = (xL + Ci)^2
-            let mut tmp_value = xl_value.map(|mut e| {
-                e.add_assign(&self.constants[i]);
-                e.square();
-                e
-            });
-            let mut tmp = cs.alloc(|| "tmp", || {
-                tmp_value.ok_or(SynthesisError::AssignmentMissing)
-            })?;
-
-            cs.enforce(
-                || "tmp = (xL + Ci)^2",
-                |lc| lc + xl + (self.constants[i], CS::one()),
-                |lc| lc + xl + (self.constants[i], CS::one()),
-                |lc| lc + tmp
-            );
-
-            // new_xL = xR + (xL + Ci)^3
-            // new_xL = xR + tmp * (xL + Ci)
-            // new_xL - xR = tmp * (xL + Ci)
-            let mut new_xl_value = xl_value.map(|mut e| {
-                e.add_assign(&self.constants[i]);
-                e.mul_assign(&tmp_value.unwrap());
-                e.add_assign(&xr_value.unwrap());
-                e
-            });
-
-            let mut new_xl = if i == (MIMC_ROUNDS-1) {
-                // This is the last round, xL is our image and so
-                // we allocate a public input.
-                cs.alloc_input(|| "image", || {
-                    new_xl_value.ok_or(SynthesisError::AssignmentMissing)
-                })?
-            } else {
-                cs.alloc(|| "new_xl", || {
-                    new_xl_value.ok_or(SynthesisError::AssignmentMissing)
-                })?
-            };
-
-            cs.enforce(
-                || "new_xL = xR + (xL + Ci)^3",
-                |lc| lc + tmp,
-                |lc| lc + xl + (self.constants[i], CS::one()),
-                |lc| lc + new_xl - xr
-            );
-
-            // xR = xL
-            xr = xl;
-            xr_value = xl_value;
-
-            // xL = new_xL
-            xl = new_xl;
-            xl_value = new_xl_value;
-        }
-
-        Ok(())
-    }
-}
-
-fn main() {
-    // This may not be cryptographically safe, use
-    // `OsRng` (for example) in production software.
-    let rng = &mut thread_rng();
-
-    // Generate the MiMC round constants
-    let constants = (0..MIMC_ROUNDS).map(|_| rng.gen()).collect::<Vec<_>>();
-
-    println!("Creating parameters...");
-
-    // Create parameters for our circuit
-    let mut params = {
-        let c = MiMCDemo::<Bls12> {
-            xl: None,
-            xr: None,
-            constants: &constants
-        };
-
-        phase2::MPCParameters::new(c).unwrap()
-    };
-
-    let old_params = params.clone();
-    params.contribute(rng);
-
-    let first_contrib = phase2::verify_contribution(&old_params, &params).expect("should verify");
-
-    let old_params = params.clone();
-    params.contribute(rng);
-
-    let second_contrib = phase2::verify_contribution(&old_params, &params).expect("should verify");
-
-    let verification_result = params.verify(MiMCDemo::<Bls12> {
-        xl: None,
-        xr: None,
-        constants: &constants
-    }).unwrap();
-
-    assert!(phase2::contains_contribution(&verification_result, &first_contrib));
-    assert!(phase2::contains_contribution(&verification_result, &second_contrib));
-
-    let params = params.get_params();
-
-    // Prepare the verification key (for proof verification)
-    let pvk = prepare_verifying_key(&params.vk);
-
-    println!("Creating proofs...");
-
-    // Let's benchmark stuff!
-    const SAMPLES: u32 = 50;
-    let mut total_proving = Duration::new(0, 0);
-    let mut total_verifying = Duration::new(0, 0);
-
-    // Just a place to put the proof data, so we can
-    // benchmark deserialization.
-    let mut proof_vec = vec![];
-
-    for _ in 0..SAMPLES {
-        // Generate a random preimage and compute the image
-        let xl = rng.gen();
-        let xr = rng.gen();
-        let image = mimc::<Bls12>(xl, xr, &constants);
-
-        proof_vec.truncate(0);
-
-        let start = Instant::now();
-        {
-            // Create an instance of our circuit (with the
-            // witness)
-            let c = MiMCDemo {
-                xl: Some(xl),
-                xr: Some(xr),
-                constants: &constants
-            };
-
-            // Create a groth16 proof with our parameters.
-            let proof = create_random_proof(c, params, rng).unwrap();
-
-            proof.write(&mut proof_vec).unwrap();
-        }
-
-        total_proving += start.elapsed();
-
-        let start = Instant::now();
-        let proof = Proof::read(&proof_vec[..]).unwrap();
-        // Check the proof
-        assert!(verify_proof(
-            &pvk,
-            &proof,
-            &[image]
-        ).unwrap());
-        total_verifying += start.elapsed();
-    }
-    let proving_avg = total_proving / SAMPLES;
-    let proving_avg = proving_avg.subsec_nanos() as f64 / 1_000_000_000f64
-                      + (proving_avg.as_secs() as f64);
-
-    let verifying_avg = total_verifying / SAMPLES;
-    let verifying_avg = verifying_avg.subsec_nanos() as f64 / 1_000_000_000f64
-                      + (verifying_avg.as_secs() as f64);
-
-    println!("Average proving time: {:?} seconds", proving_avg);
-    println!("Average verifying time: {:?} seconds", verifying_avg);
-}