tornado-nova/circuits/merkleTree.circom
2020-04-09 21:38:10 +03:00

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include "../node_modules/circomlib/circuits/mimcsponge.circom";
// Computes MiMC([left, right])
template HashLeftRight() {
signal input left;
signal input right;
signal output hash;
component hasher = MiMCSponge(2, 1);
hasher.ins[0] <== left;
hasher.ins[1] <== right;
hasher.k <== 0;
hash <== hasher.outs[0];
}
// if s == 0 returns [in[0], in[1]]
// if s == 1 returns [in[1], in[0]]
template DualMux() {
signal input in[2];
signal input s;
signal output out[2];
s * (1 - s) === 0
out[0] <== (in[1] - in[0])*s + in[0];
out[1] <== (in[0] - in[1])*s + in[1];
}
// Verifies that merkle proof is correct for given merkle root and a leaf
// pathIndices input is an array of 0/1 selectors telling whether given pathElement is on the left or right side of merkle path
template MerkleTree(levels) {
signal input leaf;
signal input pathElements[levels];
signal input pathIndices;
signal output root;
component selectors[levels];
component hashers[levels];
component indexBits = Num2Bits(levels);
indexBits.in <== pathIndices;
for (var i = 0; i < levels; i++) {
selectors[i] = DualMux();
selectors[i].in[0] <== i == 0 ? leaf : hashers[i - 1].hash;
selectors[i].in[1] <== pathElements[i];
selectors[i].s <== indexBits.out[i];
hashers[i] = HashLeftRight();
hashers[i].left <== selectors[i].out[0];
hashers[i].right <== selectors[i].out[1];
}
root <== hashers[levels - 1].hash;
}