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/* Copyright 2018 0KIMS association.
This file is part of circom (Zero Knowledge Circuit Compiler).
circom is a free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version.
circom is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License along with circom. If not, see <https://www.gnu.org/licenses/>. */
include "compconstant.circom"; include "pointbits.circom"; include "mimcsponge.circom"; include "bitify.circom"; include "escalarmulany.circom"; include "escalarmulfix.circom";
template EdDSAMiMCSpongeVerifier() { signal input enabled; signal input Ax; signal input Ay;
signal input S; signal input R8x; signal input R8y;
signal input M;
var i;
// Ensure S<Subgroup Order
component snum2bits = Num2Bits(253); snum2bits.in <== S;
component compConstant = CompConstant(2736030358979909402780800718157159386076813972158567259200215660948447373040);
for (i=0; i<253; i++) { snum2bits.out[i] ==> compConstant.in[i]; } compConstant.in[253] <== 0; compConstant.out === 0;
// Calculate the h = H(R,A, msg)
component hash = MiMCSponge(5, 220, 1); hash.ins[0] <== R8x; hash.ins[1] <== R8y; hash.ins[2] <== Ax; hash.ins[3] <== Ay; hash.ins[4] <== M; hash.k <== 0;
component h2bits = Num2Bits_strict(); h2bits.in <== hash.outs[0];
// Calculate second part of the right side: right2 = h*8*A
// Multiply by 8 by adding it 3 times. This also ensure that the result is in // the subgroup. component dbl1 = BabyDbl(); dbl1.x <== Ax; dbl1.y <== Ay; component dbl2 = BabyDbl(); dbl2.x <== dbl1.xout; dbl2.y <== dbl1.yout; component dbl3 = BabyDbl(); dbl3.x <== dbl2.xout; dbl3.y <== dbl2.yout;
// We check that A is not zero. component isZero = IsZero(); isZero.in <== dbl3.x; isZero.out === 0;
component mulAny = EscalarMulAny(254); for (i=0; i<254; i++) { mulAny.e[i] <== h2bits.out[i]; } mulAny.p[0] <== dbl3.xout; mulAny.p[1] <== dbl3.yout;
// Compute the right side: right = R8 + right2
component addRight = BabyAdd(); addRight.x1 <== R8x; addRight.y1 <== R8y; addRight.x2 <== mulAny.out[0]; addRight.y2 <== mulAny.out[1];
// Calculate left side of equation left = S*B8
var BASE8 = [ 5299619240641551281634865583518297030282874472190772894086521144482721001553, 16950150798460657717958625567821834550301663161624707787222815936182638968203 ]; component mulFix = EscalarMulFix(253, BASE8); for (i=0; i<253; i++) { mulFix.e[i] <== snum2bits.out[i]; }
// Do the comparation left == right if enabled;
component eqCheckX = ForceEqualIfEnabled(); eqCheckX.enabled <== enabled; eqCheckX.in[0] <== mulFix.out[0]; eqCheckX.in[1] <== addRight.xout;
component eqCheckY = ForceEqualIfEnabled(); eqCheckY.enabled <== enabled; eqCheckY.in[0] <== mulFix.out[1]; eqCheckY.in[1] <== addRight.yout; }
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