include "compconstant.circom";
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include "pointbits.circom";
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include "pedersen2.circom";
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include "escalarmulany.circom";
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include "escalarmulfix.circom";
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/*
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include "../node_modules/circom/circuits/bitify.circom";
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include "babyjub.circom";
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*/
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template EdDSAVerifier(n) {
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signal input msg[n];
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signal input A[256];
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signal input R8[256];
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signal input S[256];
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signal Ax;
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signal Ay;
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signal R8x;
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signal R8y;
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var i;
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// Ensure S<Subgroup Order
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component compConstant = CompConstant(2736030358979909402780800718157159386076813972158567259200215660948447373040);
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for (i=0; i<254; i++) {
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S[i] ==> compConstant.in[i];
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}
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compConstant.out === 0;
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S[254] === 0;
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S[255] === 0;
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// Convert A to Field elements (And verify A)
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component bits2pointA = Bits2Point_Strict();
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for (i=0; i<256; i++) {
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bits2pointA.in[i] <== A[i];
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}
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Ax <== bits2pointA.out[0];
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Ay <== bits2pointA.out[1];
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// Convert R8 to Field elements (And verify R8)
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component bits2pointR8 = Bits2Point_Strict();
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for (i=0; i<256; i++) {
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bits2pointR8.in[i] <== R8[i];
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}
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R8x <== bits2pointR8.out[0];
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R8y <== bits2pointR8.out[1];
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// Calculate the h = H(R,A, msg)
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component hash = Pedersen(512+n);
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for (i=0; i<256; i++) {
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hash.in[i] <== R8[i];
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hash.in[256+i] <== A[i];
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}
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for (i=0; i<n; i++) {
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hash.in[512+i] <== msg[i];
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}
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component point2bitsH = Point2Bits_Strict();
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point2bitsH.in[0] <== hash.out[0];
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point2bitsH.in[1] <== hash.out[1];
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// Calculate second part of the right side: right2 = h*8*A
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// Multiply by 8 by adding it 3 times. This also ensure that the result is in
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// the subgroup.
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component dbl1 = BabyDbl();
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dbl1.x <== Ax;
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dbl1.y <== Ay;
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component dbl2 = BabyDbl();
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dbl2.x <== dbl1.xout;
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dbl2.y <== dbl1.yout;
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component dbl3 = BabyDbl();
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dbl3.x <== dbl2.xout;
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dbl3.y <== dbl2.yout;
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// We check that A is not zero.
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component isZero = IsZero();
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isZero.in <== dbl3.x;
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isZero.out === 0;
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component mulAny = EscalarMulAny(256);
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for (i=0; i<256; i++) {
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mulAny.e[i] <== point2bitsH.out[i];
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}
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mulAny.p[0] <== dbl3.xout;
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mulAny.p[1] <== dbl3.yout;
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// Compute the right side: right = R8 + right2
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component addRight = BabyAdd();
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addRight.x1 <== R8x;
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addRight.y1 <== R8y;
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addRight.x2 <== mulAny.out[0];
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addRight.y2 <== mulAny.out[1];
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// Calculate left side of equation left = S*B8
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var BASE8 = [
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17777552123799933955779906779655732241715742912184938656739573121738514868268,
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2626589144620713026669568689430873010625803728049924121243784502389097019475
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];
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component mulFix = EscalarMulFix(256, BASE8);
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for (i=0; i<256; i++) {
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mulFix.e[i] <== S[i];
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}
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// Do the comparation left == right
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mulFix.out[0] === addRight.xout;
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mulFix.out[1] === addRight.yout;
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}
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