arnaucube
/
circomlib
mirror of https://github.com/arnaucube/circomlib.git



								include "montgomery.circom";

								include "babyjub.circom";


								template Multiplexor2() {

								    signal input sel;

								    signal input in[2][2];

								    signal output out[2];


								    out[0] <== (in[1][0] - in[0][0])*sel + in[0][0];

								    out[1] <== (in[1][1] - in[0][1])*sel + in[0][1];

								}


								template BitElementMulAny() {

								    signal input sel;

								    signal input dblIn[2];

								    signal input addIn[2];

								    signal output dblOut[2];

								    signal output addOut[2];


								    component doubler = MontgomeryDouble();

								    component adder = MontgomeryAdd();

								    component selector = Multiplexor2();


								    sel ==> selector.sel;


								    dblIn[0] ==> doubler.in[0];

								    dblIn[1] ==> doubler.in[1];

								    doubler.out[0] ==> adder.in1[0];

								    doubler.out[1] ==> adder.in1[1];

								    addIn[0] ==> adder.in2[0];

								    addIn[1] ==> adder.in2[1];

								    addIn[0] ==> selector.in[0][0];

								    addIn[1] ==> selector.in[0][1];

								    adder.out[0] ==> selector.in[1][0];

								    adder.out[1] ==> selector.in[1][1];


								    doubler.out[0] ==> dblOut[0];

								    doubler.out[1] ==> dblOut[1];

								    selector.out[0] ==> addOut[0];

								    selector.out[1] ==> addOut[1];

								}


								// p is montgomery point

								// n must be <= 248

								// returns out in twisted edwards

								// Double is in montgomery to be linked;


								template SegmentMulAny(n) {

								    signal input e[n];

								    signal input p[2];

								    signal output out[2];

								    signal output dbl[2];


								    component bits[n-1];


								    component e2m = Edwards2Montgomery();


								    p[0] ==> e2m.in[0];

								    p[1] ==> e2m.in[1];


								    var i;


								    bits[0] = BitElementMulAny();

								    e2m.out[0] ==> bits[0].dblIn[0]

								    e2m.out[1] ==> bits[0].dblIn[1]

								    e2m.out[0] ==> bits[0].addIn[0]

								    e2m.out[1] ==> bits[0].addIn[1]

								    e[1] ==> bits[0].sel;


								    for (i=1; i<n-1; i++) {

								        bits[i] = BitElementMulAny();


								        bits[i-1].dblOut[0] ==> bits[i].dblIn[0]

								        bits[i-1].dblOut[1] ==> bits[i].dblIn[1]

								        bits[i-1].addOut[0] ==> bits[i].addIn[0]

								        bits[i-1].addOut[1] ==> bits[i].addIn[1]

								        e[i+1] ==> bits[i].sel;

								    }


								    bits[n-2].dblOut[0] ==> dbl[0];

								    bits[n-2].dblOut[1] ==> dbl[1];


								    component m2e = Montgomery2Edwards();


								    bits[n-2].addOut[0] ==> m2e.in[0];

								    bits[n-2].addOut[1] ==> m2e.in[1];


								    component eadder = BabyAdd();


								    m2e.out[0] ==> eadder.x1;

								    m2e.out[1] ==> eadder.y1;

								    -p[0] ==> eadder.x2;

								    p[1] ==> eadder.y2;


								    component lastSel = Multiplexor2();


								    e[0] ==> lastSel.sel;

								    eadder.xout ==> lastSel.in[0][0];

								    eadder.yout ==> lastSel.in[0][1];

								    m2e.out[0] ==> lastSel.in[1][0];

								    m2e.out[1] ==> lastSel.in[1][1];


								    lastSel.out[0] ==> out[0];

								    lastSel.out[1] ==> out[1];

								}


								// This function assumes that p is in the subgroup and it is different to 0


								template EscalarMulAny(n) {

								    signal input e[n];              // Input in binary format

								    signal input p[2];              // Point (Twisted format)

								    signal output out[2];           // Point (Twisted format)


								    var nsegments = (n-1)\148 +1;

								    var nlastsegment = n - (nsegments-1)*148;


								    component segments[nsegments];

								    component doublers[nsegments-1];

								    component m2e[nsegments-1];

								    component adders[nsegments-1];


								    var s;

								    var i;

								    var nseg;


								    for (s=0; s<nsegments; s++) {


								        nseg = (s < nsegments-1) ? 148 : nlastsegment;


								        segments[s] = SegmentMulAny(nseg);


								        for (i=0; i<nseg; i++) {

								            e[s*148+i] ==> segments[s].e[i];

								        }


								        if (s==0) {

								            p[0] ==> segments[s].p[0];

								            p[1] ==> segments[s].p[1];

								        } else {

								            doublers[s-1] = MontgomeryDouble();

								            m2e[s-1] = Montgomery2Edwards();

								            adders[s-1] = BabyAdd();


								            segments[s-1].dbl[0] ==> doublers[s-1].in[0];

								            segments[s-1].dbl[1] ==> doublers[s-1].in[1];


								            doublers[s-1].out[0] ==> m2e[s-1].in[0];

								            doublers[s-1].out[1] ==> m2e[s-1].in[1];


								            m2e[s-1].out[0] ==> segments[s].p[0];

								            m2e[s-1].out[1] ==> segments[s].p[1];


								            if (s==1) {

								                segments[s-1].out[0] ==> adders[s-1].x1;

								                segments[s-1].out[1] ==> adders[s-1].y1;

								            } else {

								                adders[s-2].xout ==> adders[s-1].x1;

								                adders[s-2].yout ==> adders[s-1].y1;

								            }

								            segments[s].out[0] ==> adders[s-1].x2;

								            segments[s].out[1] ==> adders[s-1].y2;

								        }

								    }


								    if (nsegments == 1) {

								        segments[0].out[0] ==> out[0];

								        segments[0].out[1] ==> out[1];

								    } else {

								        adders[nsegments-2].xout ==> out[0];

								        adders[nsegments-2].yout ==> out[1];

								    }

								}