/* 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 . */ include "mux3.circom"; include "montgomery.circom"; include "babyjub.circom"; /* Window of 3 elements, it calculates out = base + base*in[0] + 2*base*in[1] + 4*base*in[2] out4 = 4*base The result should be compensated. */ /* The scalar is s = a0 + a1*2^3 + a2*2^6 + ...... + a81*2^243 First We calculate Q = B + 2^3*B + 2^6*B + ......... + 2^246*B Then we calculate S1 = 2*2^246*B + (1 + a0)*B + (2^3 + a1)*B + .....+ (2^243 + a81)*B And Finaly we compute the result: RES = SQ - Q As you can see the input of the adders cannot be equal nor zero, except for the last substraction that it's done in montgomery. A good way to see it is that the accumulator input of the adder >= 2^247*B and the other input is the output of the windows that it's going to be <= 2^246*B */ template WindowMulFix() { signal input in[3]; signal input base[2]; signal output out[2]; signal output out8[2]; // Returns 8*Base (To be linked) component mux = MultiMux3(2); mux.s[0] <== in[0]; mux.s[1] <== in[1]; mux.s[2] <== in[2]; component dbl2 = MontgomeryDouble(); component adr3 = MontgomeryAdd(); component adr4 = MontgomeryAdd(); component adr5 = MontgomeryAdd(); component adr6 = MontgomeryAdd(); component adr7 = MontgomeryAdd(); component adr8 = MontgomeryAdd(); // in[0] -> 1*BASE mux.c[0][0] <== base[0]; mux.c[1][0] <== base[1]; // in[1] -> 2*BASE dbl2.in[0] <== base[0]; dbl2.in[1] <== base[1]; mux.c[0][1] <== dbl2.out[0]; mux.c[1][1] <== dbl2.out[1]; // in[2] -> 3*BASE adr3.in1[0] <== base[0]; adr3.in1[1] <== base[1]; adr3.in2[0] <== dbl2.out[0]; adr3.in2[1] <== dbl2.out[1]; mux.c[0][2] <== adr3.out[0]; mux.c[1][2] <== adr3.out[1]; // in[3] -> 4*BASE adr4.in1[0] <== base[0]; adr4.in1[1] <== base[1]; adr4.in2[0] <== adr3.out[0]; adr4.in2[1] <== adr3.out[1]; mux.c[0][3] <== adr4.out[0]; mux.c[1][3] <== adr4.out[1]; // in[4] -> 5*BASE adr5.in1[0] <== base[0]; adr5.in1[1] <== base[1]; adr5.in2[0] <== adr4.out[0]; adr5.in2[1] <== adr4.out[1]; mux.c[0][4] <== adr5.out[0]; mux.c[1][4] <== adr5.out[1]; // in[5] -> 6*BASE adr6.in1[0] <== base[0]; adr6.in1[1] <== base[1]; adr6.in2[0] <== adr5.out[0]; adr6.in2[1] <== adr5.out[1]; mux.c[0][5] <== adr6.out[0]; mux.c[1][5] <== adr6.out[1]; // in[6] -> 7*BASE adr7.in1[0] <== base[0]; adr7.in1[1] <== base[1]; adr7.in2[0] <== adr6.out[0]; adr7.in2[1] <== adr6.out[1]; mux.c[0][6] <== adr7.out[0]; mux.c[1][6] <== adr7.out[1]; // in[7] -> 8*BASE adr8.in1[0] <== base[0]; adr8.in1[1] <== base[1]; adr8.in2[0] <== adr7.out[0]; adr8.in2[1] <== adr7.out[1]; mux.c[0][7] <== adr8.out[0]; mux.c[1][7] <== adr8.out[1]; out8[0] <== adr8.out[0]; out8[1] <== adr8.out[1]; out[0] <== mux.out[0]; out[1] <== mux.out[1]; } /* This component does a multiplication of a escalar times a fix base Signals: e: The scalar in bits base: the base point in edwards format out: The result dbl: Point in Edwards to be linked to the next segment. */ template SegmentMulFix(nWindows) { signal input e[nWindows*3]; signal input base[2]; signal output out[2]; signal output dbl[2]; var i; var j; // Convert the base to montgomery component e2m = Edwards2Montgomery(); e2m.in[0] <== base[0]; e2m.in[1] <== base[1]; component windows[nWindows]; component adders[nWindows]; component cadders[nWindows]; // In the last step we add an extra doubler so that numbers do not match. component dblLast = MontgomeryDouble(); for (i=0; i out[0]; cAdd.yout ==> out[1]; windows[nWindows-1].out8[0] ==> dbl[0]; windows[nWindows-1].out8[1] ==> dbl[1]; } /* This component multiplies a escalar times a fixed point BASE (twisted edwards format) Signals e: The escalar in binary format out: The output point in twisted edwards */ template EscalarMulFix(n, BASE) { signal input e[n]; // Input in binary format signal output out[2]; // Point (Twisted format) var nsegments = (n-1)\246 +1; // 249 probably would work. But I'm not sure and for security I keep 246 var nlastsegment = n - (nsegments-1)*249; component segments[nsegments]; component m2e[nsegments-1]; component adders[nsegments-1]; var s; var i; var nseg; var nWindows for (s=0; s m2e[s-1].in[0]; segments[s-1].dbl[1] ==> m2e[s-1].in[1]; m2e[s-1].out[0] ==> segments[s].base[0]; m2e[s-1].out[1] ==> segments[s].base[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]; } }