/*
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 "montgomery.circom";
include "mux3.circom";
include "babyjub.circom";
template Window4() {
signal input in[4];
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]*2*in[3] + mux.out[1]; // Negate y if in[3] is one
}
/* nWindows must not exceed 50 */
template Segment(nWindows) {
signal input in[nWindows*4];
signal input base[2];
signal output out[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 doublers1[nWindows-1];
component doublers2[nWindows-1];
component adders[nWindows-1];
for (i=0; i 1) {
m2e.in[0] <== adders[nWindows-2].out[0];
m2e.in[1] <== adders[nWindows-2].out[1];
} else {
m2e.in[0] <== windows[0].out[0];
m2e.in[1] <== windows[0].out[1];
}
out[0] <== m2e.out[0];
out[1] <== m2e.out[1];
}
template Pedersen(n) {
signal input in[n];
signal output out[2];
var BASE = [
[10457101036533406547632367118273992217979173478358440826365724437999023779287,19824078218392094440610104313265183977899662750282163392862422243483260492317],
[2671756056509184035029146175565761955751135805354291559563293617232983272177,2663205510731142763556352975002641716101654201788071096152948830924149045094],
[5802099305472655231388284418920769829666717045250560929368476121199858275951,5980429700218124965372158798884772646841287887664001482443826541541529227896],
[7107336197374528537877327281242680114152313102022415488494307685842428166594,2857869773864086953506483169737724679646433914307247183624878062391496185654],
[20265828622013100949498132415626198973119240347465898028410217039057588424236,1160461593266035632937973507065134938065359936056410650153315956301179689506],
[1487999857809287756929114517587739322941449154962237464737694709326309567994,14017256862867289575056460215526364897734808720610101650676790868051368668003],
[14618644331049802168996997831720384953259095788558646464435263343433563860015,13115243279999696210147231297848654998887864576952244320558158620692603342236],
[6814338563135591367010655964669793483652536871717891893032616415581401894627,13660303521961041205824633772157003587453809761793065294055279768121314853695],
[3571615583211663069428808372184817973703476260057504149923239576077102575715,11981351099832644138306422070127357074117642951423551606012551622164230222506],
[18597552580465440374022635246985743886550544261632147935254624835147509493269,6753322320275422086923032033899357299485124665258735666995435957890214041481]
]
var nSegments = ((n-1)\200)+1;
component segments[nSegments];
var i;
var j;
var nBits;
var nWindows;
for (i=0; i1) {
packPoint.in[0] <== adders[nSegments-2].xout;
packPoint.in[1] <== adders[nSegments-2].yout;
} else {
packPoint.in[0] <== segments[0].out[0];
packPoint.in[1] <== segments[0].out[1];
}
out[0] <== packPoint.out[0];
out[1] <== packPoint.out[1];
*/
if (nSegments>1) {
out[0] <== adders[nSegments-2].xout;
out[1] <== adders[nSegments-2].yout;
} else {
out[0] <== segments[0].out[0];
out[1] <== segments[0].out[1];
}
}