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


								/*

								    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 "constants.circom";

								include "t1.circom";

								include "t2.circom";

								include "../binsum.circom";

								include "sigmaplus.circom";

								include "sha256compression_function.circom";


								template Sha256compression() {

								    signal input hin[256];

								    signal input inp[512];

								    signal output out[256];

								    signal a[65][32];

								    signal b[65][32];

								    signal c[65][32];

								    signal d[65][32];

								    signal e[65][32];

								    signal f[65][32];

								    signal g[65][32];

								    signal h[65][32];

								    signal w[64][32];


								    var outCalc[256] = sha256compression(hin, inp);


								    var i;

								    for (i=0; i<256; i++) out[i] <-- outCalc[i];


								    component sigmaPlus[48];

								    for (i=0; i<48; i++) sigmaPlus[i] = SigmaPlus();


								    component ct_k[64];

								    for (i=0; i<64; i++) ct_k[i] = K(i);


								    component t1[64];

								    for (i=0; i<64; i++) t1[i] = T1();


								    component t2[64];

								    for (i=0; i<64; i++) t2[i] = T2();


								    component suma[64];

								    for (i=0; i<64; i++) suma[i] = BinSum(32, 2);


								    component sume[64];

								    for (i=0; i<64; i++) sume[i] = BinSum(32, 2);


								    component fsum[8];

								    for (i=0; i<8; i++) fsum[i] = BinSum(32, 2);


								    var k;

								    var t;


								    for (t=0; t<64; t++) {

								        if (t<16) {

								            for (k=0; k<32; k++) {

								                w[t][k] <== inp[t*32+31-k];

								            }

								        } else {

								            for (k=0; k<32; k++) {

								                sigmaPlus[t-16].in2[k] <== w[t-2][k];

								                sigmaPlus[t-16].in7[k] <== w[t-7][k];

								                sigmaPlus[t-16].in15[k] <== w[t-15][k];

								                sigmaPlus[t-16].in16[k] <== w[t-16][k];

								            }


								            for (k=0; k<32; k++) {

								                w[t][k] <== sigmaPlus[t-16].out[k];

								            }

								        }

								    }


								    for (k=0; k<32; k++ ) {

								        a[0][k] <== hin[k];

								        b[0][k] <== hin[32*1 + k];

								        c[0][k] <== hin[32*2 + k];

								        d[0][k] <== hin[32*3 + k];

								        e[0][k] <== hin[32*4 + k];

								        f[0][k] <== hin[32*5 + k];

								        g[0][k] <== hin[32*6 + k];

								        h[0][k] <== hin[32*7 + k];

								    }


								    for (t = 0; t<64; t++) {

								        for (k=0; k<32; k++) {

								            t1[t].h[k] <== h[t][k];

								            t1[t].e[k] <== e[t][k];

								            t1[t].f[k] <== f[t][k];

								            t1[t].g[k] <== g[t][k];

								            t1[t].k[k] <== ct_k[t].out[k];

								            t1[t].w[k] <== w[t][k];


								            t2[t].a[k] <== a[t][k];

								            t2[t].b[k] <== b[t][k];

								            t2[t].c[k] <== c[t][k];

								        }


								        for (k=0; k<32; k++) {

								            sume[t].in[0][k] <== d[t][k];

								            sume[t].in[1][k] <== t1[t].out[k];


								            suma[t].in[0][k] <== t1[t].out[k];

								            suma[t].in[1][k] <== t2[t].out[k];

								        }


								        for (k=0; k<32; k++) {

								            h[t+1][k] <== g[t][k];

								            g[t+1][k] <== f[t][k];

								            f[t+1][k] <== e[t][k];

								            e[t+1][k] <== sume[t].out[k];

								            d[t+1][k] <== c[t][k];

								            c[t+1][k] <== b[t][k];

								            b[t+1][k] <== a[t][k];

								            a[t+1][k] <== suma[t].out[k];

								        }

								    }


								    for (k=0; k<32; k++) {

								        fsum[0].in[0][k] <==  hin[32*0+k];

								        fsum[0].in[1][k] <==  a[64][k];

								        fsum[1].in[0][k] <==  hin[32*1+k];

								        fsum[1].in[1][k] <==  b[64][k];

								        fsum[2].in[0][k] <==  hin[32*2+k];

								        fsum[2].in[1][k] <==  c[64][k];

								        fsum[3].in[0][k] <==  hin[32*3+k];

								        fsum[3].in[1][k] <==  d[64][k];

								        fsum[4].in[0][k] <==  hin[32*4+k];

								        fsum[4].in[1][k] <==  e[64][k];

								        fsum[5].in[0][k] <==  hin[32*5+k];

								        fsum[5].in[1][k] <==  f[64][k];

								        fsum[6].in[0][k] <==  hin[32*6+k];

								        fsum[6].in[1][k] <==  g[64][k];

								        fsum[7].in[0][k] <==  hin[32*7+k];

								        fsum[7].in[1][k] <==  h[64][k];

								    }


								    for (k=0; k<32; k++) {

								        out[31-k]     === fsum[0].out[k];

								        out[32+31-k]  === fsum[1].out[k];

								        out[64+31-k]  === fsum[2].out[k];

								        out[96+31-k]  === fsum[3].out[k];

								        out[128+31-k] === fsum[4].out[k];

								        out[160+31-k] === fsum[5].out[k];

								        out[192+31-k] === fsum[6].out[k];

								        out[224+31-k] === fsum[7].out[k];

								    }

								}