/* * This file is Copyright Daniel Silverstone 2006,2015 * * Permission is hereby granted, free of charge, to any person * obtaining a copy of this software and associated documentation * files (the "Software"), to deal in the Software without * restriction, including without limitation the rights to use, copy, * modify, merge, publish, distribute, sublicense, and/or sell copies * of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT * HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, * WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. * */ #include "iguana777.h" #include "secp256k1/include/secp256k1.h" #include "secp256k1/include/secp256k1_schnorr.h" #include "secp256k1/include/secp256k1_rangeproof.h" // ------------------------------------------------------[ Preparation ]---- static gfshare_ctx *_gfshare_ctx_init_core(uint8_t *sharenrs,uint32_t sharecount,uint8_t threshold,uint32_t size,void *space,int32_t spacesize) { gfshare_ctx *ctx; int32_t allocsize; allocsize = (int32_t)(sizeof(struct _gfshare_ctx) + threshold * size); if ( allocsize > spacesize ) { printf("malloc allocsize %d vs spacesize.%d\n",allocsize,spacesize); ctx = malloc(allocsize); if( ctx == NULL ) return NULL; // errno should still be set from XMALLOC() ctx->allocsize = allocsize; } else ctx = space; memset(ctx,0,allocsize); ctx->sharecount = sharecount; ctx->threshold = threshold; ctx->size = size; memcpy(ctx->sharenrs,sharenrs,sharecount); ctx->buffersize = threshold * size; return(ctx); } // Initialise a gfshare context for producing shares gfshare_ctx *gfshare_ctx_initenc(uint8_t *sharenrs,uint32_t sharecount,uint8_t threshold,uint32_t size,void *space,int32_t spacesize) { uint32_t i; for (i=0; ithreshold = 0; return(ctx); } // Free a share context's memory void gfshare_ctx_free(gfshare_ctx *ctx) { OS_randombytes(ctx->buffer,ctx->buffersize); OS_randombytes(ctx->sharenrs,ctx->sharecount); if ( ctx->allocsize != 0 ) { OS_randombytes((uint8_t *)ctx,sizeof(struct _gfshare_ctx)); free(ctx); } OS_randombytes((uint8_t *)ctx,sizeof(struct _gfshare_ctx)); } // --------------------------------------------------------[ Splitting ]---- // Provide a secret to the encoder. (this re-scrambles the coefficients) void gfshare_ctx_enc_setsecret(gfshare_ctx *ctx,uint8_t *secret) { memcpy(ctx->buffer + ((ctx->threshold-1) * ctx->size),secret,ctx->size); OS_randombytes(ctx->buffer,(ctx->threshold-1) * ctx->size); } // Extract a share from the context. 'share' must be preallocated and at least 'size' bytes long. 'sharenr' is the index into the 'sharenrs' array of the share you want. void gfshare_ctx_encgetshare(uint8_t *_logs,uint8_t *_exps,gfshare_ctx *ctx,uint8_t sharenr,uint8_t *share) { uint32_t pos,coefficient,ilog = _logs[ctx->sharenrs[sharenr]]; uint8_t *share_ptr,*coefficient_ptr = ctx->buffer; for (pos=0; possize; pos++) share[pos] = *(coefficient_ptr++); for (coefficient=1; coefficientthreshold; coefficient++) { share_ptr = share; for (pos=0; possize; pos++) { uint8_t share_byte = *share_ptr; if ( share_byte != 0 ) share_byte = _exps[ilog + _logs[share_byte]]; *share_ptr++ = share_byte ^ *coefficient_ptr++; } } } // ----------------------------------------------------[ Recombination ]---- // Inform a recombination context of a change in share indexes void gfshare_ctx_dec_newshares(gfshare_ctx *ctx,uint8_t *sharenrs) { memcpy(ctx->sharenrs,sharenrs,ctx->sharecount); } // Provide a share context with one of the shares. The 'sharenr' is the index into the 'sharenrs' array void gfshare_ctx_dec_giveshare(gfshare_ctx *ctx,uint8_t sharenr,uint8_t *share) { memcpy(ctx->buffer + (sharenr * ctx->size),share,ctx->size); } // Extract the secret by interpolating the shares. secretbuf must be allocated and at least 'size' bytes void gfshare_ctx_decextract(uint8_t *_logs,uint8_t *_exps,gfshare_ctx *ctx,uint8_t *secretbuf) { uint32_t i,j; uint8_t *secret_ptr,*share_ptr,sharei,sharej; for (i=0; isize; i++) secretbuf[i] = 0; for (i=0; isharecount; i++) { // Compute L(i) as per Lagrange Interpolation unsigned Li_top = 0, Li_bottom = 0; if ( (sharei= ctx->sharenrs[i]) != 0 ) { for (j=0; jsharecount; j++) { if ( i != j && sharei != (sharej= ctx->sharenrs[j]) ) { if ( sharej == 0 ) continue; // skip empty share Li_top += _logs[sharej]; if ( Li_top >= 0xff ) Li_top -= 0xff; Li_bottom += _logs[sharei ^ sharej]; if ( Li_bottom >= 0xff ) Li_bottom -= 0xff; } } if ( Li_bottom > Li_top ) Li_top += 0xff; Li_top -= Li_bottom; // Li_top is now log(L(i)) secret_ptr = secretbuf, share_ptr = ctx->buffer + (ctx->size * i); for (j=0; jsize; j++) { if ( *share_ptr != 0 ) *secret_ptr ^= _exps[Li_top + _logs[*share_ptr]]; share_ptr++, secret_ptr++; } } } } int32_t gfshare_test(struct supernet_info *myinfo,int32_t M,int32_t N,int32_t datasize) { int ok = 1, i,k; uint8_t * secret = malloc(datasize); uint8_t *shares[255]; uint8_t *recomb = malloc(datasize); uint8_t space[8192],sharenrs[255],newsharenrs[255];// = (uint8_t *)strdup("0124z89abehtr"); gfshare_ctx *G; for (i=0; i> 8; /* Stage 2, split it N ways with a threshold of M */ G = gfshare_ctx_initenc( sharenrs, N, M, datasize,space,sizeof(space) ); gfshare_ctx_enc_setsecret( G, secret ); for (i=0; ilogs,myinfo->exps, G, i, shares[i] ); gfshare_ctx_free( G ); /* Prep the decode shape */ uint8_t save[255]; memcpy(save,sharenrs,sizeof(sharenrs)); G = gfshare_ctx_initdec( sharenrs, N, datasize,space,sizeof(space) ); for (k=0; k<10; k++) { memcpy(sharenrs,save,sizeof(sharenrs)); memset(newsharenrs,0,N); int32_t j,r,m; m = M + (rand() % (N-M+1)); for (i=0; ilogs,myinfo->exps, G, recomb ); for (i=0; ictx = secp256k1_context_create(SECP256K1_CONTEXT_SIGN | SECP256K1_CONTEXT_VERIFY); secp256k1_pedersen_context_initialize(myinfo->ctx); secp256k1_rangeproof_context_initialize(myinfo->ctx); } void libgfshare_init(struct supernet_info *myinfo,uint8_t _logs[256],uint8_t _exps[510]) { uint32_t i,x = 1; myinfo->ctx = secp256k1_context_create(SECP256K1_CONTEXT_SIGN | SECP256K1_CONTEXT_VERIFY); secp256k1_pedersen_context_initialize(myinfo->ctx); secp256k1_rangeproof_context_initialize(myinfo->ctx); for (i=0; i<255; i++) { _exps[i] = x; _logs[x] = i; x <<= 1; if ( x & 0x100 ) x ^= 0x11d; // Unset the 8th bit and mix in 0x1d } for (i=255; i<510; i++) _exps[i] = _exps[i % 255]; _logs[0] = 0; // can't log(0) so just set it neatly to 0 if ( 0 ) { void test_mofn(struct supernet_info *myinfo); gfshare_test(myinfo,6,11,32); test_mofn(myinfo); getchar(); } } // Construct and write out the tables for the gfshare code int maingen(int argc,char **argv) { uint8_t logs[256],exps[255]; uint32_t i; libgfshare_init(0,logs,exps); // The above generation algorithm clearly demonstrates that // logs[exps[i]] == i for 0 <= i <= 254 // exps[logs[i]] == i for 1 <= i <= 255 // Spew out the tables fprintf(stdout, "\ /*\n\ * This file is autogenerated by gfshare_maketable.\n\ */\n\ \n\ static uint8_t logs[256] = {\n "); for ( i = 0; i < 256; ++i ) { fprintf(stdout, "0x%02x", logs[i]); if( i == 255 ) fprintf(stdout, " };\n"); else if( (i % 8) == 7 ) fprintf(stdout, ",\n "); else fprintf(stdout, ", "); } // The exp table we output from 0 to 509 because that way when we // do the lagrange interpolation we don't have to be quite so strict // with staying inside the field which makes it quicker fprintf(stdout, "\ \n\ static uint8_t exps[510] = {\n "); for ( i = 0; i < 510; ++i ) { fprintf(stdout, "0x%02x", exps[i % 255]); /* exps[255]==exps[0] */ if ( i == 509 ) fprintf(stdout, " };\n"); else if( (i % 8) == 7) fprintf(stdout, ",\n "); else fprintf(stdout, ", "); } return 0; } /****************************************************************************** * Copyright © 2014-2017 The SuperNET Developers. * * * * See the AUTHORS, DEVELOPER-AGREEMENT and LICENSE files at * * the top-level directory of this distribution for the individual copyright * * holder information and the developer policies on copyright and licensing. * * * * Unless otherwise agreed in a custom licensing agreement, no part of the * * SuperNET software, including this file may be copied, modified, propagated * * or distributed except according to the terms contained in the LICENSE file * * * * Removal or modification of this copyright notice is prohibited. * * * ******************************************************************************/ int32_t init_sharenrs(uint8_t sharenrs[255],uint8_t *orig,int32_t m,int32_t n) { uint8_t *randvals,valid[255]; int32_t i,j,r,remains,orign; if ( m > n || n >= 0xff ) // reserve 255 for illegal sharei { printf("illegal M.%d of N.%d\n",m,n); return(-1); } randvals = calloc(1,65536); OS_randombytes(randvals,65536); if ( orig == 0 && n == m ) { memset(sharenrs,0,n); for (i=0; i<255; i++) valid[i] = (i + 1); remains = orign = 255; for (i=0; i= M ) { G = gfshare_ctx_initdec(recovernrs,N,datasize,space,sizeof(space)); for (i=0; ilogs,myinfo->exps,G,recover); gfshare_ctx_free(G); return(recover); } else return(0); } void calc_share(struct supernet_info *myinfo,uint8_t *buffer,int32_t size,int32_t M,uint32_t ilog,uint8_t *share) { uint32_t pos,coefficient; uint8_t *share_ptr,share_byte; for (pos=0; posexps[ilog + myinfo->logs[share_byte]]; *share_ptr++ = (share_byte ^ *buffer++); } } } void calc_shares(struct supernet_info *myinfo,uint8_t *shares,uint8_t *secret,int32_t size,int32_t width,int32_t M,int32_t N,uint8_t *sharenrs,uint8_t *space,int32_t spacesize) { int32_t i; uint8_t *buffer; if ( M*width > spacesize ) { buffer = calloc(M,width); printf("calloc M.%d width.%d\n",M,width); } else buffer = space; memset(shares,0,N * width); memcpy(buffer + ((M - 1) * size),secret,size); OS_randombytes(buffer,(M - 1) * size); for (i=0; ilogs[sharenrs[i]],&shares[i * width]); //printf("(%03d %08x) ",sharenrs[i],calc_crc32(0,&shares[i * width],size)); } if ( buffer != space ) free(buffer); } int32_t calc_sharenrs(uint8_t *sharenrs,int32_t N,uint8_t *data,int32_t datasize) { bits256 hash,hash2; uint8_t r; int32_t i,j,n = sizeof(hash); vcalc_sha256(0,hash.bytes,data,datasize); vcalc_sha256(0,hash2.bytes,hash.bytes,sizeof(hash)); for (i=0; i= sizeof(hash) ) { vcalc_sha256(0,hash.bytes,hash2.bytes,sizeof(hash2)); vcalc_sha256(0,hash2.bytes,hash.bytes,sizeof(hash)); n = 0; } r = hash2.bytes[n++]; if ( (sharenrs[i]= r) == 0 || sharenrs[i] == 0xff ) continue; for (j=0; j N || N == 0 || N == 0xff ) return(0); allocsize = mofn256_size(M,N); if ( allocsize > spacesize ) { mofn = calloc(1,allocsize); mofn->allocsize = allocsize; } else { mofn = (void *)space; memset(mofn,0,allocsize); } mofn->M = M; mofn->N = N; mofn->sharenrs = (void *)&mofn->allshares[N]; if ( calcflag != 0 ) { mofn->secret = secret; calcmofn(myinfo,mofn->allshares[0].bytes,mofn->sharenrs,M,secret.bytes,sizeof(secret),N); } return(mofn); } bits256 mofn256_recover(struct supernet_info *myinfo,struct mofn256_info *mofn) { uint8_t *shares[255]; bits256 recover; int32_t i; for (i=0; iN; i++) { if ( bits256_nonz(mofn->allshares[i]) != 0 ) shares[i] = mofn->allshares[i].bytes; else shares[i] = 0; } if ( recoverdata(myinfo,shares,mofn->sharenrs,mofn->M,recover.bytes,sizeof(recover),mofn->N) == 0 ) memset(recover.bytes,0,sizeof(recover)); return(recover); } int32_t test_mofn256(struct supernet_info *myinfo,int32_t M,int32_t N) { uint8_t space[8192]; char str[65],str2[65]; struct mofn256_info *mofn,*cmp; bits256 secret,recover; int32_t i,allocsize,retval,m = 0; allocsize = mofn256_size(M,N); cmp = mofn256_init(myinfo,GENESIS_PUBKEY,M,N,0,space,sizeof(space)); secret = rand256(0); mofn = mofn256_init(myinfo,secret,M,N,1,&space[allocsize],sizeof(space) - allocsize); memcpy(cmp->sharenrs,mofn->sharenrs,mofn->N); for (i=0; iallshares[i] = mofn->allshares[i], m++; recover = mofn256_recover(myinfo,cmp); retval = -1 * (bits256_cmp(recover,mofn->secret) != 0); if ( bits256_cmp(recover,mofn->secret) != 0 ) { if ( m >= M ) printf("%s %s error m.%d vs M.%d N.%d\n",bits256_str(str,secret),bits256_str(str2,recover),m,mofn->M,mofn->N); } #if defined(_M_X64) if (((uint64_t)mofn - (uint64_t)space) >= sizeof(space) || ((uint64_t)mofn - (uint64_t)space) < 0) free(mofn); if (((uint64_t)cmp - (uint64_t)space) >= sizeof(space) || ((uint64_t)cmp - (uint64_t)space) < 0) free(cmp); #else if ( ((long)mofn - (long)space) >= sizeof(space) || ((long)mofn - (long)space) < 0 ) free(mofn); if ( ((long)cmp - (long)space) >= sizeof(space) || ((long)cmp - (long)space) < 0 ) free(cmp); #endif return(retval); } #define N 11 #define M 6 void test_mofn(struct supernet_info *myinfo) { bits256 allshares[N],secret,recover; uint8_t *shares[N],sharenrs[N]; int32_t i,j,m; secret = rand256(0); srand(secret.uints[0]); calcmofn(myinfo,allshares[0].bytes,sharenrs,M,secret.bytes,sizeof(secret),N); for (i=0; i<10000; i++) { memset(shares,0,sizeof(shares)); for (j=m=0; jbytes,pubkey33+1,32); break; } } if ( j == maxj ) { printf("couldnt generate even noncepair\n"); iguana_exit(0,0); } return(privnonce); } struct schnorr_info { bits256 msg256,privkey,pubkey,privnonce,pubnonce,serhash2; int32_t M,N; uint32_t msgid; uint8_t sig64[64],combinedsig64[64],allpub[33],combined_allpub[33]; uint16_t ind,nonz; bits256 *pubkeys,*pubnonces; uint8_t serialized[65 + sizeof(uint16_t) + sizeof(uint32_t) + sizeof(bits256)*4]; uint8_t sigs[]; }; int32_t schnorr_rwinitdata(int32_t rwflag,uint8_t *serialized,uint16_t *indp,uint32_t *msgidp,bits256 hashes[4]) { int32_t i,j,len = 0; len += iguana_rwnum(rwflag,&serialized[len],sizeof(*indp),indp); len += iguana_rwnum(rwflag,&serialized[len],sizeof(*msgidp),msgidp); for (j=0; j<4; j++) for (i=0; i<32; i++) iguana_rwnum(rwflag,&serialized[len++],1,&hashes[j].bytes[i]); return(len); } struct schnorr_info *schnorr_init(struct supernet_info *myinfo,uint32_t msgid,uint16_t ind,int32_t M,int32_t N,void *space,int32_t spacesize,bits256 msg256) { uint8_t *serialized; bits256 hashes[4]; int32_t len,odd_even = 0; struct schnorr_info *si = space; si->pubnonces = (void *)&si->sigs[N * 64]; si->pubkeys = &si->pubnonces[N]; si->M = M; si->N = N; si->ind = ind; si->msgid = msgid; si->msg256 = msg256; si->pubkey = bitcoin_pub256(myinfo->ctx,&si->privkey,odd_even); si->privnonce = iguana_schnorr_noncepair(myinfo->ctx,&si->pubnonce,odd_even,msg256,si->privkey,100); len = 0; serialized = &si->serialized[65]; hashes[0] = myinfo->myaddr.persistent; hashes[1] = si->pubkey; hashes[2] = si->pubnonce; hashes[3] = msg256; len = schnorr_rwinitdata(1,serialized,&ind,&msgid,hashes); blockhash_sha256(si->serhash2.bytes,serialized,len); if ( bitcoin_sign(myinfo->ctx,"SCHNORR",si->serialized,si->serhash2,myinfo->persistent_priv,1) != 65 ) printf("error signing schnorr initdata\n"); return(si); } int32_t schnorr_update(struct supernet_info *myinfo,struct schnorr_info *si,uint8_t *serialized,int32_t recvlen) { int32_t len; uint16_t ind; uint32_t msgid; bits256 hashes[4]; // verify compact sig len = schnorr_rwinitdata(0,&serialized[65],&ind,&msgid,hashes); // verify persistent pubkey matches ind if ( bits256_cmp(hashes[3],si->msg256) == 0 && msgid == si->msgid && bits256_nonz(si->pubkeys[ind]) == 0 && bits256_nonz(si->pubnonces[ind]) == 0 ) { si->pubkeys[ind] = hashes[1]; si->pubnonces[ind] = hashes[2]; if ( ++si->nonz >= si->M ) { iguana_schnorr_peersign(myinfo->ctx,si->allpub,si->sig64,si->ind,si->privkey,si->privnonce,si->pubnonces,si->M,si->msg256); // broadcast si->sig64 + ind + msgid } } return(si->M); } /*{ if ( bitcoin_schnorr_combine(myinfo->ctx,si->combinedsig64,si->combined_allpub,si->sigs,si->M,si->msg256) < 0 ) printf("error combining k.%d sig64 iter.%d\n",k,iter); if ( bitcoin_schnorr_verify(myinfo->ctx,si->combinedsig64,si->msg256,si->combined_allpub,33) < 0 ) printf("allpub2 error verifying combined sig k.%d\n",k); }*/ void iguana_schnorr(struct supernet_info *myinfo) { uint8_t allpubs[256][33],allpub[33],allpub2[33],sig64s[256][64],sig64[64],*sigs[256]; bits256 msg256,privnonces[256],signers,privkeys[256],pubkeys[256],pubkeysB[256],nonces[256]; int32_t i,iter,n,k,maxj = 100; OS_randombytes((void *)&n,sizeof(n)); srand(n); n = 1 + (rand() % 255); // generate onetime keypairs for (i=0; ictx,&privkeys[i],0); msg256 = rand256(0); for (i=0; ictx,&nonces[i],0,msg256,privkeys[i],maxj); for (i=0; ictx,allpubs[i],sig64s[i],i,privkeys[i],privnonces[i],nonces,n,msg256); for (iter=0; iter<1; iter++) { memset(signers.bytes,0,sizeof(signers)); for (i=k=0; ictx,sig64,allpub2,sigs,k,msg256) < 0 ) printf("error combining k.%d sig64 iter.%d\n",k,iter); else if ( bitcoin_schnorr_verify(myinfo->ctx,sig64,msg256,allpub2,33) < 0 ) printf("allpub2 error verifying combined sig k.%d\n",k); else if ( 0 ) // doesnt replicate with subsets { if ( bitcoin_pubkey_combine(myinfo->ctx,allpub,0,pubkeys,n,0,0) == 0 ) { if ( memcmp(allpub,allpubs[0],33) != 0 ) { printf("\n"); for (k=0; k<33; k++) printf("%02x",allpubs[0][k]); printf(" combined\n"); for (k=0; k<33; k++) printf("%02x",allpub[k]); printf(" allpub, "); printf("allpub mismatch iter.%d i.%d n.%d\n",iter,i,n); } else printf("validated iter.%d k.%d %llx\n",iter,k,(long long)signers.txid); } //else printf("error combining\n"); } else printf("passed n.%d\n",n); } }