-rw-r--r-- 23747 lib25519-20240321/command/lib25519-speed.c raw
/* WARNING: auto-generated (by autogen/speed); do not edit */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include <assert.h> #include <time.h> #include <sys/time.h> #include <sys/types.h> #include <sys/resource.h> #include "cpucycles.h" /* -lcpucycles */ #include "lib25519.h" /* -l25519 */ #include "randombytes.h" /* -lrandombytes */ static const char *targeto = 0; static const char *targetp = 0; static const char *targeti = 0; #include "limits.inc" static unsigned char *alignedcalloc(unsigned long long len) { unsigned char *x = (unsigned char *) calloc(1,len + 128); if (!x) abort(); /* will never deallocate so shifting is ok */ x += 63 & (-(unsigned long) x); return x; } #define TIMINGS 15 static long long t[TIMINGS+1]; static void t_print(const char *op,long long impl,long long len) { long long median = 0; printf("%s",op); if (impl >= 0) printf(" %lld",impl); else printf(" selected"); printf(" %lld",len); for (long long i = 0;i < TIMINGS;++i) t[i] = t[i+1]-t[i]; for (long long j = 0;j < TIMINGS;++j) { long long belowj = 0; long long abovej = 0; for (long long i = 0;i < TIMINGS;++i) if (t[i] < t[j]) ++belowj; for (long long i = 0;i < TIMINGS;++i) if (t[i] > t[j]) ++abovej; if (belowj*2 < TIMINGS && abovej*2 < TIMINGS) { median = t[j]; break; } } printf(" %lld ",median); for (long long i = 0;i < TIMINGS;++i) printf("%+lld",t[i]-median); printf("\n"); fflush(stdout); } #define MAXBATCH 16 #define MAXTEST_BYTES 65536 static void measure_cpucycles(void) { printf("cpucycles selected persecond %lld\n",cpucycles_persecond()); printf("cpucycles selected implementation %s\n",cpucycles_implementation()); for (long long i = 0;i <= TIMINGS;++i) t[i] = cpucycles(); t_print("cpucycles",-1,0); } static void measure_randombytes(void) { unsigned char *m = alignedcalloc(MAXTEST_BYTES); long long mlen = 0; while (mlen < MAXTEST_BYTES) { for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); randombytes(m,mlen); } t_print("randombytes",-1,mlen); mlen += 1+mlen/2; } } static void measure_verify_32(void) { if (targeto && strcmp(targeto,"verify")) return; if (targetp && strcmp(targetp,"32")) return; unsigned char *x = alignedcalloc(lib25519_verify_32_BYTES); unsigned char *y = alignedcalloc(lib25519_verify_32_BYTES); for (long long impl = -1;impl < lib25519_numimpl_verify_32();++impl) { int (*crypto_verify)(const unsigned char *,const unsigned char *); if (targeti && strcmp(targeti,lib25519_dispatch_verify_32_implementation(impl))) continue; if (impl >= 0) { crypto_verify = lib25519_dispatch_verify_32(impl); printf("verify_32 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_verify_32_implementation(impl),lib25519_dispatch_verify_32_compiler(impl)); } else { crypto_verify = lib25519_verify_32; printf("verify_32 selected implementation %s compiler %s\n",lib25519_verify_32_implementation(),lib25519_verify_32_compiler()); } randombytes(x,lib25519_verify_32_BYTES); randombytes(y,lib25519_verify_32_BYTES); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_verify(x,y); } t_print("verify_32",impl,lib25519_verify_32_BYTES); } } static void measure_hashblocks_sha512(void) { if (targeto && strcmp(targeto,"hashblocks")) return; if (targetp && strcmp(targetp,"sha512")) return; unsigned char *h = alignedcalloc(lib25519_hashblocks_sha512_STATEBYTES); unsigned char *m = alignedcalloc(MAXTEST_BYTES); long long mlen; for (long long impl = -1;impl < lib25519_numimpl_hashblocks_sha512();++impl) { int (*crypto_hashblocks)(unsigned char *,const unsigned char *,long long); if (targeti && strcmp(targeti,lib25519_dispatch_hashblocks_sha512_implementation(impl))) continue; if (impl >= 0) { crypto_hashblocks = lib25519_dispatch_hashblocks_sha512(impl); printf("hashblocks_sha512 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_hashblocks_sha512_implementation(impl),lib25519_dispatch_hashblocks_sha512_compiler(impl)); } else { crypto_hashblocks = lib25519_hashblocks_sha512; printf("hashblocks_sha512 selected implementation %s compiler %s\n",lib25519_hashblocks_sha512_implementation(),lib25519_hashblocks_sha512_compiler()); } randombytes(h,lib25519_hashblocks_sha512_STATEBYTES); randombytes(m,MAXTEST_BYTES); mlen = 0; while (mlen <= MAXTEST_BYTES) { randombytes(m,mlen); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_hashblocks(h,m,mlen); } t_print("hashblocks_sha512",impl,mlen); mlen += 1+mlen/2; } } } static void measure_hash_sha512(void) { if (targeto && strcmp(targeto,"hash")) return; if (targetp && strcmp(targetp,"sha512")) return; unsigned char *h = alignedcalloc(lib25519_hash_sha512_BYTES); unsigned char *m = alignedcalloc(MAXTEST_BYTES); long long mlen; for (long long impl = -1;impl < lib25519_numimpl_hash_sha512();++impl) { void (*crypto_hash)(unsigned char *,const unsigned char *,long long); if (targeti && strcmp(targeti,lib25519_dispatch_hash_sha512_implementation(impl))) continue; if (impl >= 0) { crypto_hash = lib25519_dispatch_hash_sha512(impl); printf("hash_sha512 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_hash_sha512_implementation(impl),lib25519_dispatch_hash_sha512_compiler(impl)); } else { crypto_hash = lib25519_hash_sha512; printf("hash_sha512 selected implementation %s compiler %s\n",lib25519_hash_sha512_implementation(),lib25519_hash_sha512_compiler()); } randombytes(h,lib25519_hash_sha512_BYTES); randombytes(m,MAXTEST_BYTES); mlen = 0; while (mlen <= MAXTEST_BYTES) { randombytes(m,mlen); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_hash(h,m,mlen); } t_print("hash_sha512",impl,mlen); mlen += 1+mlen/2; } } } static void measure_pow_inv25519(void) { if (targeto && strcmp(targeto,"pow")) return; if (targetp && strcmp(targetp,"inv25519")) return; unsigned char *n = alignedcalloc(lib25519_pow_inv25519_BYTES); unsigned char *ne = alignedcalloc(lib25519_pow_inv25519_BYTES); for (long long impl = -1;impl < lib25519_numimpl_pow_inv25519();++impl) { void (*crypto_pow)(unsigned char *,const unsigned char *); if (targeti && strcmp(targeti,lib25519_dispatch_pow_inv25519_implementation(impl))) continue; if (impl >= 0) { crypto_pow = lib25519_dispatch_pow_inv25519(impl); printf("pow_inv25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_pow_inv25519_implementation(impl),lib25519_dispatch_pow_inv25519_compiler(impl)); } else { crypto_pow = lib25519_pow_inv25519; printf("pow_inv25519 selected implementation %s compiler %s\n",lib25519_pow_inv25519_implementation(),lib25519_pow_inv25519_compiler()); } randombytes(n,lib25519_pow_inv25519_BYTES); randombytes(ne,lib25519_pow_inv25519_BYTES); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_pow(ne,n); } t_print("pow_inv25519",impl,lib25519_pow_inv25519_BYTES); } } static void measure_powbatch_inv25519(void) { if (targeto && strcmp(targeto,"powbatch")) return; if (targetp && strcmp(targetp,"inv25519")) return; unsigned char *n = alignedcalloc(MAXBATCH*lib25519_powbatch_inv25519_BYTES); unsigned char *ne = alignedcalloc(MAXBATCH*lib25519_powbatch_inv25519_BYTES); for (long long impl = -1;impl < lib25519_numimpl_powbatch_inv25519();++impl) { void (*crypto_powbatch)(unsigned char *,const unsigned char *,long long); if (targeti && strcmp(targeti,lib25519_dispatch_powbatch_inv25519_implementation(impl))) continue; if (impl >= 0) { crypto_powbatch = lib25519_dispatch_powbatch_inv25519(impl); printf("powbatch_inv25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_powbatch_inv25519_implementation(impl),lib25519_dispatch_powbatch_inv25519_compiler(impl)); } else { crypto_powbatch = lib25519_powbatch_inv25519; printf("powbatch_inv25519 selected implementation %s compiler %s\n",lib25519_powbatch_inv25519_implementation(),lib25519_powbatch_inv25519_compiler()); } randombytes(n,MAXBATCH*lib25519_powbatch_inv25519_BYTES); randombytes(ne,MAXBATCH*lib25519_powbatch_inv25519_BYTES); for (long long batch = 0;batch <= MAXBATCH;++batch) { for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_powbatch(ne,n,batch); } t_print("powbatch_inv25519",impl,batch); } } } static void measure_nP_montgomery25519(void) { if (targeto && strcmp(targeto,"nP")) return; if (targetp && strcmp(targetp,"montgomery25519")) return; unsigned char *n = alignedcalloc(lib25519_nP_montgomery25519_SCALARBYTES); unsigned char *P = alignedcalloc(lib25519_nP_montgomery25519_POINTBYTES); unsigned char *nP = alignedcalloc(lib25519_nP_montgomery25519_POINTBYTES); for (long long impl = -1;impl < lib25519_numimpl_nP_montgomery25519();++impl) { void (*crypto_nP)(unsigned char *,const unsigned char *,const unsigned char *); if (targeti && strcmp(targeti,lib25519_dispatch_nP_montgomery25519_implementation(impl))) continue; if (impl >= 0) { crypto_nP = lib25519_dispatch_nP_montgomery25519(impl); printf("nP_montgomery25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_nP_montgomery25519_implementation(impl),lib25519_dispatch_nP_montgomery25519_compiler(impl)); } else { crypto_nP = lib25519_nP_montgomery25519; printf("nP_montgomery25519 selected implementation %s compiler %s\n",lib25519_nP_montgomery25519_implementation(),lib25519_nP_montgomery25519_compiler()); } randombytes(n,lib25519_nP_montgomery25519_SCALARBYTES); randombytes(P,lib25519_nP_montgomery25519_POINTBYTES); randombytes(nP,lib25519_nP_montgomery25519_POINTBYTES); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_nP(nP,n,P); } t_print("nP_montgomery25519",impl,lib25519_nP_montgomery25519_POINTBYTES); } } static void measure_nPbatch_montgomery25519(void) { if (targeto && strcmp(targeto,"nPbatch")) return; if (targetp && strcmp(targetp,"montgomery25519")) return; unsigned char *n = alignedcalloc(MAXBATCH*lib25519_nPbatch_montgomery25519_SCALARBYTES); unsigned char *P = alignedcalloc(MAXBATCH*lib25519_nPbatch_montgomery25519_POINTBYTES); unsigned char *nP = alignedcalloc(MAXBATCH*lib25519_nPbatch_montgomery25519_POINTBYTES); for (long long impl = -1;impl < lib25519_numimpl_nPbatch_montgomery25519();++impl) { void (*crypto_nPbatch)(unsigned char *,const unsigned char *,const unsigned char *,long long); if (targeti && strcmp(targeti,lib25519_dispatch_nPbatch_montgomery25519_implementation(impl))) continue; if (impl >= 0) { crypto_nPbatch = lib25519_dispatch_nPbatch_montgomery25519(impl); printf("nPbatch_montgomery25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_nPbatch_montgomery25519_implementation(impl),lib25519_dispatch_nPbatch_montgomery25519_compiler(impl)); } else { crypto_nPbatch = lib25519_nPbatch_montgomery25519; printf("nPbatch_montgomery25519 selected implementation %s compiler %s\n",lib25519_nPbatch_montgomery25519_implementation(),lib25519_nPbatch_montgomery25519_compiler()); } randombytes(n,MAXBATCH*lib25519_nPbatch_montgomery25519_SCALARBYTES); randombytes(P,MAXBATCH*lib25519_nPbatch_montgomery25519_POINTBYTES); randombytes(nP,MAXBATCH*lib25519_nPbatch_montgomery25519_POINTBYTES); for (long long batch = 0;batch <= MAXBATCH;++batch) { for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_nPbatch(nP,n,P,batch); } t_print("nPbatch_montgomery25519",impl,batch); } } } static void measure_nG_merged25519(void) { if (targeto && strcmp(targeto,"nG")) return; if (targetp && strcmp(targetp,"merged25519")) return; unsigned char *n = alignedcalloc(lib25519_nG_merged25519_SCALARBYTES); unsigned char *nG = alignedcalloc(lib25519_nG_merged25519_POINTBYTES); for (long long impl = -1;impl < lib25519_numimpl_nG_merged25519();++impl) { void (*crypto_nG)(unsigned char *,const unsigned char *); if (targeti && strcmp(targeti,lib25519_dispatch_nG_merged25519_implementation(impl))) continue; if (impl >= 0) { crypto_nG = lib25519_dispatch_nG_merged25519(impl); printf("nG_merged25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_nG_merged25519_implementation(impl),lib25519_dispatch_nG_merged25519_compiler(impl)); } else { crypto_nG = lib25519_nG_merged25519; printf("nG_merged25519 selected implementation %s compiler %s\n",lib25519_nG_merged25519_implementation(),lib25519_nG_merged25519_compiler()); } randombytes(n,lib25519_nG_merged25519_SCALARBYTES); randombytes(nG,lib25519_nG_merged25519_POINTBYTES); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_nG(nG,n); } t_print("nG_merged25519",impl,lib25519_nG_merged25519_POINTBYTES); } } static void measure_nG_montgomery25519(void) { if (targeto && strcmp(targeto,"nG")) return; if (targetp && strcmp(targetp,"montgomery25519")) return; unsigned char *n = alignedcalloc(lib25519_nG_montgomery25519_SCALARBYTES); unsigned char *nG = alignedcalloc(lib25519_nG_montgomery25519_POINTBYTES); for (long long impl = -1;impl < lib25519_numimpl_nG_montgomery25519();++impl) { void (*crypto_nG)(unsigned char *,const unsigned char *); if (targeti && strcmp(targeti,lib25519_dispatch_nG_montgomery25519_implementation(impl))) continue; if (impl >= 0) { crypto_nG = lib25519_dispatch_nG_montgomery25519(impl); printf("nG_montgomery25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_nG_montgomery25519_implementation(impl),lib25519_dispatch_nG_montgomery25519_compiler(impl)); } else { crypto_nG = lib25519_nG_montgomery25519; printf("nG_montgomery25519 selected implementation %s compiler %s\n",lib25519_nG_montgomery25519_implementation(),lib25519_nG_montgomery25519_compiler()); } randombytes(n,lib25519_nG_montgomery25519_SCALARBYTES); randombytes(nG,lib25519_nG_montgomery25519_POINTBYTES); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_nG(nG,n); } t_print("nG_montgomery25519",impl,lib25519_nG_montgomery25519_POINTBYTES); } } static void measure_mGnP_ed25519(void) { if (targeto && strcmp(targeto,"mGnP")) return; if (targetp && strcmp(targetp,"ed25519")) return; unsigned char *mGnP = alignedcalloc(lib25519_mGnP_ed25519_OUTPUTBYTES); unsigned char *m = alignedcalloc(lib25519_mGnP_ed25519_MBYTES); unsigned char *n = alignedcalloc(lib25519_mGnP_ed25519_NBYTES); unsigned char *P = alignedcalloc(lib25519_mGnP_ed25519_PBYTES); for (long long impl = -1;impl < lib25519_numimpl_mGnP_ed25519();++impl) { void (*crypto_mGnP)(unsigned char *,const unsigned char *,const unsigned char *,const unsigned char *); if (targeti && strcmp(targeti,lib25519_dispatch_mGnP_ed25519_implementation(impl))) continue; if (impl >= 0) { crypto_mGnP = lib25519_dispatch_mGnP_ed25519(impl); printf("mGnP_ed25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_mGnP_ed25519_implementation(impl),lib25519_dispatch_mGnP_ed25519_compiler(impl)); } else { crypto_mGnP = lib25519_mGnP_ed25519; printf("mGnP_ed25519 selected implementation %s compiler %s\n",lib25519_mGnP_ed25519_implementation(),lib25519_mGnP_ed25519_compiler()); } randombytes(mGnP,lib25519_mGnP_ed25519_OUTPUTBYTES); randombytes(m,lib25519_mGnP_ed25519_MBYTES); randombytes(n,lib25519_mGnP_ed25519_NBYTES); randombytes(P,lib25519_mGnP_ed25519_PBYTES); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_mGnP(mGnP,m,n,P); } t_print("mGnP_ed25519",impl,lib25519_mGnP_ed25519_OUTPUTBYTES); } } static void measure_multiscalar_ed25519(void) { if (targeto && strcmp(targeto,"multiscalar")) return; if (targetp && strcmp(targetp,"ed25519")) return; unsigned char *Q = alignedcalloc(MAXBATCH*lib25519_multiscalar_ed25519_OUTPUTBYTES); unsigned char *n = alignedcalloc(MAXBATCH*lib25519_multiscalar_ed25519_SCALARBYTES); unsigned char *P = alignedcalloc(MAXBATCH*lib25519_multiscalar_ed25519_POINTBYTES); for (long long impl = -1;impl < lib25519_numimpl_multiscalar_ed25519();++impl) { void (*crypto_multiscalar)(unsigned char *,const unsigned char *,const unsigned char *,long long); if (targeti && strcmp(targeti,lib25519_dispatch_multiscalar_ed25519_implementation(impl))) continue; if (impl >= 0) { crypto_multiscalar = lib25519_dispatch_multiscalar_ed25519(impl); printf("multiscalar_ed25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_multiscalar_ed25519_implementation(impl),lib25519_dispatch_multiscalar_ed25519_compiler(impl)); } else { crypto_multiscalar = lib25519_multiscalar_ed25519; printf("multiscalar_ed25519 selected implementation %s compiler %s\n",lib25519_multiscalar_ed25519_implementation(),lib25519_multiscalar_ed25519_compiler()); } randombytes(Q,MAXBATCH*lib25519_multiscalar_ed25519_OUTPUTBYTES); randombytes(n,MAXBATCH*lib25519_multiscalar_ed25519_SCALARBYTES); randombytes(P,MAXBATCH*lib25519_multiscalar_ed25519_POINTBYTES); for (long long batch = 0;batch <= MAXBATCH;++batch) { for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_multiscalar(Q,n,P,batch); } t_print("multiscalar_ed25519",impl,batch); } } } static void measure_dh_x25519(void) { if (targeto && strcmp(targeto,"dh")) return; if (targetp && strcmp(targetp,"x25519")) return; unsigned char *pka = alignedcalloc(lib25519_dh_x25519_PUBLICKEYBYTES); unsigned char *ska = alignedcalloc(lib25519_dh_x25519_SECRETKEYBYTES); unsigned char *pkb = alignedcalloc(lib25519_dh_x25519_PUBLICKEYBYTES); unsigned char *skb = alignedcalloc(lib25519_dh_x25519_SECRETKEYBYTES); unsigned char *ka = alignedcalloc(lib25519_dh_x25519_BYTES); for (long long impl = -1;impl < lib25519_numimpl_dh_x25519();++impl) { void (*crypto_dh_keypair)(unsigned char *,unsigned char *); void (*crypto_dh)(unsigned char *,const unsigned char *,const unsigned char *); if (targeti && strcmp(targeti,lib25519_dispatch_dh_x25519_implementation(impl))) continue; if (impl >= 0) { crypto_dh_keypair = lib25519_dispatch_dh_x25519_keypair(impl); crypto_dh = lib25519_dispatch_dh_x25519(impl); printf("dh_x25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_dh_x25519_implementation(impl),lib25519_dispatch_dh_x25519_compiler(impl)); } else { crypto_dh_keypair = lib25519_dh_x25519_keypair; crypto_dh = lib25519_dh_x25519; printf("dh_x25519 selected implementation %s compiler %s\n",lib25519_dh_x25519_implementation(),lib25519_dh_x25519_compiler()); } randombytes(pka,lib25519_dh_x25519_PUBLICKEYBYTES); randombytes(ska,lib25519_dh_x25519_SECRETKEYBYTES); randombytes(pkb,lib25519_dh_x25519_PUBLICKEYBYTES); randombytes(skb,lib25519_dh_x25519_SECRETKEYBYTES); randombytes(ka,lib25519_dh_x25519_BYTES); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_dh_keypair(pka,ska); } t_print("dh_x25519_keypair",impl,lib25519_dh_x25519_PUBLICKEYBYTES); crypto_dh_keypair(pkb,skb); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_dh(ka,pkb,ska); } t_print("dh_x25519",impl,lib25519_dh_x25519_BYTES); } } static void measure_sign_ed25519(void) { if (targeto && strcmp(targeto,"sign")) return; if (targetp && strcmp(targetp,"ed25519")) return; unsigned char *pk = alignedcalloc(lib25519_sign_ed25519_PUBLICKEYBYTES); unsigned char *sk = alignedcalloc(lib25519_sign_ed25519_SECRETKEYBYTES); unsigned char *m = alignedcalloc(MAXTEST_BYTES+lib25519_sign_ed25519_BYTES); unsigned char *sm = alignedcalloc(MAXTEST_BYTES+lib25519_sign_ed25519_BYTES); unsigned char *m2 = alignedcalloc(MAXTEST_BYTES+lib25519_sign_ed25519_BYTES); long long mlen; long long smlen; long long m2len; for (long long impl = -1;impl < lib25519_numimpl_sign_ed25519();++impl) { void (*crypto_sign_keypair)(unsigned char *,unsigned char *); void (*crypto_sign)(unsigned char *,long long *,const unsigned char *,long long,const unsigned char *); int (*crypto_sign_open)(unsigned char *,long long *,const unsigned char *,long long,const unsigned char *); if (targeti && strcmp(targeti,lib25519_dispatch_sign_ed25519_implementation(impl))) continue; if (impl >= 0) { crypto_sign_keypair = lib25519_dispatch_sign_ed25519_keypair(impl); crypto_sign = lib25519_dispatch_sign_ed25519(impl); crypto_sign_open = lib25519_dispatch_sign_ed25519_open(impl); printf("sign_ed25519 %lld implementation %s compiler %s\n",impl,lib25519_dispatch_sign_ed25519_implementation(impl),lib25519_dispatch_sign_ed25519_compiler(impl)); } else { crypto_sign_keypair = lib25519_sign_ed25519_keypair; crypto_sign = lib25519_sign_ed25519; crypto_sign_open = lib25519_sign_ed25519_open; printf("sign_ed25519 selected implementation %s compiler %s\n",lib25519_sign_ed25519_implementation(),lib25519_sign_ed25519_compiler()); } randombytes(pk,lib25519_sign_ed25519_PUBLICKEYBYTES); randombytes(sk,lib25519_sign_ed25519_SECRETKEYBYTES); randombytes(m,MAXTEST_BYTES+lib25519_sign_ed25519_BYTES); randombytes(sm,MAXTEST_BYTES+lib25519_sign_ed25519_BYTES); randombytes(m2,MAXTEST_BYTES+lib25519_sign_ed25519_BYTES); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_sign_keypair(pk,sk); } t_print("sign_ed25519_keypair",impl,lib25519_sign_ed25519_PUBLICKEYBYTES); mlen = 0; while (mlen <= MAXTEST_BYTES) { randombytes(m,mlen); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_sign(sm,&smlen,m,mlen,sk); } t_print("sign_ed25519",impl,mlen); mlen += 1+mlen/4; } mlen = 0; while (mlen <= MAXTEST_BYTES) { randombytes(m,mlen); lib25519_sign(sm,&smlen,m,mlen,sk); for (long long i = 0;i <= TIMINGS;++i) { t[i] = cpucycles(); crypto_sign_open(m2,&m2len,sm,smlen,pk); } t_print("sign_ed25519_open",impl,mlen); /* this is, in principle, not a test program */ /* but some checks here help validate the data flow above */ assert(m2len == mlen); assert(!memcmp(m,m2,mlen)); mlen += 1+mlen/4; } } } #include "print_cpuid.inc" int main(int argc,char **argv) { printf("lib25519 version %s\n",lib25519_version); printf("lib25519 arch %s\n",lib25519_arch); print_cpuid(); if (*argv) ++argv; if (*argv) { targeto = *argv++; if (*argv) { targetp = *argv++; if (*argv) { targeti = *argv++; } } } measure_cpucycles(); measure_randombytes(); limits(); measure_verify_32(); measure_hashblocks_sha512(); measure_hash_sha512(); measure_pow_inv25519(); measure_powbatch_inv25519(); measure_nP_montgomery25519(); measure_nPbatch_montgomery25519(); measure_nG_merged25519(); measure_nG_montgomery25519(); measure_mGnP_ed25519(); measure_multiscalar_ed25519(); measure_dh_x25519(); measure_sign_ed25519(); return 0; }