#!/usr/bin/env python3 import random # ----- precomputed test vectors precomputed = {} # ----- Z = r'''/* WARNING: auto-generated (by autogen/test); do not edit */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "crypto_uint8.h" #include "crypto_uint32.h" #include "crypto_uint64.h" #include "crypto_declassify.h" #include /* -lmceliece */ #include static const char *targeto = 0; static const char *targetp = 0; static const char *targeti = 0; static const char *targetn = 0; static const char *targetoffset = 0; static int ok = 1; #define fail ((ok = 0),printf) /* ----- valgrind support */ static int valgrind = 0; static unsigned char valgrind_undefined_byte = 0; static char *volatile valgrind_pointer = 0; static char *valgrind_malloc_1(void) { char *x = malloc(1); if (!x) abort(); *(char **volatile) &valgrind_pointer = x; return valgrind_pointer; } static void valgrind_init(void) { char *e = getenv("valgrind_multiplier"); char *x; if (!e) return; x = valgrind_malloc_1(); valgrind_undefined_byte = x[0]+1; valgrind_undefined_byte *= atoi(e); valgrind_undefined_byte ^= x[0]+1; free(x); valgrind = 1; } static void secret(void *xvoid,long long xlen) { unsigned char *x = xvoid; while (xlen > 0) { *x ^= valgrind_undefined_byte; ++x; --xlen; } } static void public(void *x,long long xlen) { crypto_declassify(x,xlen); } /* ----- rng and hash, from supercop/try-anything.c */ typedef crypto_uint8 u8; typedef crypto_uint32 u32; typedef crypto_uint64 u64; #define FOR(i,n) for (i = 0;i < n;++i) static u32 L32(u32 x,int c) { return (x << c) | ((x&0xffffffff) >> (32 - c)); } static u32 ld32(const u8 *x) { u32 u = x[3]; u = (u<<8)|x[2]; u = (u<<8)|x[1]; return (u<<8)|x[0]; } static void st32(u8 *x,u32 u) { int i; FOR(i,4) { x[i] = u; u >>= 8; } } static const u8 sigma[17] = "expand 32-byte k"; static void core_salsa(u8 *out,const u8 *in,const u8 *k) { u32 w[16],x[16],y[16],t[4]; int i,j,m; FOR(i,4) { x[5*i] = ld32(sigma+4*i); x[1+i] = ld32(k+4*i); x[6+i] = ld32(in+4*i); x[11+i] = ld32(k+16+4*i); } FOR(i,16) y[i] = x[i]; FOR(i,20) { FOR(j,4) { FOR(m,4) t[m] = x[(5*j+4*m)%16]; t[1] ^= L32(t[0]+t[3], 7); t[2] ^= L32(t[1]+t[0], 9); t[3] ^= L32(t[2]+t[1],13); t[0] ^= L32(t[3]+t[2],18); FOR(m,4) w[4*j+(j+m)%4] = t[m]; } FOR(m,16) x[m] = w[m]; } FOR(i,16) st32(out + 4 * i,x[i] + y[i]); } static void salsa20(u8 *c,u64 b,const u8 *n,const u8 *k) { u8 z[16],x[64]; u32 u,i; if (!b) return; FOR(i,16) z[i] = 0; FOR(i,8) z[i] = n[i]; while (b >= 64) { core_salsa(x,z,k); FOR(i,64) c[i] = x[i]; u = 1; for (i = 8;i < 16;++i) { u += (u32) z[i]; z[i] = u; u >>= 8; } b -= 64; c += 64; } if (b) { core_salsa(x,z,k); FOR(i,b) c[i] = x[i]; } } static void increment(u8 *n) { if (!++n[0]) if (!++n[1]) if (!++n[2]) if (!++n[3]) if (!++n[4]) if (!++n[5]) if (!++n[6]) if (!++n[7]) ; } static unsigned char testvector_n[8]; static void testvector_clear(void) { memset(testvector_n,0,sizeof testvector_n); } static void testvector(unsigned char *x,unsigned long long xlen) { const static unsigned char testvector_k[33] = "generate inputs for test vectors"; salsa20(x,xlen,testvector_n,testvector_k); increment(testvector_n); } static unsigned long long myrandom(void) { unsigned char x[8]; unsigned long long result; testvector(x,8); result = x[7]; result = (result<<8)|x[6]; result = (result<<8)|x[5]; result = (result<<8)|x[4]; result = (result<<8)|x[3]; result = (result<<8)|x[2]; result = (result<<8)|x[1]; result = (result<<8)|x[0]; return result; } static unsigned char canary_n[8]; static void canary(unsigned char *x,unsigned long long xlen) { const static unsigned char canary_k[33] = "generate pad to catch overwrites"; salsa20(x,xlen,canary_n,canary_k); increment(canary_n); } static void double_canary(unsigned char *x2,unsigned char *x,unsigned long long xlen) { if (valgrind) return; canary(x - 16,16); canary(x + xlen,16); memcpy(x2 - 16,x - 16,16); memcpy(x2 + xlen,x + xlen,16); } static void input_prepare(unsigned char *x2,unsigned char *x,unsigned long long xlen) { testvector(x,xlen); if (valgrind) { memcpy(x2,x,xlen); return; } canary(x - 16,16); canary(x + xlen,16); memcpy(x2 - 16,x - 16,xlen + 32); } static void input_compare(const unsigned char *x2,const unsigned char *x,unsigned long long xlen,const char *fun) { if (valgrind) return; if (memcmp(x2 - 16,x - 16,xlen + 32)) { fail("failure: %s overwrites input\n",fun); } } static void output_prepare(unsigned char *x2,unsigned char *x,unsigned long long xlen) { if (valgrind) { memcpy(x2,x,xlen); return; } canary(x - 16,xlen + 32); memcpy(x2 - 16,x - 16,xlen + 32); } static void output_compare(const unsigned char *x2,const unsigned char *x,unsigned long long xlen,const char *fun) { if (valgrind) return; if (memcmp(x2 - 16,x - 16,16)) { fail("failure: %s writes before output\n",fun); } if (memcmp(x2 + xlen,x + xlen,16)) { fail("failure: %s writes after output\n",fun); } } /* ----- knownrandombytes */ static const int knownrandombytes_is_only_for_testing_not_for_cryptographic_use = 1; #define knownrandombytes randombytes #define QUARTERROUND(a,b,c,d) \ a += b; d = L32(d^a,16); \ c += d; b = L32(b^c,12); \ a += b; d = L32(d^a, 8); \ c += d; b = L32(b^c, 7); static void core_chacha(u8 *out,const u8 *in,const u8 *k) { u32 x[16],y[16]; int i,j; FOR(i,4) { x[i] = ld32(sigma+4*i); x[12+i] = ld32(in+4*i); } FOR(i,8) x[4+i] = ld32(k+4*i); FOR(i,16) y[i] = x[i]; FOR(i,10) { FOR(j,4) { QUARTERROUND(x[j],x[j+4],x[j+8],x[j+12]) } FOR(j,4) { QUARTERROUND(x[j],x[((j+1)&3)+4],x[((j+2)&3)+8],x[((j+3)&3)+12]) } } FOR(i,16) st32(out+4*i,x[i]+y[i]); } static void chacha20(u8 *c,u64 b,const u8 *n,const u8 *k) { u8 z[16],x[64]; u32 u,i; if (!b) return; FOR(i,16) z[i] = 0; FOR(i,8) z[i+8] = n[i]; while (b >= 64) { core_chacha(x,z,k); FOR(i,64) c[i] = x[i]; u = 1; FOR(i,8) { u += (u32) z[i]; z[i] = u; u >>= 8; } b -= 64; c += 64; } if (b) { core_chacha(x,z,k); FOR(i,b) c[i] = x[i]; } } #define crypto_rng_OUTPUTBYTES 736 static int crypto_rng( unsigned char *r, /* random output */ unsigned char *n, /* new key */ const unsigned char *g /* old key */ ) { static const unsigned char nonce[8] = {0}; unsigned char x[32+crypto_rng_OUTPUTBYTES]; chacha20(x,sizeof x,nonce,g); memcpy(n,x,32); memcpy(r,x+32,crypto_rng_OUTPUTBYTES); return 0; } static unsigned char knownrandombytes_g[32]; static unsigned char knownrandombytes_r[crypto_rng_OUTPUTBYTES]; static unsigned long long knownrandombytes_pos = crypto_rng_OUTPUTBYTES; static void knownrandombytes_clear(void) { memset(knownrandombytes_g,0,sizeof knownrandombytes_g); memset(knownrandombytes_r,0,sizeof knownrandombytes_r); knownrandombytes_pos = crypto_rng_OUTPUTBYTES; } void knownrandombytes_main(void *xvoid,long long xlen) { unsigned char *x = xvoid; assert(knownrandombytes_is_only_for_testing_not_for_cryptographic_use); while (xlen > 0) { if (knownrandombytes_pos == crypto_rng_OUTPUTBYTES) { crypto_rng(knownrandombytes_r,knownrandombytes_g,knownrandombytes_g); knownrandombytes_pos = 0; } *x++ = knownrandombytes_r[knownrandombytes_pos]; xlen -= 1; knownrandombytes_r[knownrandombytes_pos++] = 0; } } void knownrandombytes(void *xvoid,long long xlen) { knownrandombytes_main(xvoid,xlen); secret(xvoid,xlen); } /* ----- checksums */ static unsigned char checksum_state[64]; static char checksum_hex[65]; static void checksum_expected(const char *expected) { long long i; for (i = 0;i < 32;++i) { checksum_hex[2 * i] = "0123456789abcdef"[15 & (checksum_state[i] >> 4)]; checksum_hex[2 * i + 1] = "0123456789abcdef"[15 & checksum_state[i]]; } checksum_hex[2 * i] = 0; if (strcmp(checksum_hex,expected)) fail("failure: checksum mismatch: %s expected %s\n",checksum_hex,expected); } static void checksum_clear(void) { memset(checksum_state,0,sizeof checksum_state); knownrandombytes_clear(); testvector_clear(); /* not necessary to clear canary */ } static void checksum(const unsigned char *x,unsigned long long xlen) { u8 block[16]; int i; while (xlen >= 16) { core_salsa(checksum_state,x,checksum_state); x += 16; xlen -= 16; } FOR(i,16) block[i] = 0; FOR(i,xlen) block[i] = x[i]; block[xlen] = 1; checksum_state[0] ^= 1; core_salsa(checksum_state,block,checksum_state); } #include "limits.inc" static void *callocplus(long long len) { if (valgrind) { unsigned char *x = malloc(len); if (!x) abort(); return x; } else { unsigned char *x = calloc(1,len + 256); long long i; if (!x) abort(); for (i = 0;i < len + 256;++i) x[i] = random(); return x; } } static void *aligned(void *x,long long len) { if (valgrind) return x; else { long long i; unsigned char *y = x; y += 64; y += 63 & (-(unsigned long) y); for (i = 0;i < len;++i) y[i] = 0; return y; } } /* ----- catching SIGILL, SIGBUS, SIGSEGV, etc. */ static void forked(void (*test)(long long),long long impl) { if (valgrind) { test(impl); return; } fflush(stdout); pid_t child = fork(); int childstatus = -1; if (child == -1) { fprintf(stderr,"fatal: fork failed: %s",strerror(errno)); exit(111); } if (child == 0) { ok = 1; limits(); test(impl); if (!ok) exit(100); exit(0); } if (waitpid(child,&childstatus,0) != child) { fprintf(stderr,"fatal: wait failed: %s",strerror(errno)); exit(111); } if (childstatus) fail("failure: process failed, status %d\n",childstatus); fflush(stdout); } /* ----- endianness */ /* on big-endian machines, flip into little-endian */ /* other types of endianness are not supported */ static void endianness(unsigned char *e,unsigned long long words,unsigned long long bytesperword) { long long i = 1; if (1 == *(unsigned char *) &i) return; while (words > 0) { for (i = 0;2 * i < bytesperword;++i) { long long j = bytesperword - 1 - i; unsigned char ei = e[i]; e[i] = e[j]; e[j] = ei; } e += bytesperword; words -= 1; } } ''' checksums = {} operations = [] primitives = {} sizes = {} exports = {} prototypes = {} nooverlap = set() with open('api') as f: for line in f: line = line.strip() if line.startswith('crypto_'): line = line.split() x = line[0].split('/') assert len(x) == 2 o = x[0].split('_')[1] if o not in operations: operations += [o] p = x[1] if o not in primitives: primitives[o] = [] primitives[o] += [p] if len(line) >= 3: checksums[o,p] = line[1],line[2] for option in line[3:]: if option == 'nooverlap': nooverlap.add((o,p)) continue if line.startswith('#define '): x = line.split(' ') x = x[1].split('_') assert len(x) == 4 assert x[0] == 'crypto' o = x[1] p = x[2] if (o,p) not in sizes: sizes[o,p] = '' sizes[o,p] += line+'\n' continue if line.endswith(');'): fun,args = line[:-2].split('(') rettype,fun = fun.split() fun = fun.split('_') o = fun[1] assert fun[0] == 'crypto' if o not in exports: exports[o] = [] exports[o] += ['_'.join(fun[1:])] if o not in prototypes: prototypes[o] = [] prototypes[o] += [(rettype,fun,args)] todo = ( ('xof',( ('h',None,'16384'), ('m',None,'16384'), ),( ('loops','64','512'), ('maxtest','128','16384'), ),( ('',('h',),(),('hlen','m','mlen')), )), ('sort',( ('x',None,'4096'), ),( ('loops','1024','4096'), ('maxtest','128','4096'), ),( ('',(),('x',),('xwords',)), )), ('kem',( ('p','crypto_kem_PUBLICKEYBYTES','crypto_kem_PUBLICKEYBYTES'), ('s','crypto_kem_SECRETKEYBYTES','crypto_kem_SECRETKEYBYTES'), ('k','crypto_kem_BYTES','crypto_kem_BYTES'), ('c','crypto_kem_CIPHERTEXTBYTES','crypto_kem_CIPHERTEXTBYTES'), ('t','crypto_kem_BYTES','crypto_kem_BYTES'), ),( ('loops','8','64'), ),( ('_keypair',('p','s'),(),()), ('_enc',('c','k'),(),('p',)), ('_dec',('t',),(),('c','s')), )), ) for t in todo: o,vars,howmuch,tests = t Z += '\n' Z += '/* ----- %s, derived from supercop/crypto_%s/try.c */\n' % (o,o) for p in primitives[o]: Z += 'static const char *%s_%s_checksums[] = {\n' % (o,p) Z += ' "%s",\n' % checksums[o,p][0] Z += ' "%s",\n' % checksums[o,p][1] Z += '} ;\n' Z += '\n' for rettype,fun,args in prototypes[o]: Z += 'static %s (*%s)(%s);\n' % (rettype,'_'.join(fun),args) if (o,p) in sizes: for line in sizes[o,p].splitlines(): psize = line.split()[1] size1 = psize.replace('crypto_%s_%s_'%(o,p),'crypto_%s_'%o) size2 = psize.replace('crypto_','mceliece_') Z += '#define %s %s\n' % (size1,size2) Z += '\n' for v,initsize,allocsize in vars: Z += 'static void *storage_%s_%s_%s;\n' % (o,p,v) Z += 'static unsigned char *test_%s_%s_%s;\n' % (o,p,v) for v,initsize,allocsize in vars: Z += 'static void *storage_%s_%s_%s2;\n' % (o,p,v) Z += 'static unsigned char *test_%s_%s_%s2;\n' % (o,p,v) Z += '\n' if (o,p) in precomputed: Z += '#define precomputed_%s_%s_NUM %d\n' % (o,p,len(precomputed[o,p])) Z += '\n' for v,initsize,allocsize in vars: Z += 'static const unsigned char precomputed_%s_%s_%s[precomputed_%s_%s_NUM][%s] = {\n' % (o,p,v,o,p,allocsize) for precomp in precomputed[o,p]: Z += ' {%s},\n' % ','.join(str(c) for c in precomp[v]) Z += '} ;\n' Z += '\n' Z += 'static void test_%s_%s_impl(long long impl)\n' % (o,p) Z += '{\n' for v,initsize,allocsize in vars: Z += ' unsigned char *%s = test_%s_%s_%s;\n' % (v,o,p,v) for v,initsize,allocsize in vars: Z += ' unsigned char *%s2 = test_%s_%s_%s2;\n' % (v,o,p,v) for v,initsize,allocsize in vars: if initsize is None: Z += ' long long %slen;\n' % v if o == 'sort': Z += ' long long %swords;\n' % v else: Z += ' long long %slen = %s;\n' % (v,initsize) Z += '\n' Z += ' if (targeti && strcmp(targeti,".") && strcmp(targeti,mceliece_dispatch_%s_%s_implementation(impl))) return;\n' % (o,p) Z += ' if (targetn && atol(targetn) != impl) return;\n' # XXX: atoll is slightly unportable Z += ' if (impl >= 0) {\n' for rettype,fun,args in prototypes[o]: f2 = ['mceliece','dispatch',o,p]+fun[2:] Z += ' %s = %s(impl);\n' % ('_'.join(fun),'_'.join(f2)) Z += ' printf("%s_%s %%lld implementation %%s compiler %%s\\n",impl,mceliece_dispatch_%s_%s_implementation(impl),mceliece_dispatch_%s_%s_compiler(impl));\n' % (o,p,o,p,o,p) Z += ' } else {\n' for rettype,fun,args in prototypes[o]: f2 = ['mceliece',o,p]+fun[2:] Z += ' %s = %s;\n' % ('_'.join(fun),'_'.join(f2)) Z += ' printf("%s_%s selected implementation %%s compiler %%s\\n",mceliece_%s_%s_implementation(),mceliece_%s_%s_compiler());\n' % (o,p,o,p,o,p) Z += ' }\n' Z += ' for (long long checksumbig = 0;checksumbig < 2;++checksumbig) {\n' maxtestdefined = False for v,small,big in howmuch: Z += ' long long %s = checksumbig ? %s : %s;\n' % (v,big,small) if v == 'maxtest': maxtestdefined = True Z += '\n' Z += ' checksum_clear();\n' Z += '\n' Z += ' for (long long loop = 0;loop < loops;++loop) {\n' wantresult = False for f,output,inout,input in tests: cof = 'crypto_'+o+f for rettype,fun,args in prototypes[o]: if cof == '_'.join(fun): if rettype != 'void': wantresult = True if wantresult: Z += ' int result;\n' if maxtestdefined and 'mlen' in input: Z += ' mlen = myrandom() % (maxtest + 1);\n' if maxtestdefined and 'hlen' in input: Z += ' hlen = myrandom() % (maxtest + 1);\n' if maxtestdefined and 'xwords' in input: Z += ' xwords = myrandom() % (maxtest + 1);\n' Z += ' xlen = mceliece_sort_%s_BYTES*xwords;\n' % p Z += '\n' initialized = set() for f,output,inout,input in tests: cof = 'crypto_'+o+f cofrettype = None for rettype,fun,args in prototypes[o]: if cof == '_'.join(fun): cofrettype = rettype expected = '0' unexpected = 'nonzero' for v in output: if len(v) == 1: Z += ' output_prepare(%s2,%s,%slen);\n' % (v,v,v) # v now has CDE where C is canary, D is canary, E is canary # v2 now has same CDE # D is at start of v with specified length # C is 16 bytes before beginning # E is 16 bytes past end for v in input+inout: if len(v) == 1: if v in initialized: Z += ' memcpy(%s2,%s,%slen);\n' % (v,v,v) Z += ' double_canary(%s2,%s,%slen);\n' % (v,v,v) else: Z += ' input_prepare(%s2,%s,%slen);\n' % (v,v,v) # v now has CTE where C is canary, T is test data, E is canary # v2 has same CTE initialized.add(v) if o == 'sort': Z += ' endianness(x,xwords,mceliece_sort_%s_BYTES);\n' % p for v in input+inout: if len(v) == 1: Z += ' secret(%s,%slen);\n' % (v,v) args = ','.join(output+inout+input) if cofrettype == 'void': Z += ' %s(%s);\n' % (cof,args) else: Z += ' result = %s(%s);\n' % (cof,args) Z += ' public(&result,sizeof result);\n' Z += ' if (result != %s) fail("failure: %s returns %s\\n");\n' % (expected,cof,unexpected) for v in input+inout+output: if len(v) == 1: Z += ' public(%s,%slen);\n' % (v,v) if o == 'sort': Z += ' endianness(x,xwords,mceliece_sort_%s_BYTES);\n' % p if cof == 'crypto_kem_dec': Z += ' if (memcmp(t,k,klen) != 0) fail("failure: %s does not match k\\n");\n' % cof for v in output+inout: if len(v) == 1: Z += ' checksum(%s,%slen);\n' % (v,v) # output v,v2 now has COE,CDE where O is output; checksum O initialized.add(v) for v in output+inout: if len(v) == 1: if cof == 'crypto_sign_open' and v == 't': Z += ' output_compare(%s2,%s,%slen,"%s");\n' % (v,v,'c',cof) else: Z += ' output_compare(%s2,%s,%slen,"%s");\n' % (v,v,v,cof) # output_compare checks COE,CDE for equal C, equal E for v in input: if len(v) == 1: Z += ' input_compare(%s2,%s,%slen,"%s");\n' % (v,v,v,cof) # input_compare checks CTE,CTE for equal C, equal T, equal E deterministic = True if inout+input == (): deterministic = False if cof == 'crypto_kem_enc': deterministic = False if deterministic: Z += '\n' for v in output+inout+input: if len(v) == 1: Z += ' double_canary(%s2,%s,%slen);\n' % (v,v,v) # old output v,v2: COE,CDE; new v,v2: FOG,FDG where F,G are new canaries # old inout v,v2: COE,CTE; new v,v2: FOG,FTG # old input v,v2: CTE,CTE; new v,v2: FTG,FTG if o == 'sort': Z += ' endianness(x2,xwords,mceliece_sort_%s_BYTES);\n' % p for v in input+inout: if len(v) == 1: Z += ' secret(%s2,%slen);\n' % (v,v) args = ','.join([v if v.endswith('words') or v.endswith('len') else v+'2' for v in output+inout+input]) if cofrettype == 'void': Z += ' %s(%s);\n' % (cof,args) else: Z += ' result = %s(%s);\n' % (cof,args) Z += ' public(&result,sizeof result);\n' Z += ' if (result != %s) fail("failure: %s returns %s\\n");\n' % (expected,cof,unexpected) for v in input+inout+output: if len(v) == 1: Z += ' public(%s2,%slen);\n' % (v,v) if o == 'sort': Z += ' endianness(x2,xwords,mceliece_sort_%s_BYTES);\n' % p for w in output + inout: if len(w) == 1: # w,w2: COE,COE; goal now is to compare O Z += ' if (memcmp(%s2,%s,%slen) != 0) fail("failure: %s is nondeterministic\\n");\n' % (w,w,w,cof) overlap = deterministic if inout != (): overlap = False if (o,p) in nooverlap: overlap = False # XXX: overlap test assumes that inputs are at least as big as outputs if overlap: for y in output: if len(y) == 1: Z += '\n' for v in output: if len(v) == 1: Z += ' double_canary(%s2,%s,%slen);\n' % (v,v,v) for v in input: if len(v) == 1: Z += ' double_canary(%s2,%s,%slen);\n' % (v,v,v) for x in input: if len(x) == 1: # try writing to x2 instead of y, while reading x2 args = ','.join([x+'2' if v==y else v for v in output] + [x+'2' if v==x else v for v in input]) for v in input+inout: v2 = x+'2' if v==x else v if len(v) == 1: Z += ' secret(%s,%slen);\n' % (v2,v) if cofrettype == 'void': Z += ' %s(%s);\n' % (cof,args) else: Z += ' result = %s(%s);\n' % (cof,args) Z += ' public(&result,sizeof result);\n' Z += ' if (result != %s) fail("failure: %s with %s=%s overlap returns %s\\n");\n' % (expected,cof,x,y,unexpected) for v in output: v2 = x+'2' if v==y else v if len(v) == 1: Z += ' public(%s,%slen);\n' % (v2,v) for v in input: if v == x: continue if len(v) == 1: Z += ' public(%s,%slen);\n' % (v,v) Z += ' if (memcmp(%s2,%s,%slen) != 0) fail("failure: %s does not handle %s=%s overlap\\n");\n' % (x,y,y,cof,x,y) Z += ' memcpy(%s2,%s,%slen);\n' % (x,x,x) if cof == 'crypto_kem_dec': Z += '\n' for tweaks in range(3): Z += ' c[myrandom() % clen] += 1 + (myrandom() % 255);\n' Z += ' if (%s(t,c,s) == 0)\n' % cof Z += ' checksum(t,tlen);\n' Z += ' else\n' Z += ' checksum(c,clen);\n' Z += ' }\n' Z += ' checksum_expected(%s_%s_checksums[checksumbig]);\n' % (o,p) Z += ' }\n' # ----- test vectors computed by python for f,output,inout,input in tests: cof = 'crypto_'+o+f if (o,p) in precomputed: Z += ' for (long long precomp = 0;precomp < precomputed_%s_%s_NUM;++precomp) {\n' % (o,p) for v,initsize,allocsize in vars: if v in output: Z += ' output_prepare(%s2,%s,%s);\n' % (v,v,allocsize) if v in input+inout: Z += ' input_prepare(%s2,%s,%s);\n' % (v,v,allocsize) Z += ' memcpy(%s,precomputed_%s_%s_%s[precomp],%s);\n' % (v,o,p,v,allocsize) Z += ' memcpy(%s2,precomputed_%s_%s_%s[precomp],%s);\n' % (v,o,p,v,allocsize) args = ','.join(output+inout+input) Z += ' %s(%s);\n' % (cof,args) for v,initsize,allocsize in vars: if v in output+inout: Z += ' if (memcmp(%s,precomputed_%s_%s_%s[precomp],%s)) {\n' % (v,o,p,v,allocsize) Z += ' fail("failure: %s fails precomputed test vectors\\n");\n' % cof Z += ' printf("expected %s: ");\n' % v Z += ' for (long long pos = 0;pos < %s;++pos) printf("%%02x",precomputed_%s_%s_%s[precomp][pos]);\n' % (allocsize,o,p,v) Z += ' printf("\\n");\n' Z += ' printf("received %s: ");\n' % v Z += ' for (long long pos = 0;pos < %s;++pos) printf("%%02x",%s[pos]);\n' % (allocsize,v) Z += ' printf("\\n");\n' Z += ' }\n' for v,initsize,allocsize in vars: if v in output+inout: Z += ' output_compare(%s2,%s,%s,"%s");\n' % (v,v,allocsize,cof) if v in input: Z += ' input_compare(%s2,%s,%s,"%s");\n' % (v,v,allocsize,cof) Z += ' }\n' Z += '}\n' Z += '\n' Z += 'static void test_%s_%s(void)\n' % (o,p) Z += '{\n' Z += ' if (targeto && strcmp(targeto,"%s")) return;\n' % o Z += ' if (targetp && strcmp(targetp,"%s")) return;\n' % p if cof == 'crypto_sort': for v,initsize,allocsize in vars: Z += ' storage_%s_%s_%s = callocplus(mceliece_sort_%s_BYTES*%s);\n' % (o,p,v,p,allocsize) Z += ' test_%s_%s_%s = aligned(storage_%s_%s_%s,mceliece_sort_%s_BYTES*%s);\n' % (o,p,v,o,p,v,p,allocsize) for v,initsize,allocsize in vars: Z += ' storage_%s_%s_%s2 = callocplus(mceliece_sort_%s_BYTES*%s);\n' % (o,p,v,p,allocsize) Z += ' test_%s_%s_%s2 = aligned(storage_%s_%s_%s2,mceliece_sort_%s_BYTES*%s);\n' % (o,p,v,o,p,v,p,allocsize) else: for v,initsize,allocsize in vars: Z += ' storage_%s_%s_%s = callocplus(%s);\n' % (o,p,v,allocsize) Z += ' test_%s_%s_%s = aligned(storage_%s_%s_%s,%s);\n' % (o,p,v,o,p,v,allocsize) for v,initsize,allocsize in vars: Z += ' storage_%s_%s_%s2 = callocplus(%s);\n' % (o,p,v,allocsize) Z += ' test_%s_%s_%s2 = aligned(storage_%s_%s_%s2,%s);\n' % (o,p,v,o,p,v,allocsize) Z += '\n' if o == 'sort': # requires alignment Z += ' for (long long offset = 0;offset < 1;++offset) {\n' else: Z += ' for (long long offset = 0;offset < 2;++offset) {\n' Z += ' if (targetoffset && atol(targetoffset) != offset) continue;\n' Z += ' if (offset && valgrind) break;\n' Z += ' printf("%s_%s offset %%lld\\n",offset);\n' % (o,p) Z += ' for (long long impl = -1;impl < mceliece_numimpl_%s_%s();++impl)\n' % (o,p) Z += ' forked(test_%s_%s_impl,impl);\n' % (o,p) for v,initsize,allocsize in vars: Z += ' ++test_%s_%s_%s;\n' % (o,p,v) for v,initsize,allocsize in vars: Z += ' ++test_%s_%s_%s2;\n' % (o,p,v) Z += ' }\n' for v,initsize,allocsize in reversed(vars): Z += ' free(storage_%s_%s_%s2);\n' % (o,p,v) for v,initsize,allocsize in reversed(vars): Z += ' free(storage_%s_%s_%s);\n' % (o,p,v) Z += '}\n' if (o,p) in sizes: for line in sizes[o,p].splitlines(): psize = line.split()[1] size1 = psize.replace('crypto_%s_%s_'%(o,p),'crypto_%s_'%o) Z += '#undef %s\n' % size1 Z += '\n' Z += r'''/* ----- top level */ #include "print_cpuid.inc" int main(int argc,char **argv) { valgrind_init(); if (valgrind) limits(); setvbuf(stdout,0,_IOLBF,0); printf("mceliece version %s\n",mceliece_version); printf("mceliece arch %s\n",mceliece_arch); print_cpuid(); if (valgrind) { printf("valgrind %d",(int) valgrind); printf(" declassify %d",(int) crypto_declassify_uses_valgrind); if (!crypto_declassify_uses_valgrind) printf(" (expect false positives)"); printf("\n"); } if (*argv) ++argv; if (*argv) { targeto = *argv++; if (*argv) { targetp = *argv++; if (*argv) { targeti = *argv++; if (*argv) { targetn = *argv++; if (*argv) { targetoffset = *argv++; } } } } } ''' for t in todo: o,vars,howmuch,tests = t for p in primitives[o]: Z += ' test_%s_%s();\n' % (o,p) Z += r''' if (!ok) { printf("some tests failed\n"); return 100; } printf("all tests succeeded\n"); return 0; } ''' with open('command/mceliece-test.c','w') as f: f.write(Z)