#include #include #include #include /* C11 specifies DBL_TRUE_MIN, might not be immediately available. */ #ifndef DBL_TRUE_MIN #define DBL_TRUE_MIN 4.9406564584124654E-324 #endif #include static char reconstructed[2][512]; static int reconstr_lens[2]; static int callback(const void *buffer, size_t size, void *app_key) { char *buf = reconstructed[app_key ? 1 : 0]; int *len = &reconstr_lens[app_key ? 1 : 0]; if(*len + size >= sizeof(reconstructed[0])) return -1; memcpy(buf + *len, buffer, size); *len += size; return 0; } static char * d2s(double d, int canonical) { ssize_t s; reconstr_lens[canonical] = 0; s = REAL__dump(d, canonical, callback, (void *)(ptrdiff_t)canonical); assert(s > 0 && (size_t)s < sizeof(reconstructed[canonical])); assert(s == reconstr_lens[canonical]); reconstructed[canonical][s] = '\0'; // ASCIIZ return reconstructed[canonical]; } /* * Verify that a string representation of a given floating point value * is as given in the (sample) and (canonical_sample) arguments. */ static void check_str_representation(double d, const char *sample, const char *canonical_sample, int lineno) { char *s0, *s1; s0 = d2s(d, 0); s1 = d2s(d, 1); if(sample) { printf("%03d: Checking %g->[\"%s\"] against [\"%s\"]%s\n", lineno, d, s0, sample, canonical_sample ? " (canonical follows...)" : "" ); assert(!strcmp(s0, sample)); } if(canonical_sample) { printf("%03d: Checking %g->[\"%s\"] against [\"%s\"] (canonical)\n", lineno, d, s1, canonical_sample); assert(!strcmp(s1, canonical_sample)); } } #define check(rn, d, str1, str2) \ check_impl(rn, d, str1, str2, __LINE__) static void check_impl(REAL_t *rn, double orig_dbl, const char *sample, const char *canonical_sample, int lineno) { double val; uint8_t *p, *end; int ret; printf("Line %d: double value %.12f [", lineno, orig_dbl); for(p = (uint8_t *)&orig_dbl, end = p + sizeof(double); p < end ; p++) printf("%02x", *p); printf("] (ilogb %d)\n", ilogb(orig_dbl)); val = frexp(orig_dbl, &ret); printf("frexp(%f, %d): [", val, ret); for(p = (uint8_t *)&val, end = p + sizeof(double); p < end ; p++) printf("%02x", *p); printf("]\n"); ret = asn_double2REAL(rn, orig_dbl); assert(ret == 0); printf("converted into ["); for(p = rn->buf, end = p + rn->size; p < end; p++) printf("%02x", *p); printf("]: %d\n", rn->size); ret = asn_REAL2double(rn, &val); assert(ret == 0); printf("and back to double: ["); for(p = (uint8_t *)&val, end = p + sizeof(double); p < end ; p++) printf("%02x", *p); printf("] (ilogb %d)\n", ilogb(val)); printf("%.12f vs %.12f\n", val, orig_dbl); assert((isnan(orig_dbl) && isnan(val)) || val == orig_dbl); printf("OK\n"); check_str_representation(val, sample, canonical_sample, lineno); } static void check_xer(int fuzzy, double orig_value) { asn_enc_rval_t er; asn_dec_rval_t rc; REAL_t st; REAL_t *newst0 = 0; REAL_t *newst1 = 0; REAL_t **newst0p = &newst0; REAL_t **newst1p = &newst1; double value0, value1; int ret; memset(&st, 0, sizeof(st)); ret = asn_double2REAL(&st, orig_value); assert(ret == 0); reconstr_lens[0] = 0; reconstr_lens[1] = 0; er = xer_encode(&asn_DEF_REAL, &st, XER_F_BASIC, callback, 0); assert(er.encoded == reconstr_lens[0]); er = xer_encode(&asn_DEF_REAL, &st, XER_F_CANONICAL, callback, (void *)1); assert(er.encoded == reconstr_lens[1]); reconstructed[0][reconstr_lens[0]] = 0; reconstructed[1][reconstr_lens[1]] = 0; printf("%f vs (%d)[%s] & (%d)%s", orig_value, reconstr_lens[1], reconstructed[1], reconstr_lens[0], reconstructed[0] ); rc = xer_decode(0, &asn_DEF_REAL, (void **)newst0p, reconstructed[0], reconstr_lens[0]); assert(rc.code == RC_OK); assert(reconstr_lens[0] > 0 && rc.consumed < (size_t)reconstr_lens[0]); rc = xer_decode(0, &asn_DEF_REAL, (void **)newst1p, reconstructed[1], reconstr_lens[1]); assert(rc.code == RC_OK); assert(rc.consumed == (size_t)reconstr_lens[1]); ret = asn_REAL2double(newst0, &value0); assert(ret == 0); ret = asn_REAL2double(newst1, &value1); assert(ret == 0); assert((isnan(value0) && isnan(orig_value)) || value0 == orig_value || fuzzy); assert((isnan(value1) && isnan(orig_value)) || value1 == orig_value); assert(newst0->size == st.size || fuzzy); assert(newst1->size == st.size); assert(fuzzy || memcmp(newst0->buf, st.buf, st.size) == 0); assert(memcmp(newst1->buf, st.buf, st.size) == 0); } static void check_ber_buffer_twoway(double d, const char *sample, const char *canonical_sample, uint8_t *inbuf, size_t insize, uint8_t *outbuf, size_t outsize, int lineno) { REAL_t rn; double val; int ret; /* * Decode our expected buffer and check that it matches the given (d). */ rn.buf = inbuf; rn.size = insize; asn_REAL2double(&rn, &val); if(isnan(val)) assert(isnan(d)); if(isnan(d)) assert(isnan(val)); if(!isnan(val) && !isnan(d)) { assert(copysign(1.0, d) == copysign(1.0, val)); assert(d == val); } /* * Encode value and check that it matches our expected buffer. */ memset(&rn, 0, sizeof(rn)); ret = asn_double2REAL(&rn, d); assert(ret == 0); if((size_t)rn.size != outsize) { printf("Encoded %f into %d expected %ld\n", d, (int)rn.size, outsize); assert((size_t)rn.size == outsize); } assert(memcmp(rn.buf, outbuf, rn.size) == 0); check_str_representation(d, sample, canonical_sample, lineno); } static void check_ber_buffer_oneway(double d, const char *sample, const char *canonical_sample, uint8_t *buf, size_t bufsize, int lineno) { REAL_t rn; double val; uint8_t *p, *end; int ret; memset(&rn, 0, sizeof(rn)); printf("verify double value %.12f [", d); for(p = (uint8_t *)&d, end = p + sizeof(double); p < end ; p++) printf("%02x", *p); printf("] (ilogb %d)\n", ilogb(d)); ret = asn_double2REAL(&rn, d); assert(ret == 0); printf("canonical DER: ["); for(p = rn.buf, end = p + rn.size; p < end; p++) printf("%02x", *p); printf("]\n"); rn.buf = buf; rn.size = bufsize; printf("received as: ["); for(p = rn.buf, end = p + rn.size; p < end; p++) printf("%02x", *p); printf("]\n"); ret = asn_REAL2double(&rn, &val); assert(ret == 0); printf("%.12f vs %.12f\n", d, val); assert(val == d); check_str_representation(val, sample, canonical_sample, lineno); } /* * 8.5.7 Verify binary encoding, two-way. */ static void check_ber_857_encoding(int base, int sign, int scaling_factor, int exponent, int mantissa) { uint8_t buf[100]; uint8_t *b = buf; int explen, mantlen; REAL_t rn; static REAL_t rn_check; double d; double verify; int baseF = 0; int ret; #define BIT(b) (1<<(b - 1)) switch(base) { case 0: baseF = 1; break; case 1: baseF = 3; break; case 2: baseF = 4; break; default: assert(base >= 0 && base <= 2); } if(exponent >= -128 && exponent <= 127) { explen = 1; } else { assert(exponent > -60000 && exponent < 60000); explen = 2; } if(mantissa == 0) { mantlen = 0; } else if(mantissa >= 0 && mantissa <= 255) { mantlen = 1; } else if(mantissa >= 0 && mantissa <= 65535) { mantlen = 2; } else { assert(mantissa >= 0 && mantissa <= 256 * 65536); mantlen = 3; } *b = BIT(8) | (sign ? BIT(7) : 0); *b |= (base & 0x03) << 4; /* 8.5.7.2 */ *b |= (scaling_factor & 0x03) << 2; /* 8.5.7.3 */ *b |= ((explen - 1) & 0x03); /* 8.5.7.4 */ b++; switch(explen) { case 2: *b++ = (int8_t)(exponent >> 8); case 1: *b++ = (int8_t)exponent; } switch(mantlen) { case 3: *b++ = (mantissa >> 16) & 0xff; case 2: *b++ = (mantissa >> 8) & 0xff; case 1: *b++ = (mantissa & 0xff); } verify = (sign ? -1.0 : 1.0) * ldexp(mantissa, exponent * baseF + scaling_factor); /* Verify than encoding of this double value round-trips */ if(!isinf(verify)) { d = verify; verify = 0.0; ret = asn_double2REAL(&rn_check, d); assert(ret == 0); ret = asn_REAL2double(&rn_check, &verify); assert(ret == 0); assert(d == verify); /* Verify with a slight non-friendly offset. Not too easy. */ d = verify - 0.13; verify = 0.0; ret = asn_double2REAL(&rn_check, d); assert(ret == 0); ret = asn_REAL2double(&rn_check, &verify); assert(ret == 0); assert(ret == 0); assert(d == verify); } verify = (sign ? -1.0 : 1.0) * ldexp(mantissa, exponent * baseF + scaling_factor); rn.buf = buf; rn.size = b - buf; ret = asn_REAL2double(&rn, &d); if(!isinf(verify) && (ret != 0 || d != verify)) { printf("Converting B=%d, S=%d, F=%d, E=%d/%d, M=%d/%d\n", (1 << baseF), sign, scaling_factor, exponent, explen, mantissa, mantlen); printf("Verify: %e\n", verify); uint8_t *p; printf("received as: ["); for(p = buf; p < b; p++) printf("%02x", *p); printf("]\n"); assert(ret == 0); printf("Converted: %e\n", d); assert(d == verify); } } static void check_ber_encoding() { static const double zero = 0.0; #define CHECK_BER_STRICT(v, nocan, can, inbuf, outbuf) \ check_ber_buffer_twoway(v, nocan, can, inbuf, sizeof(inbuf), \ outbuf, sizeof(outbuf), __LINE__) #define CHECK_BER_NONSTRICT(v, nocan, can, buf) \ check_ber_buffer_oneway(v, nocan, can, buf, sizeof(buf), __LINE__) /* * X.690 8.4 Encoding of an enumerated value. */ /* 8.5.2 If the real value is the value plus zero, * there shall be no contents octet in the encoding */ { uint8_t b_0[] = {}; CHECK_BER_STRICT(0.0, "0", "0", b_0, b_0); } /* 8.5.3 When -0 is to be encoded, there shall be only one contents octet */ { uint8_t b_m0[] = { 0x43 }; CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0, b_m0); } /* Old way of encoding -0.0: 8.5.6 a) */ { uint8_t b_m0[] = { 0x43 }; uint8_t b_m0_856a[] = { 0xC0, 0x00 }; /* #8.5.6 a) */ uint8_t b_m0_856a_1[] = { 0xC0, 0x00, 0x00 }; uint8_t b_m0_856a_2[] = { 0xC0, 0x00, 0x00, 0x00 }; uint8_t b_m0_856a_3[] = { 0xC0, 0x00, 0x00, 0x00, 0x00 }; CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_856a, b_m0); CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_856a_1, b_m0); CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_856a_2, b_m0); CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_856a_3, b_m0); } /* 8.5.6 c) => 8.5.9 SpecialRealValue */ { uint8_t b_pinf[] = { 0x40 }; uint8_t b_minf[] = { 0x41 }; uint8_t b_nan[] = { 0x42 }; CHECK_BER_STRICT(1.0/zero, "", "", b_pinf, b_pinf); CHECK_BER_STRICT(-1.0/zero, "", "", b_minf, b_minf); CHECK_BER_STRICT(zero/zero, "", "", b_nan, b_nan); } /* 8.5.6 b) => 8.5.8 Decimal encoding is used; NR1 form */ { uint8_t b_0_nr1[] = { 0x01, '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_0_nr1, b_0); } { uint8_t b_0_nr1[] = { 0x01, '0', '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_0_nr1, b_0); } { uint8_t b_0_nr1[] = { 0x01, ' ', '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_0_nr1, b_0); } { uint8_t b_p0_nr1[] = { 0x01, '+', '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_p0_nr1, b_0); } { uint8_t b_p0_nr1[] = { 0x01, ' ', '+', '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_p0_nr1, b_0); } { uint8_t b_m0_nr1[] = { 0x01, '-', '0' }; uint8_t b_m0[] = { 0x43 }; CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_nr1, b_m0); } { uint8_t b_m0_nr1[] = { 0x01, ' ', '-', '0' }; uint8_t b_m0[] = { 0x43 }; CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_nr1, b_m0); } { uint8_t b_1_nr1[] = { 0x01, '1' }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_1_nr1, b_1); } { uint8_t b_1_nr1[] = { 0x01, '0', '1' }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_1_nr1, b_1); } { uint8_t b_1_nr1[] = { 0x01, ' ', '1' }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_1_nr1, b_1); } { uint8_t b_p1_nr1[] = { 0x01, '+', '1' }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_p1_nr1, b_1); } { uint8_t b_p1_nr1[] = { 0x01, ' ', '+', '1' }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_p1_nr1, b_1); } { uint8_t b_m1_nr1[] = { 0x01, '-', '1' }; uint8_t b_m1[] = { 0xC0, 0x00, 0x01 }; CHECK_BER_STRICT(-1.0, "-1.0", "-1.0E0", b_m1_nr1, b_m1); } { uint8_t b_m1_nr1[] = { 0x01, ' ', '-', '1' }; uint8_t b_m1[] = { 0xC0, 0x00, 0x01 }; CHECK_BER_STRICT(-1.0, "-1.0", "-1.0E0", b_m1_nr1, b_m1); } { uint8_t comma_symbol[] = { '.', ',' }; int csi; for(csi = 0; csi < 2; csi++) { uint8_t CS = comma_symbol[csi]; /* 8.5.6 b) => 8.5.8 Decimal encoding is used; NR2 form */ { uint8_t b_0_nr2[] = { 0x02, '0', CS, '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_0_nr2, b_0); } { uint8_t b_0_nr2[] = { 0x02, '0', '0', CS, '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_0_nr2, b_0); } { uint8_t b_0_nr2[] = { 0x02, ' ', '0', CS, '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_0_nr2, b_0); } { uint8_t b_p0_nr2[] = { 0x02, '+', '0', CS, '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_p0_nr2, b_0); } { uint8_t b_p0_nr2[] = { 0x02, ' ', '+', '0', CS, '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_p0_nr2, b_0); } { uint8_t b_m0_nr2[] = { 0x02, '-', '0', CS, '0' }; uint8_t b_m0[] = { 0x43 }; CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_nr2, b_m0); } { uint8_t b_m0_nr2[] = { 0x02, ' ', '-', '0', CS, '0' }; uint8_t b_m0[] = { 0x43 }; CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_nr2, b_m0); } /* 8.5.6 b) => 8.5.8 NR2 "1." */ { uint8_t b_1_nr2[] = { 0x02, '1', CS }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_1_nr2, b_1); } { uint8_t b_1_nr2[] = { 0x02, '0', '1', CS }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_1_nr2, b_1); } { uint8_t b_1_nr2[] = { 0x02, ' ', '1', CS }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_1_nr2, b_1); } { uint8_t b_p1_nr2[] = { 0x02, '+', '1', CS }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_p1_nr2, b_1); } { uint8_t b_p1_nr2[] = { 0x02, ' ', '+', '1', CS }; uint8_t b_1[] = { 0x80, 0x00, 0x01 }; CHECK_BER_STRICT(1.0, "1.0", "1.0E0", b_p1_nr2, b_1); } { uint8_t b_m1_nr2[] = { 0x02, '-', '1', CS }; uint8_t b_m1[] = { 0xC0, 0x00, 0x01 }; CHECK_BER_STRICT(-1.0, "-1.0", "-1.0E0", b_m1_nr2, b_m1); } { uint8_t b_m1_nr2[] = { 0x02, ' ', '-', '1', CS }; uint8_t b_m1[] = { 0xC0, 0x00, 0x01 }; CHECK_BER_STRICT(-1.0, "-1.0", "-1.0E0", b_m1_nr2, b_m1); } /* 8.5.6 b) => 8.5.8 NR2 ".5" */ { uint8_t b_05_nr2[] = { 0x02, CS, '5' }; uint8_t b_05[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_05_nr2, b_05); } { uint8_t b_05_nr2[] = { 0x02, '0', CS, '5' }; uint8_t b_05[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_05_nr2, b_05); } { uint8_t b_05_nr2[] = { 0x02, ' ', CS, '5' }; uint8_t b_05[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_05_nr2, b_05); } { uint8_t b_p1_nr2[] = { 0x02, '+', CS, '5' }; uint8_t b_05[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_p1_nr2, b_05); } { uint8_t b_p1_nr2[] = { 0x02, ' ', '+', CS, '5' }; uint8_t b_05[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_p1_nr2, b_05); } { uint8_t b_m05_nr2[] = { 0x02, '-', CS, '5' }; uint8_t b_m05[] = { 0xC0, 0xff, 0x01 }; CHECK_BER_STRICT(-0.5, "-0.5", "-5.0E-1", b_m05_nr2, b_m05); } { uint8_t b_m05_nr2[] = { 0x02, ' ', '-', CS, '5' }; uint8_t b_m05[] = { 0xC0, 0xff, 0x01 }; CHECK_BER_STRICT(-0.5, "-0.5", "-5.0E-1", b_m05_nr2, b_m05); } /* 8.5.6 b) => 8.5.8 Decimal encoding is used; NR3 form */ { uint8_t b_0_nr3[] = { 0x03, '0', CS, '0', 'e', '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_0_nr3, b_0); } { uint8_t b_0_nr3[] = { 0x03, '0', '0', CS, '0', 'E', '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_0_nr3, b_0); } { uint8_t b_0_nr3[] = { 0x03, ' ', '0', CS, '0', 'e', '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_0_nr3, b_0); } { uint8_t b_p0_nr3[] = { 0x03, '+', '0', CS, '0', 'E', '+', '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_p0_nr3, b_0); } { uint8_t b_p0_nr3[] = { 0x03, ' ', '+', '0', CS, '0', 'e', '+', '0' }; uint8_t b_0[] = { }; CHECK_BER_STRICT(0.0, "0", "0", b_p0_nr3, b_0); } { uint8_t b_m0_nr3[] = { 0x03, '-', '0', CS, '0', 'E', '-', '0' }; uint8_t b_m0[] = { 0x43 }; CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_nr3, b_m0); } { uint8_t b_m0_nr3[] = { 0x03, ' ', '-', '0', CS, '0', 'e', '-', '0' }; uint8_t b_m0[] = { 0x43 }; CHECK_BER_STRICT(-0.0, "-0", "-0", b_m0_nr3, b_m0); } /* 8.5.6 b) => 8.5.8 NR3 "5.e-1" */ { uint8_t b_5_nr3[] = { 0x03, '5', CS, 'e', '-', '1' }; uint8_t b_5[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_5_nr3, b_5); } { uint8_t b_5_nr3[] = { 0x03, '0', '5', CS, 'E', '-', '1' }; uint8_t b_5[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_5_nr3, b_5); } { uint8_t b_5_nr3[] = { 0x03, ' ', '5', CS, 'e', '-', '1' }; uint8_t b_5[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_5_nr3, b_5); } { uint8_t b_p5_nr3[] = { 0x03, '+', '5', CS, 'E', '-', '1' }; uint8_t b_5[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_p5_nr3, b_5); } { uint8_t b_p5_nr3[] = { 0x03, ' ', '+', '5', CS, 'e', '-', '1' }; uint8_t b_5[] = { 0x80, 0xff, 0x01 }; CHECK_BER_STRICT(0.5, "0.5", "5.0E-1", b_p5_nr3, b_5); } { uint8_t b_m5_nr3[] = { 0x03, '-', '5', CS, 'E', '-', '1' }; uint8_t b_m5[] = { 0xC0, 0xff, 0x01 }; CHECK_BER_STRICT(-0.5, "-0.5", "-5.0E-1", b_m5_nr3, b_m5); } { uint8_t b_m5_nr3[] = { 0x03, ' ', '-', '5', CS, 'e', '-', '1' }; uint8_t b_m5[] = { 0xC0, 0xff, 0x01 }; CHECK_BER_STRICT(-0.5, "-0.5", "-5.0E-1", b_m5_nr3, b_m5); } /* 8.5.6 b) => 8.5.8 NR3 ".5e1" */ { uint8_t b_05_nr3[] = { 0x03, CS, '5', 'e', '+', '1' }; uint8_t b_05[] = { 0x80, 0x00, 0x05 }; CHECK_BER_STRICT(5.0, "5.0", "5.0E0", b_05_nr3, b_05); } { uint8_t b_05_nr3[] = { 0x03, '0', CS, '5', 'E', '+', '1'}; uint8_t b_05[] = { 0x80, 0x00, 0x05 }; CHECK_BER_STRICT(5.0, "5.0", "5.0E0", b_05_nr3, b_05); } { uint8_t b_05_nr3[] = { 0x03, ' ', CS, '5', 'e', '1'}; uint8_t b_05[] = { 0x80, 0x00, 0x05 }; CHECK_BER_STRICT(5.0, "5.0", "5.0E0", b_05_nr3, b_05); } { uint8_t b_p1_nr3[] = { 0x03, '+', CS, '5', 'E', '1' }; uint8_t b_05[] = { 0x80, 0x00, 0x05 }; CHECK_BER_STRICT(5.0, "5.0", "5.0E0", b_p1_nr3, b_05); } { uint8_t b_p1_nr3[] = { 0x03, ' ', '+', CS, '5', 'e', '+', '1' }; uint8_t b_05[] = { 0x80, 0x00, 0x05 }; CHECK_BER_STRICT(5.0, "5.0", "5.0E0", b_p1_nr3, b_05); } { uint8_t b_m05_nr3[] = { 0x03, '-', CS, '5', 'E', '+', '1' }; uint8_t b_m05[] = { 0xC0, 0x00, 0x05 }; CHECK_BER_STRICT(-5.0, "-5.0", "-5.0E0", b_m05_nr3, b_m05); } { uint8_t b_m05_nr3[] = { 0x03, ' ', '-', CS, '5', 'e', '1' }; uint8_t b_m05[] = { 0xC0, 0x00, 0x05 }; CHECK_BER_STRICT(-5.0, "-5.0", "-5.0E0", b_m05_nr3, b_m05); } } /* for(comma symbol) */ } /* Scan through the range of bits, construct the valid base-2 numbers, and * try two-way conversion with them */ { int base, sign, scaling_factor, exponent, mantissa; for(base = 0; base <= 2; base++) { for(sign = 0; sign <= 1; sign++) { for(scaling_factor = 0; scaling_factor <= 3; scaling_factor++) { for(exponent = -1000; exponent < 1000; exponent += (exponent > -990 && exponent < 990) ? 100 : 1) { for(mantissa = 0; mantissa < 66000; mantissa += (mantissa > 300 && mantissa < 65400) ? 100 : 1) { check_ber_857_encoding(base, sign, scaling_factor, exponent, mantissa); } } } } } } { uint8_t b_1_0[] = { 0x80, 0xcc, 0x10, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; uint8_t b_1_1[] = { 0x80, 0xcc, 0x11, 0x99, 0x99, 0x99, 0x99, 0x99, 0x9a }; uint8_t b_3_14[] = { 0x80, 0xcd, 0x19, 0x1e, 0xb8, 0x51, 0xeb, 0x85, 0x1f }; uint8_t b_3_14_mo1[] = { 0xC0, 0xc5, 0x19, 0x1e, 0xb8, 0x51, 0xeb, 0x85, 0x1f,3}; uint8_t b_3_14_mo2[] = { 0x80, 0xbd, 0x19, 0x1e, 0xb8, 0x51, 0xeb, 0x85, 0x1f,3,2}; CHECK_BER_NONSTRICT(1.0, "1.0", "1.0E0", b_1_0); CHECK_BER_NONSTRICT(1.1, "1.1", "1.1E0", b_1_1); CHECK_BER_NONSTRICT(3.14, "3.14", "3.14E0", b_3_14); /* These two are very interesting! They check mantissa overflow! */ CHECK_BER_NONSTRICT(-3.14, "-3.14", "-3.14E0", b_3_14_mo1); CHECK_BER_NONSTRICT(3.14, "3.14", "3.14E0", b_3_14_mo2); } } int main() { REAL_t rn; static const double zero = 0.0; memset(&rn, 0, sizeof(rn)); check_ber_encoding(); check(&rn, 0.0, "0", "0"); check(&rn, -0.0, "-0", "-0"); /* minus-zero */ check(&rn, zero/zero, "", ""); check(&rn, 1.0/zero, "", ""); check(&rn, -1.0/zero, "", ""); check(&rn, 1.0, "1.0", "1.0E0"); check(&rn, -1.0, "-1.0", "-1.0E0"); check(&rn, 0.1, "0.1", "1.0E-1"); check(&rn, 0.01, "0.01", "1.0E-2"); check(&rn, 0.02, "0.02", "2.0E-2"); check(&rn, 0.09, "0.09", "9.0E-2"); check(&rn, 1.5, "1.5", "1.5E0"); check(&rn, 0.33333, "0.33333", "3.3333E-1"); check(&rn, 2, "2.0", "2.0E0"); check(&rn, 2.1, "2.1", "2.1E0"); check(&rn, 3, "3.0", "3.0E0"); check(&rn, 3.1, "3.1", "3.1E0"); check(&rn, 3.14, "3.14", "3.14E0"); check(&rn, 3.1415, "3.1415", "3.1415E0"); check(&rn, 3.141592, "3.141592", "3.141592E0"); check(&rn, 3.14159265, "3.14159265", "3.14159265E0"); check(&rn, -3.14159265, "-3.14159265", "-3.14159265E0"); check(&rn, 14159265.0, "14159265.0", "1.4159265E7"); check(&rn, -123456789123456789.0, "-123456789123456784.0", "-1.234567891234568E17"); check(&rn, 0.00000000001, "0.00000000001", "9.999999999999999E-12"); check(&rn, 0.00000000002, "0.00000000002", "2.0E-11"); check(&rn, 0.00000000009, "0.00000000009", "9.0E-11"); check(&rn, 0.000000000002, "0.000000000002", "2.0E-12"); check(&rn, 0.0000000000002, "0.0000000000002", "2.0E-13"); check(&rn, 0.00000000000002, "0.00000000000002", "2.0E-14"); check(&rn, 0.000000000000002, "0.000000000000002", "2.0E-15"); check(&rn, 0.0000000000000002, "0.0", "2.0E-16"); check(&rn, 0.0000000000000000000001, "0.0", "1.0E-22"); check(&rn, 0.000000000000000000000000000001, "0.0", "1.0E-30"); /* proved 2B a problem */ check(&rn,-0.000000000000000000000000000001, "-0.0", "-1.0E-30"); /* proved 2B a problem */ check(&rn, 0.0000000000010000000001000000000001, 0, 0); check(&rn, 0.00000000000000000000000000000000000000000000000000000000000000000000000000000000000000000001, 0, 0); check(&rn, 0.000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000001, 0, 0); check(&rn,-0.000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000001, 0, 0); check(&rn,-3.33333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333, 0, 0); check(&rn, 0.0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000033333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333, 0, 0); check(&rn, 0.25, "0.25", "2.5E-1"); check(&rn, -0.25, "-0.25", "-2.5E-1"); check(&rn, 0.03, "0.03", "3.0E-2"); check(&rn, -0.03, "-0.03", "-3.0E-2"); check(&rn, 4.01E-50, "0.0", "4.01E-50"); check(&rn, -4.01E-50, "-0.0", "-4.01E-50"); check(&rn, -4.9406564584124654E-324, "-0.0", "-4.940656458412465E-324"); /* MIN */ check(&rn, DBL_MIN, "0.0", "2.225073858507201E-308"); /* MIN */ check(&rn, -DBL_MIN, "-0.0", "-2.225073858507201E-308"); /* -MIN */ check(&rn, DBL_MAX, "179769313486231570814527423731704356798070567525844996598917476803157260780028538760589558632766878171540458953514382464234321326889464182768467546703537516986049910576551282076245490090389328944075868508455133942304583236903222948165808559332123348274797826204144723168738177180919299881250404026184124858368.0", "1.797693134862316E308"); /* MAX */ check(&rn, -DBL_MAX, "-179769313486231570814527423731704356798070567525844996598917476803157260780028538760589558632766878171540458953514382464234321326889464182768467546703537516986049910576551282076245490090389328944075868508455133942304583236903222948165808559332123348274797826204144723168738177180919299881250404026184124858368.0", "-1.797693134862316E308"); /* MAX */ check(&rn, -DBL_TRUE_MIN, "-0.0", "-4.940656458412465E-324"); /* subnorm */ check(&rn, DBL_TRUE_MIN, "0.0", "4.940656458412465E-324"); /* subnorm */ #ifdef NAN check_xer(0, NAN); /* "" */ #else check_xer(0, zero/zero); /* "" */ #endif #ifdef INFINITY check_xer(0, INFINITY); /* "" */ check_xer(0, -INFINITY); /* "" */ #else check_xer(0, 1.0/zero); /* "" */ check_xer(0, -1.0/zero); /* "" */ #endif check_xer(0, 1.0); check_xer(0, -1.0); check_xer(0, 1.5); check_xer(0, 123); check_xer(1, 0.0000000000000000000001); check_xer(1, -0.0000000000000000000001); return 0; }