#include #include #include #include #define CHECK_DECODE(code, a, b, c, d, e, f) check_decode(__LINE__, code, a, b, c, d, e, f) #define CHECK_ROUNDTRIP(a, b, c) check_roundtrip(__LINE__, a, b, c); #define CHECK_ENCODE_OK(a, b, c) check_encode(__LINE__, 0, a, b, c) #define CHECK_ENCODE_BAD(a, b, c) check_encode(__LINE__, 1, a, b, c); static asn_oer_constraints_t * setup_constraints(unsigned width, unsigned positive) { static struct asn_oer_constraints_s empty_constraints; asn_oer_constraints_t *constraints = &empty_constraints; asn_oer_constraint_number_t *ct_value = &constraints->value; memset(&empty_constraints, 0, sizeof(empty_constraints)); /* Setup integer constraints as requested */ ct_value->width = width; ct_value->positive = positive; return constraints; } static void check_decode(int lineno, enum asn_dec_rval_code_e code, intmax_t control, const char *buf, size_t size, const char *dummy, unsigned width, unsigned positive) { static char *code_s[] = { "RC_OK", "RC_WMORE", "RC_FAIL", "" }; fprintf(stderr, "\n%d: OER decode (control %" PRIdMAX ")\n", lineno, control); INTEGER_t *st = NULL; asn_dec_rval_t ret; asn_oer_constraints_t *constraints = setup_constraints(width, positive); fprintf(stderr, "%d: buf[%zu]={%d, %d, ...}\n", lineno, size, size <= 0 ? -1 : ((const uint8_t *)buf)[0], size <= 1 ? -1 : ((const uint8_t *)buf)[1]); (void)dummy; ret = asn_DEF_INTEGER.op->oer_decoder(0, &asn_DEF_INTEGER, constraints, (void **)&st, buf, size); if(ret.code != RC_OK) { /* Basic OER decode does not work */ fprintf(stderr, "%d: Failed oer_decode(ctl=%" PRIdMAX ", size=%zu)\n", lineno, control, size); if(ret.code == code) { fprintf(stderr, " (That was expected)\n"); ASN_STRUCT_FREE(asn_DEF_INTEGER, st); return; } else { fprintf( stderr, " Unexpected return code %s (%d) expected %s\n", code_s[(unsigned)ret.code <= RC_FAIL ? RC_FAIL : (RC_FAIL + 1)], (int)ret.code, code_s[code]); assert(ret.code == code); } } else { intmax_t outcome; if(asn_INTEGER2imax(st, &outcome) != 0) { /* Result of decode is structurally incorrect */ fprintf(stderr, "%d: Failed to convert INTEGER 2 imax; structurally " "incorrect INTEGER\n", lineno); assert(!"Unreachable"); } else if(outcome != control) { /* Decoded value is wrong */ fprintf(stderr, "%d: Decode result %" PRIdMAX " is not expected %" PRIdMAX "\n", lineno, outcome, control); assert(outcome == control); } } fprintf(stderr, "%d: Decode result %" PRIdMAX "\n", lineno, control); ASN_STRUCT_FREE(asn_DEF_INTEGER, st); } static void dump_data(int lineno, const uint8_t *buf, size_t size) { const uint8_t *p = buf; const uint8_t *end = buf + size; fprintf(stderr, "%d: Encoded: [", lineno); for(; p < end; p++) { fprintf(stderr, "\\x%02x", *(const unsigned char *)p); } fprintf(stderr, "] (%zu bytes)\n", size); } static void check_roundtrip(int lineno, intmax_t value, intmax_t lower_bound, intmax_t upper_bound) { uint8_t tmpbuf[32]; size_t tmpbuf_size; fprintf(stderr, "\n%d: OER round-trip value %" PRIdMAX "\n", lineno, value); INTEGER_t *stOut = (INTEGER_t *)calloc(1, sizeof(*stOut)); INTEGER_t *stIn = NULL; asn_enc_rval_t er; asn_dec_rval_t ret; asn_oer_constraints_t *constraints = setup_constraints(lower_bound, upper_bound); if(asn_imax2INTEGER(stOut, value) == -1) { assert(!"Unreachable imax2INTEGER failure"); } else { assert(stOut->buf != NULL); assert(stOut->size != 0); } er = oer_encode_to_buffer(&asn_DEF_INTEGER, constraints, stOut, tmpbuf, sizeof(tmpbuf)); if(er.encoded == -1) { fprintf(stderr, "%d: OER encode failed for %s\n", lineno, er.failed_type ? er.failed_type->name : ""); assert(er.encoded != -1); } tmpbuf_size = er.encoded; ASN_STRUCT_FREE(asn_DEF_INTEGER, stOut); dump_data(lineno, tmpbuf, tmpbuf_size); ret = asn_DEF_INTEGER.op->oer_decoder(0, &asn_DEF_INTEGER, constraints, (void **)&stIn, tmpbuf, tmpbuf_size); if(ret.code != RC_OK) { /* Basic OER decode does not work */ fprintf(stderr, "%d: Failed oer_decode(value=%" PRIdMAX ", size=%zu)\n", lineno, value, tmpbuf_size); assert(ret.code == 0); } else { intmax_t outcome; if(asn_INTEGER2imax(stIn, &outcome) != 0) { /* Result of decode is structurally incorrect */ fprintf(stderr, "%d: Failed to convert INTEGER 2 imax; structurally " "incorrect INTEGER\n", lineno); assert(!"Unreachable"); } else if(outcome != value) { /* Decoded value is wrong */ fprintf(stderr, "%d: Decode result %" PRIdMAX " is not expected %" PRIdMAX "\n", lineno, outcome, value); assert(outcome == value); } } ASN_STRUCT_FREE(asn_DEF_INTEGER, stIn); fprintf(stderr, "%d: Decode result %" PRIdMAX "\n", lineno, value); } static void check_encode(int lineno, int bad, intmax_t value, unsigned width, unsigned positive) { uint8_t tmpbuf[32]; fprintf(stderr, "\n%d: OER encode value %" PRIdMAX "\n", lineno, value); INTEGER_t *stOut = (INTEGER_t *)calloc(1, sizeof(*stOut)); asn_enc_rval_t er; asn_oer_constraints_t *constraints = setup_constraints(width, positive); if(asn_imax2INTEGER(stOut, value) == -1) { assert(!"Unreachable imax2INTEGER failure"); } else { assert(stOut->buf != NULL); assert(stOut->size != 0); } er = oer_encode_to_buffer(&asn_DEF_INTEGER, constraints, stOut, tmpbuf, sizeof(tmpbuf)); if(er.encoded == -1) { fprintf(stderr, "%d: OER encode failed for %s%s\n", lineno, er.failed_type ? er.failed_type->name : "", bad ? " (expected)" : ""); if(!bad) { assert(er.encoded != -1); } } else { dump_data(lineno, tmpbuf, er.encoded); if(bad) { assert(er.encoded == -1); } } ASN_STRUCT_FREE(asn_DEF_INTEGER, stOut); } int main() { CHECK_DECODE(RC_WMORE, 0, "", 0, "bounds=", 0, 0); CHECK_DECODE(RC_FAIL, 0, "\x00", 1, "bounds=", 0, 0); CHECK_DECODE(RC_WMORE, 0, "", 0, "bounds=", 1, 0); CHECK_DECODE(RC_WMORE, 0, "", 0, "bounds=", 1, 1); CHECK_DECODE(RC_OK, 0, "\x00", 1, "bounds=", 1, 1); CHECK_DECODE(RC_OK, 0, "\x00", 1, "bounds=", 1, 0); CHECK_DECODE(RC_OK, 0, "\x00", 1, "bounds=", 1, 0); CHECK_DECODE(RC_OK, 1, "\x01", 1, "bounds=", 1, 0); CHECK_DECODE(RC_OK, -1, "\xff", 1, "bounds=", 1, 0); CHECK_DECODE(RC_OK, -1, "\xff", 1, "bounds=", 1, 0); CHECK_DECODE(RC_OK, 127, "\x7f", 1, "bounds=", 1, 1); CHECK_DECODE(RC_OK, 255, "\xff", 1, "bounds=", 1, 1); CHECK_DECODE(RC_OK, 255, "\xff", 1, "bounds=", 1, 1); CHECK_DECODE(RC_WMORE, 0, "\xff", 1, "bounds=", 2, 1); CHECK_DECODE(RC_OK, 65535, "\xff\xff", 2, "bounds=", 2, 1); CHECK_DECODE(RC_OK, 0, "\x01\x00", 2, "bounds=", 0, 0); CHECK_DECODE(RC_OK, 1, "\x01\x01", 2, "bounds=", 0, 0); CHECK_DECODE(RC_OK, -1, "\x1\xff", 2, "bounds=", 0, 0); CHECK_DECODE(RC_OK, -1, "\x1\xff", 2, "bounds=", 0, 0); CHECK_DECODE(RC_OK, -1, "\x1\xff", 2, "bounds=", 0, 0); CHECK_DECODE(RC_OK, 255, "\x1\xff", 2, "bounds=", 0, 1); CHECK_DECODE(RC_WMORE, -1, "\x02\x00\xff", 2, "bounds=", 0, 0); CHECK_DECODE(RC_OK, 255, "\x02\x00\xff", 3, "bounds=", 0, 0); CHECK_ROUNDTRIP(0, 0, 0); CHECK_ROUNDTRIP(1, 0, 0); CHECK_ROUNDTRIP(-1, 0, 0); CHECK_ROUNDTRIP(-65000, 0, 0); CHECK_ROUNDTRIP(65000, 0, 0); CHECK_ROUNDTRIP(65535, 0, 0); CHECK_ROUNDTRIP(-65535, 0, 0); CHECK_ROUNDTRIP(-65536, 0, 0); CHECK_ROUNDTRIP(65536, 0, 0); CHECK_ROUNDTRIP(0, 1, 0); CHECK_ROUNDTRIP(1, 1, 0); CHECK_ROUNDTRIP(-1, 1, 0); CHECK_ROUNDTRIP(-127, 1, 0); CHECK_ROUNDTRIP(-128, 1, 0); CHECK_ROUNDTRIP(127, 1, 0); CHECK_ROUNDTRIP(1, 2, 1); CHECK_ROUNDTRIP(32000, 2, 1); CHECK_ROUNDTRIP(32000, 2, 0); CHECK_ROUNDTRIP(1, 2, 1); CHECK_ROUNDTRIP(65535, 2, 1); CHECK_ROUNDTRIP(65535, 4, 0); CHECK_ENCODE_OK(0, 1, 1); CHECK_ENCODE_OK(255, 1, 1); CHECK_ENCODE_BAD(256, 1, 1); CHECK_ENCODE_OK(0, 1, 0); CHECK_ENCODE_OK(127, 1, 0); CHECK_ENCODE_OK(-128, 1, 0); CHECK_ENCODE_BAD(-129, 1, 0); CHECK_ENCODE_BAD(128, 1, 0); CHECK_ENCODE_OK(-4900000000, 8, 0); CHECK_ENCODE_OK(4900000000, 8, 0); CHECK_ENCODE_OK(-2000000000, 8, 0); CHECK_ENCODE_OK(-4000000000, 8, 0); CHECK_ENCODE_BAD(-4900000000, 4, 1); CHECK_ENCODE_BAD(-1, 0, 4000000000); CHECK_ENCODE_BAD(4900000000, 4, 1); CHECK_ENCODE_OK(4100000000, 4, 1); for(size_t i = 0; i < 7 ; i++) { intmax_t value = (intmax_t)1 << i; CHECK_ROUNDTRIP(value, 1, 1); value = -value; CHECK_ROUNDTRIP(value, 1, 0); } for(size_t i = 0; i < 16 ; i++) { intmax_t value = (intmax_t)1 << i; CHECK_ROUNDTRIP(value, 2, 1); value = -value; CHECK_ROUNDTRIP(value, 2, 0); } for(size_t i = 0; i < 32 ; i++) { intmax_t value = (intmax_t)1 << i; CHECK_ROUNDTRIP(value, 4, 1); value = -value; CHECK_ROUNDTRIP(value, 4, 0); } for(size_t i = 0; i < 8 * sizeof(intmax_t) - 1; i++) { intmax_t value = (intmax_t)1 << i; CHECK_ROUNDTRIP(value, 8, 0); value = -value; CHECK_ROUNDTRIP(value, 8, 0); } for(size_t i = 0; i < 8 * sizeof(intmax_t) - 1; i++) { intmax_t value = (intmax_t)1 << i; CHECK_ROUNDTRIP(value, 0, 0); value = -value; CHECK_ROUNDTRIP(value, 0, 0); } }