/* netinfo.c -- generated by Trunnel v1.5.2. * https://gitweb.torproject.org/trunnel.git * You probably shouldn't edit this file. */ #include #include "trunnel-impl.h" #include "netinfo.h" #define TRUNNEL_SET_ERROR_CODE(obj) \ do { \ (obj)->trunnel_error_code_ = 1; \ } while (0) #if defined(__COVERITY__) || defined(__clang_analyzer__) /* If we're running a static analysis tool, we don't want it to complain * that some of our remaining-bytes checks are dead-code. */ int netinfo_deadcode_dummy__ = 0; #define OR_DEADCODE_DUMMY || netinfo_deadcode_dummy__ #else #define OR_DEADCODE_DUMMY #endif #define CHECK_REMAINING(nbytes, label) \ do { \ if (remaining < (nbytes) OR_DEADCODE_DUMMY) { \ goto label; \ } \ } while (0) netinfo_addr_t * netinfo_addr_new(void) { netinfo_addr_t *val = trunnel_calloc(1, sizeof(netinfo_addr_t)); if (NULL == val) return NULL; return val; } /** Release all storage held inside 'obj', but do not free 'obj'. */ static void netinfo_addr_clear(netinfo_addr_t *obj) { (void) obj; } void netinfo_addr_free(netinfo_addr_t *obj) { if (obj == NULL) return; netinfo_addr_clear(obj); trunnel_memwipe(obj, sizeof(netinfo_addr_t)); trunnel_free_(obj); } uint8_t netinfo_addr_get_addr_type(const netinfo_addr_t *inp) { return inp->addr_type; } int netinfo_addr_set_addr_type(netinfo_addr_t *inp, uint8_t val) { inp->addr_type = val; return 0; } uint8_t netinfo_addr_get_len(const netinfo_addr_t *inp) { return inp->len; } int netinfo_addr_set_len(netinfo_addr_t *inp, uint8_t val) { inp->len = val; return 0; } uint32_t netinfo_addr_get_addr_ipv4(const netinfo_addr_t *inp) { return inp->addr_ipv4; } int netinfo_addr_set_addr_ipv4(netinfo_addr_t *inp, uint32_t val) { inp->addr_ipv4 = val; return 0; } size_t netinfo_addr_getlen_addr_ipv6(const netinfo_addr_t *inp) { (void)inp; return 16; } uint8_t netinfo_addr_get_addr_ipv6(netinfo_addr_t *inp, size_t idx) { trunnel_assert(idx < 16); return inp->addr_ipv6[idx]; } uint8_t netinfo_addr_getconst_addr_ipv6(const netinfo_addr_t *inp, size_t idx) { return netinfo_addr_get_addr_ipv6((netinfo_addr_t*)inp, idx); } int netinfo_addr_set_addr_ipv6(netinfo_addr_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 16); inp->addr_ipv6[idx] = elt; return 0; } uint8_t * netinfo_addr_getarray_addr_ipv6(netinfo_addr_t *inp) { return inp->addr_ipv6; } const uint8_t * netinfo_addr_getconstarray_addr_ipv6(const netinfo_addr_t *inp) { return (const uint8_t *)netinfo_addr_getarray_addr_ipv6((netinfo_addr_t*)inp); } const char * netinfo_addr_check(const netinfo_addr_t *obj) { if (obj == NULL) return "Object was NULL"; if (obj->trunnel_error_code_) return "A set function failed on this object"; switch (obj->addr_type) { case NETINFO_ADDR_TYPE_IPV4: break; case NETINFO_ADDR_TYPE_IPV6: break; default: return "Bad tag for union"; break; } return NULL; } ssize_t netinfo_addr_encoded_len(const netinfo_addr_t *obj) { ssize_t result = 0; if (NULL != netinfo_addr_check(obj)) return -1; /* Length of u8 addr_type */ result += 1; /* Length of u8 len */ result += 1; switch (obj->addr_type) { case NETINFO_ADDR_TYPE_IPV4: /* Length of u32 addr_ipv4 */ result += 4; break; case NETINFO_ADDR_TYPE_IPV6: /* Length of u8 addr_ipv6[16] */ result += 16; break; default: trunnel_assert(0); break; } return result; } int netinfo_addr_clear_errors(netinfo_addr_t *obj) { int r = obj->trunnel_error_code_; obj->trunnel_error_code_ = 0; return r; } ssize_t netinfo_addr_encode(uint8_t *output, const size_t avail, const netinfo_addr_t *obj) { ssize_t result = 0; size_t written = 0; uint8_t *ptr = output; const char *msg; #ifdef TRUNNEL_CHECK_ENCODED_LEN const ssize_t encoded_len = netinfo_addr_encoded_len(obj); #endif if (NULL != (msg = netinfo_addr_check(obj))) goto check_failed; #ifdef TRUNNEL_CHECK_ENCODED_LEN trunnel_assert(encoded_len >= 0); #endif /* Encode u8 addr_type */ trunnel_assert(written <= avail); if (avail - written < 1) goto truncated; trunnel_set_uint8(ptr, (obj->addr_type)); written += 1; ptr += 1; /* Encode u8 len */ trunnel_assert(written <= avail); if (avail - written < 1) goto truncated; trunnel_set_uint8(ptr, (obj->len)); written += 1; ptr += 1; /* Encode union addr[addr_type] */ trunnel_assert(written <= avail); switch (obj->addr_type) { case NETINFO_ADDR_TYPE_IPV4: /* Encode u32 addr_ipv4 */ trunnel_assert(written <= avail); if (avail - written < 4) goto truncated; trunnel_set_uint32(ptr, trunnel_htonl(obj->addr_ipv4)); written += 4; ptr += 4; break; case NETINFO_ADDR_TYPE_IPV6: /* Encode u8 addr_ipv6[16] */ trunnel_assert(written <= avail); if (avail - written < 16) goto truncated; memcpy(ptr, obj->addr_ipv6, 16); written += 16; ptr += 16; break; default: trunnel_assert(0); break; } trunnel_assert(ptr == output + written); #ifdef TRUNNEL_CHECK_ENCODED_LEN { trunnel_assert(encoded_len >= 0); trunnel_assert((size_t)encoded_len == written); } #endif return written; truncated: result = -2; goto fail; check_failed: (void)msg; result = -1; goto fail; fail: trunnel_assert(result < 0); return result; } /** As netinfo_addr_parse(), but do not allocate the output object. */ static ssize_t netinfo_addr_parse_into(netinfo_addr_t *obj, const uint8_t *input, const size_t len_in) { const uint8_t *ptr = input; size_t remaining = len_in; ssize_t result = 0; (void)result; /* Parse u8 addr_type */ CHECK_REMAINING(1, truncated); obj->addr_type = (trunnel_get_uint8(ptr)); remaining -= 1; ptr += 1; /* Parse u8 len */ CHECK_REMAINING(1, truncated); obj->len = (trunnel_get_uint8(ptr)); remaining -= 1; ptr += 1; /* Parse union addr[addr_type] */ switch (obj->addr_type) { case NETINFO_ADDR_TYPE_IPV4: /* Parse u32 addr_ipv4 */ CHECK_REMAINING(4, truncated); obj->addr_ipv4 = trunnel_ntohl(trunnel_get_uint32(ptr)); remaining -= 4; ptr += 4; break; case NETINFO_ADDR_TYPE_IPV6: /* Parse u8 addr_ipv6[16] */ CHECK_REMAINING(16, truncated); memcpy(obj->addr_ipv6, ptr, 16); remaining -= 16; ptr += 16; break; default: goto fail; break; } trunnel_assert(ptr + remaining == input + len_in); return len_in - remaining; truncated: return -2; fail: result = -1; return result; } ssize_t netinfo_addr_parse(netinfo_addr_t **output, const uint8_t *input, const size_t len_in) { ssize_t result; *output = netinfo_addr_new(); if (NULL == *output) return -1; result = netinfo_addr_parse_into(*output, input, len_in); if (result < 0) { netinfo_addr_free(*output); *output = NULL; } return result; } netinfo_cell_t * netinfo_cell_new(void) { netinfo_cell_t *val = trunnel_calloc(1, sizeof(netinfo_cell_t)); if (NULL == val) return NULL; return val; } /** Release all storage held inside 'obj', but do not free 'obj'. */ static void netinfo_cell_clear(netinfo_cell_t *obj) { (void) obj; netinfo_addr_free(obj->other_addr); obj->other_addr = NULL; { unsigned idx; for (idx = 0; idx < TRUNNEL_DYNARRAY_LEN(&obj->my_addrs); ++idx) { netinfo_addr_free(TRUNNEL_DYNARRAY_GET(&obj->my_addrs, idx)); } } TRUNNEL_DYNARRAY_WIPE(&obj->my_addrs); TRUNNEL_DYNARRAY_CLEAR(&obj->my_addrs); } void netinfo_cell_free(netinfo_cell_t *obj) { if (obj == NULL) return; netinfo_cell_clear(obj); trunnel_memwipe(obj, sizeof(netinfo_cell_t)); trunnel_free_(obj); } uint32_t netinfo_cell_get_timestamp(const netinfo_cell_t *inp) { return inp->timestamp; } int netinfo_cell_set_timestamp(netinfo_cell_t *inp, uint32_t val) { inp->timestamp = val; return 0; } struct netinfo_addr_st * netinfo_cell_get_other_addr(netinfo_cell_t *inp) { return inp->other_addr; } const struct netinfo_addr_st * netinfo_cell_getconst_other_addr(const netinfo_cell_t *inp) { return netinfo_cell_get_other_addr((netinfo_cell_t*) inp); } int netinfo_cell_set_other_addr(netinfo_cell_t *inp, struct netinfo_addr_st *val) { if (inp->other_addr && inp->other_addr != val) netinfo_addr_free(inp->other_addr); return netinfo_cell_set0_other_addr(inp, val); } int netinfo_cell_set0_other_addr(netinfo_cell_t *inp, struct netinfo_addr_st *val) { inp->other_addr = val; return 0; } uint8_t netinfo_cell_get_n_my_addrs(const netinfo_cell_t *inp) { return inp->n_my_addrs; } int netinfo_cell_set_n_my_addrs(netinfo_cell_t *inp, uint8_t val) { inp->n_my_addrs = val; return 0; } size_t netinfo_cell_getlen_my_addrs(const netinfo_cell_t *inp) { return TRUNNEL_DYNARRAY_LEN(&inp->my_addrs); } struct netinfo_addr_st * netinfo_cell_get_my_addrs(netinfo_cell_t *inp, size_t idx) { return TRUNNEL_DYNARRAY_GET(&inp->my_addrs, idx); } const struct netinfo_addr_st * netinfo_cell_getconst_my_addrs(const netinfo_cell_t *inp, size_t idx) { return netinfo_cell_get_my_addrs((netinfo_cell_t*)inp, idx); } int netinfo_cell_set_my_addrs(netinfo_cell_t *inp, size_t idx, struct netinfo_addr_st * elt) { netinfo_addr_t *oldval = TRUNNEL_DYNARRAY_GET(&inp->my_addrs, idx); if (oldval && oldval != elt) netinfo_addr_free(oldval); return netinfo_cell_set0_my_addrs(inp, idx, elt); } int netinfo_cell_set0_my_addrs(netinfo_cell_t *inp, size_t idx, struct netinfo_addr_st * elt) { TRUNNEL_DYNARRAY_SET(&inp->my_addrs, idx, elt); return 0; } int netinfo_cell_add_my_addrs(netinfo_cell_t *inp, struct netinfo_addr_st * elt) { #if SIZE_MAX >= UINT8_MAX if (inp->my_addrs.n_ == UINT8_MAX) goto trunnel_alloc_failed; #endif TRUNNEL_DYNARRAY_ADD(struct netinfo_addr_st *, &inp->my_addrs, elt, {}); return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } struct netinfo_addr_st * * netinfo_cell_getarray_my_addrs(netinfo_cell_t *inp) { return inp->my_addrs.elts_; } const struct netinfo_addr_st * const * netinfo_cell_getconstarray_my_addrs(const netinfo_cell_t *inp) { return (const struct netinfo_addr_st * const *)netinfo_cell_getarray_my_addrs((netinfo_cell_t*)inp); } int netinfo_cell_setlen_my_addrs(netinfo_cell_t *inp, size_t newlen) { struct netinfo_addr_st * *newptr; #if UINT8_MAX < SIZE_MAX if (newlen > UINT8_MAX) goto trunnel_alloc_failed; #endif newptr = trunnel_dynarray_setlen(&inp->my_addrs.allocated_, &inp->my_addrs.n_, inp->my_addrs.elts_, newlen, sizeof(inp->my_addrs.elts_[0]), (trunnel_free_fn_t) netinfo_addr_free, &inp->trunnel_error_code_); if (newlen != 0 && newptr == NULL) goto trunnel_alloc_failed; inp->my_addrs.elts_ = newptr; return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } const char * netinfo_cell_check(const netinfo_cell_t *obj) { if (obj == NULL) return "Object was NULL"; if (obj->trunnel_error_code_) return "A set function failed on this object"; { const char *msg; if (NULL != (msg = netinfo_addr_check(obj->other_addr))) return msg; } { const char *msg; unsigned idx; for (idx = 0; idx < TRUNNEL_DYNARRAY_LEN(&obj->my_addrs); ++idx) { if (NULL != (msg = netinfo_addr_check(TRUNNEL_DYNARRAY_GET(&obj->my_addrs, idx)))) return msg; } } if (TRUNNEL_DYNARRAY_LEN(&obj->my_addrs) != obj->n_my_addrs) return "Length mismatch for my_addrs"; return NULL; } ssize_t netinfo_cell_encoded_len(const netinfo_cell_t *obj) { ssize_t result = 0; if (NULL != netinfo_cell_check(obj)) return -1; /* Length of u32 timestamp */ result += 4; /* Length of struct netinfo_addr other_addr */ result += netinfo_addr_encoded_len(obj->other_addr); /* Length of u8 n_my_addrs */ result += 1; /* Length of struct netinfo_addr my_addrs[n_my_addrs] */ { unsigned idx; for (idx = 0; idx < TRUNNEL_DYNARRAY_LEN(&obj->my_addrs); ++idx) { result += netinfo_addr_encoded_len(TRUNNEL_DYNARRAY_GET(&obj->my_addrs, idx)); } } return result; } int netinfo_cell_clear_errors(netinfo_cell_t *obj) { int r = obj->trunnel_error_code_; obj->trunnel_error_code_ = 0; return r; } ssize_t netinfo_cell_encode(uint8_t *output, const size_t avail, const netinfo_cell_t *obj) { ssize_t result = 0; size_t written = 0; uint8_t *ptr = output; const char *msg; #ifdef TRUNNEL_CHECK_ENCODED_LEN const ssize_t encoded_len = netinfo_cell_encoded_len(obj); #endif if (NULL != (msg = netinfo_cell_check(obj))) goto check_failed; #ifdef TRUNNEL_CHECK_ENCODED_LEN trunnel_assert(encoded_len >= 0); #endif /* Encode u32 timestamp */ trunnel_assert(written <= avail); if (avail - written < 4) goto truncated; trunnel_set_uint32(ptr, trunnel_htonl(obj->timestamp)); written += 4; ptr += 4; /* Encode struct netinfo_addr other_addr */ trunnel_assert(written <= avail); result = netinfo_addr_encode(ptr, avail - written, obj->other_addr); if (result < 0) goto fail; /* XXXXXXX !*/ written += result; ptr += result; /* Encode u8 n_my_addrs */ trunnel_assert(written <= avail); if (avail - written < 1) goto truncated; trunnel_set_uint8(ptr, (obj->n_my_addrs)); written += 1; ptr += 1; /* Encode struct netinfo_addr my_addrs[n_my_addrs] */ { unsigned idx; for (idx = 0; idx < TRUNNEL_DYNARRAY_LEN(&obj->my_addrs); ++idx) { trunnel_assert(written <= avail); result = netinfo_addr_encode(ptr, avail - written, TRUNNEL_DYNARRAY_GET(&obj->my_addrs, idx)); if (result < 0) goto fail; /* XXXXXXX !*/ written += result; ptr += result; } } trunnel_assert(ptr == output + written); #ifdef TRUNNEL_CHECK_ENCODED_LEN { trunnel_assert(encoded_len >= 0); trunnel_assert((size_t)encoded_len == written); } #endif return written; truncated: result = -2; goto fail; check_failed: (void)msg; result = -1; goto fail; fail: trunnel_assert(result < 0); return result; } /** As netinfo_cell_parse(), but do not allocate the output object. */ static ssize_t netinfo_cell_parse_into(netinfo_cell_t *obj, const uint8_t *input, const size_t len_in) { const uint8_t *ptr = input; size_t remaining = len_in; ssize_t result = 0; (void)result; /* Parse u32 timestamp */ CHECK_REMAINING(4, truncated); obj->timestamp = trunnel_ntohl(trunnel_get_uint32(ptr)); remaining -= 4; ptr += 4; /* Parse struct netinfo_addr other_addr */ result = netinfo_addr_parse(&obj->other_addr, ptr, remaining); if (result < 0) goto relay_fail; trunnel_assert((size_t)result <= remaining); remaining -= result; ptr += result; /* Parse u8 n_my_addrs */ CHECK_REMAINING(1, truncated); obj->n_my_addrs = (trunnel_get_uint8(ptr)); remaining -= 1; ptr += 1; /* Parse struct netinfo_addr my_addrs[n_my_addrs] */ TRUNNEL_DYNARRAY_EXPAND(netinfo_addr_t *, &obj->my_addrs, obj->n_my_addrs, {}); { netinfo_addr_t * elt; unsigned idx; for (idx = 0; idx < obj->n_my_addrs; ++idx) { result = netinfo_addr_parse(&elt, ptr, remaining); if (result < 0) goto relay_fail; trunnel_assert((size_t)result <= remaining); remaining -= result; ptr += result; TRUNNEL_DYNARRAY_ADD(netinfo_addr_t *, &obj->my_addrs, elt, {netinfo_addr_free(elt);}); } } trunnel_assert(ptr + remaining == input + len_in); return len_in - remaining; truncated: return -2; relay_fail: trunnel_assert(result < 0); return result; trunnel_alloc_failed: return -1; } ssize_t netinfo_cell_parse(netinfo_cell_t **output, const uint8_t *input, const size_t len_in) { ssize_t result; *output = netinfo_cell_new(); if (NULL == *output) return -1; result = netinfo_cell_parse_into(*output, input, len_in); if (result < 0) { netinfo_cell_free(*output); *output = NULL; } return result; }