/* link_handshake.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 "link_handshake.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 linkhandshake_deadcode_dummy__ = 0; #define OR_DEADCODE_DUMMY || linkhandshake_deadcode_dummy__ #else #define OR_DEADCODE_DUMMY #endif #define CHECK_REMAINING(nbytes, label) \ do { \ if (remaining < (nbytes) OR_DEADCODE_DUMMY) { \ goto label; \ } \ } while (0) auth_challenge_cell_t * auth_challenge_cell_new(void) { auth_challenge_cell_t *val = trunnel_calloc(1, sizeof(auth_challenge_cell_t)); if (NULL == val) return NULL; return val; } /** Release all storage held inside 'obj', but do not free 'obj'. */ static void auth_challenge_cell_clear(auth_challenge_cell_t *obj) { (void) obj; TRUNNEL_DYNARRAY_WIPE(&obj->methods); TRUNNEL_DYNARRAY_CLEAR(&obj->methods); } void auth_challenge_cell_free(auth_challenge_cell_t *obj) { if (obj == NULL) return; auth_challenge_cell_clear(obj); trunnel_memwipe(obj, sizeof(auth_challenge_cell_t)); trunnel_free_(obj); } size_t auth_challenge_cell_getlen_challenge(const auth_challenge_cell_t *inp) { (void)inp; return 32; } uint8_t auth_challenge_cell_get_challenge(auth_challenge_cell_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->challenge[idx]; } uint8_t auth_challenge_cell_getconst_challenge(const auth_challenge_cell_t *inp, size_t idx) { return auth_challenge_cell_get_challenge((auth_challenge_cell_t*)inp, idx); } int auth_challenge_cell_set_challenge(auth_challenge_cell_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->challenge[idx] = elt; return 0; } uint8_t * auth_challenge_cell_getarray_challenge(auth_challenge_cell_t *inp) { return inp->challenge; } const uint8_t * auth_challenge_cell_getconstarray_challenge(const auth_challenge_cell_t *inp) { return (const uint8_t *)auth_challenge_cell_getarray_challenge((auth_challenge_cell_t*)inp); } uint16_t auth_challenge_cell_get_n_methods(const auth_challenge_cell_t *inp) { return inp->n_methods; } int auth_challenge_cell_set_n_methods(auth_challenge_cell_t *inp, uint16_t val) { inp->n_methods = val; return 0; } size_t auth_challenge_cell_getlen_methods(const auth_challenge_cell_t *inp) { return TRUNNEL_DYNARRAY_LEN(&inp->methods); } uint16_t auth_challenge_cell_get_methods(auth_challenge_cell_t *inp, size_t idx) { return TRUNNEL_DYNARRAY_GET(&inp->methods, idx); } uint16_t auth_challenge_cell_getconst_methods(const auth_challenge_cell_t *inp, size_t idx) { return auth_challenge_cell_get_methods((auth_challenge_cell_t*)inp, idx); } int auth_challenge_cell_set_methods(auth_challenge_cell_t *inp, size_t idx, uint16_t elt) { TRUNNEL_DYNARRAY_SET(&inp->methods, idx, elt); return 0; } int auth_challenge_cell_add_methods(auth_challenge_cell_t *inp, uint16_t elt) { #if SIZE_MAX >= UINT16_MAX if (inp->methods.n_ == UINT16_MAX) goto trunnel_alloc_failed; #endif TRUNNEL_DYNARRAY_ADD(uint16_t, &inp->methods, elt, {}); return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } uint16_t * auth_challenge_cell_getarray_methods(auth_challenge_cell_t *inp) { return inp->methods.elts_; } const uint16_t * auth_challenge_cell_getconstarray_methods(const auth_challenge_cell_t *inp) { return (const uint16_t *)auth_challenge_cell_getarray_methods((auth_challenge_cell_t*)inp); } int auth_challenge_cell_setlen_methods(auth_challenge_cell_t *inp, size_t newlen) { uint16_t *newptr; #if UINT16_MAX < SIZE_MAX if (newlen > UINT16_MAX) goto trunnel_alloc_failed; #endif newptr = trunnel_dynarray_setlen(&inp->methods.allocated_, &inp->methods.n_, inp->methods.elts_, newlen, sizeof(inp->methods.elts_[0]), (trunnel_free_fn_t) NULL, &inp->trunnel_error_code_); if (newlen != 0 && newptr == NULL) goto trunnel_alloc_failed; inp->methods.elts_ = newptr; return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } const char * auth_challenge_cell_check(const auth_challenge_cell_t *obj) { if (obj == NULL) return "Object was NULL"; if (obj->trunnel_error_code_) return "A set function failed on this object"; if (TRUNNEL_DYNARRAY_LEN(&obj->methods) != obj->n_methods) return "Length mismatch for methods"; return NULL; } ssize_t auth_challenge_cell_encoded_len(const auth_challenge_cell_t *obj) { ssize_t result = 0; if (NULL != auth_challenge_cell_check(obj)) return -1; /* Length of u8 challenge[32] */ result += 32; /* Length of u16 n_methods */ result += 2; /* Length of u16 methods[n_methods] */ result += 2 * TRUNNEL_DYNARRAY_LEN(&obj->methods); return result; } int auth_challenge_cell_clear_errors(auth_challenge_cell_t *obj) { int r = obj->trunnel_error_code_; obj->trunnel_error_code_ = 0; return r; } ssize_t auth_challenge_cell_encode(uint8_t *output, const size_t avail, const auth_challenge_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 = auth_challenge_cell_encoded_len(obj); #endif if (NULL != (msg = auth_challenge_cell_check(obj))) goto check_failed; #ifdef TRUNNEL_CHECK_ENCODED_LEN trunnel_assert(encoded_len >= 0); #endif /* Encode u8 challenge[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->challenge, 32); written += 32; ptr += 32; /* Encode u16 n_methods */ trunnel_assert(written <= avail); if (avail - written < 2) goto truncated; trunnel_set_uint16(ptr, trunnel_htons(obj->n_methods)); written += 2; ptr += 2; /* Encode u16 methods[n_methods] */ { unsigned idx; for (idx = 0; idx < TRUNNEL_DYNARRAY_LEN(&obj->methods); ++idx) { trunnel_assert(written <= avail); if (avail - written < 2) goto truncated; trunnel_set_uint16(ptr, trunnel_htons(TRUNNEL_DYNARRAY_GET(&obj->methods, idx))); written += 2; ptr += 2; } } 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 auth_challenge_cell_parse(), but do not allocate the output * object. */ static ssize_t auth_challenge_cell_parse_into(auth_challenge_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 u8 challenge[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->challenge, ptr, 32); remaining -= 32; ptr += 32; /* Parse u16 n_methods */ CHECK_REMAINING(2, truncated); obj->n_methods = trunnel_ntohs(trunnel_get_uint16(ptr)); remaining -= 2; ptr += 2; /* Parse u16 methods[n_methods] */ TRUNNEL_DYNARRAY_EXPAND(uint16_t, &obj->methods, obj->n_methods, {}); { uint16_t elt; unsigned idx; for (idx = 0; idx < obj->n_methods; ++idx) { CHECK_REMAINING(2, truncated); elt = trunnel_ntohs(trunnel_get_uint16(ptr)); remaining -= 2; ptr += 2; TRUNNEL_DYNARRAY_ADD(uint16_t, &obj->methods, elt, {}); } } trunnel_assert(ptr + remaining == input + len_in); return len_in - remaining; truncated: return -2; trunnel_alloc_failed: return -1; } ssize_t auth_challenge_cell_parse(auth_challenge_cell_t **output, const uint8_t *input, const size_t len_in) { ssize_t result; *output = auth_challenge_cell_new(); if (NULL == *output) return -1; result = auth_challenge_cell_parse_into(*output, input, len_in); if (result < 0) { auth_challenge_cell_free(*output); *output = NULL; } return result; } auth_ctx_t * auth_ctx_new(void) { auth_ctx_t *val = trunnel_calloc(1, sizeof(auth_ctx_t)); if (NULL == val) return NULL; return val; } /** Release all storage held inside 'obj', but do not free 'obj'. */ static void auth_ctx_clear(auth_ctx_t *obj) { (void) obj; } void auth_ctx_free(auth_ctx_t *obj) { if (obj == NULL) return; auth_ctx_clear(obj); trunnel_memwipe(obj, sizeof(auth_ctx_t)); trunnel_free_(obj); } uint8_t auth_ctx_get_is_ed(const auth_ctx_t *inp) { return inp->is_ed; } int auth_ctx_set_is_ed(auth_ctx_t *inp, uint8_t val) { inp->is_ed = val; return 0; } certs_cell_cert_t * certs_cell_cert_new(void) { certs_cell_cert_t *val = trunnel_calloc(1, sizeof(certs_cell_cert_t)); if (NULL == val) return NULL; return val; } /** Release all storage held inside 'obj', but do not free 'obj'. */ static void certs_cell_cert_clear(certs_cell_cert_t *obj) { (void) obj; TRUNNEL_DYNARRAY_WIPE(&obj->body); TRUNNEL_DYNARRAY_CLEAR(&obj->body); } void certs_cell_cert_free(certs_cell_cert_t *obj) { if (obj == NULL) return; certs_cell_cert_clear(obj); trunnel_memwipe(obj, sizeof(certs_cell_cert_t)); trunnel_free_(obj); } uint8_t certs_cell_cert_get_cert_type(const certs_cell_cert_t *inp) { return inp->cert_type; } int certs_cell_cert_set_cert_type(certs_cell_cert_t *inp, uint8_t val) { inp->cert_type = val; return 0; } uint16_t certs_cell_cert_get_cert_len(const certs_cell_cert_t *inp) { return inp->cert_len; } int certs_cell_cert_set_cert_len(certs_cell_cert_t *inp, uint16_t val) { inp->cert_len = val; return 0; } size_t certs_cell_cert_getlen_body(const certs_cell_cert_t *inp) { return TRUNNEL_DYNARRAY_LEN(&inp->body); } uint8_t certs_cell_cert_get_body(certs_cell_cert_t *inp, size_t idx) { return TRUNNEL_DYNARRAY_GET(&inp->body, idx); } uint8_t certs_cell_cert_getconst_body(const certs_cell_cert_t *inp, size_t idx) { return certs_cell_cert_get_body((certs_cell_cert_t*)inp, idx); } int certs_cell_cert_set_body(certs_cell_cert_t *inp, size_t idx, uint8_t elt) { TRUNNEL_DYNARRAY_SET(&inp->body, idx, elt); return 0; } int certs_cell_cert_add_body(certs_cell_cert_t *inp, uint8_t elt) { #if SIZE_MAX >= UINT16_MAX if (inp->body.n_ == UINT16_MAX) goto trunnel_alloc_failed; #endif TRUNNEL_DYNARRAY_ADD(uint8_t, &inp->body, elt, {}); return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } uint8_t * certs_cell_cert_getarray_body(certs_cell_cert_t *inp) { return inp->body.elts_; } const uint8_t * certs_cell_cert_getconstarray_body(const certs_cell_cert_t *inp) { return (const uint8_t *)certs_cell_cert_getarray_body((certs_cell_cert_t*)inp); } int certs_cell_cert_setlen_body(certs_cell_cert_t *inp, size_t newlen) { uint8_t *newptr; #if UINT16_MAX < SIZE_MAX if (newlen > UINT16_MAX) goto trunnel_alloc_failed; #endif newptr = trunnel_dynarray_setlen(&inp->body.allocated_, &inp->body.n_, inp->body.elts_, newlen, sizeof(inp->body.elts_[0]), (trunnel_free_fn_t) NULL, &inp->trunnel_error_code_); if (newlen != 0 && newptr == NULL) goto trunnel_alloc_failed; inp->body.elts_ = newptr; return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } const char * certs_cell_cert_check(const certs_cell_cert_t *obj) { if (obj == NULL) return "Object was NULL"; if (obj->trunnel_error_code_) return "A set function failed on this object"; if (TRUNNEL_DYNARRAY_LEN(&obj->body) != obj->cert_len) return "Length mismatch for body"; return NULL; } ssize_t certs_cell_cert_encoded_len(const certs_cell_cert_t *obj) { ssize_t result = 0; if (NULL != certs_cell_cert_check(obj)) return -1; /* Length of u8 cert_type */ result += 1; /* Length of u16 cert_len */ result += 2; /* Length of u8 body[cert_len] */ result += TRUNNEL_DYNARRAY_LEN(&obj->body); return result; } int certs_cell_cert_clear_errors(certs_cell_cert_t *obj) { int r = obj->trunnel_error_code_; obj->trunnel_error_code_ = 0; return r; } ssize_t certs_cell_cert_encode(uint8_t *output, const size_t avail, const certs_cell_cert_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 = certs_cell_cert_encoded_len(obj); #endif if (NULL != (msg = certs_cell_cert_check(obj))) goto check_failed; #ifdef TRUNNEL_CHECK_ENCODED_LEN trunnel_assert(encoded_len >= 0); #endif /* Encode u8 cert_type */ trunnel_assert(written <= avail); if (avail - written < 1) goto truncated; trunnel_set_uint8(ptr, (obj->cert_type)); written += 1; ptr += 1; /* Encode u16 cert_len */ trunnel_assert(written <= avail); if (avail - written < 2) goto truncated; trunnel_set_uint16(ptr, trunnel_htons(obj->cert_len)); written += 2; ptr += 2; /* Encode u8 body[cert_len] */ { size_t elt_len = TRUNNEL_DYNARRAY_LEN(&obj->body); trunnel_assert(obj->cert_len == elt_len); trunnel_assert(written <= avail); if (avail - written < elt_len) goto truncated; if (elt_len) memcpy(ptr, obj->body.elts_, elt_len); written += elt_len; ptr += elt_len; } 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 certs_cell_cert_parse(), but do not allocate the output object. */ static ssize_t certs_cell_cert_parse_into(certs_cell_cert_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 cert_type */ CHECK_REMAINING(1, truncated); obj->cert_type = (trunnel_get_uint8(ptr)); remaining -= 1; ptr += 1; /* Parse u16 cert_len */ CHECK_REMAINING(2, truncated); obj->cert_len = trunnel_ntohs(trunnel_get_uint16(ptr)); remaining -= 2; ptr += 2; /* Parse u8 body[cert_len] */ CHECK_REMAINING(obj->cert_len, truncated); TRUNNEL_DYNARRAY_EXPAND(uint8_t, &obj->body, obj->cert_len, {}); obj->body.n_ = obj->cert_len; if (obj->cert_len) memcpy(obj->body.elts_, ptr, obj->cert_len); ptr += obj->cert_len; remaining -= obj->cert_len; trunnel_assert(ptr + remaining == input + len_in); return len_in - remaining; truncated: return -2; trunnel_alloc_failed: return -1; } ssize_t certs_cell_cert_parse(certs_cell_cert_t **output, const uint8_t *input, const size_t len_in) { ssize_t result; *output = certs_cell_cert_new(); if (NULL == *output) return -1; result = certs_cell_cert_parse_into(*output, input, len_in); if (result < 0) { certs_cell_cert_free(*output); *output = NULL; } return result; } rsa_ed_crosscert_t * rsa_ed_crosscert_new(void) { rsa_ed_crosscert_t *val = trunnel_calloc(1, sizeof(rsa_ed_crosscert_t)); if (NULL == val) return NULL; return val; } /** Release all storage held inside 'obj', but do not free 'obj'. */ static void rsa_ed_crosscert_clear(rsa_ed_crosscert_t *obj) { (void) obj; TRUNNEL_DYNARRAY_WIPE(&obj->sig); TRUNNEL_DYNARRAY_CLEAR(&obj->sig); } void rsa_ed_crosscert_free(rsa_ed_crosscert_t *obj) { if (obj == NULL) return; rsa_ed_crosscert_clear(obj); trunnel_memwipe(obj, sizeof(rsa_ed_crosscert_t)); trunnel_free_(obj); } size_t rsa_ed_crosscert_getlen_ed_key(const rsa_ed_crosscert_t *inp) { (void)inp; return 32; } uint8_t rsa_ed_crosscert_get_ed_key(rsa_ed_crosscert_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->ed_key[idx]; } uint8_t rsa_ed_crosscert_getconst_ed_key(const rsa_ed_crosscert_t *inp, size_t idx) { return rsa_ed_crosscert_get_ed_key((rsa_ed_crosscert_t*)inp, idx); } int rsa_ed_crosscert_set_ed_key(rsa_ed_crosscert_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->ed_key[idx] = elt; return 0; } uint8_t * rsa_ed_crosscert_getarray_ed_key(rsa_ed_crosscert_t *inp) { return inp->ed_key; } const uint8_t * rsa_ed_crosscert_getconstarray_ed_key(const rsa_ed_crosscert_t *inp) { return (const uint8_t *)rsa_ed_crosscert_getarray_ed_key((rsa_ed_crosscert_t*)inp); } uint32_t rsa_ed_crosscert_get_expiration(const rsa_ed_crosscert_t *inp) { return inp->expiration; } int rsa_ed_crosscert_set_expiration(rsa_ed_crosscert_t *inp, uint32_t val) { inp->expiration = val; return 0; } const uint8_t * rsa_ed_crosscert_get_end_of_signed(const rsa_ed_crosscert_t *inp) { return inp->end_of_signed; } uint8_t rsa_ed_crosscert_get_sig_len(const rsa_ed_crosscert_t *inp) { return inp->sig_len; } int rsa_ed_crosscert_set_sig_len(rsa_ed_crosscert_t *inp, uint8_t val) { inp->sig_len = val; return 0; } size_t rsa_ed_crosscert_getlen_sig(const rsa_ed_crosscert_t *inp) { return TRUNNEL_DYNARRAY_LEN(&inp->sig); } uint8_t rsa_ed_crosscert_get_sig(rsa_ed_crosscert_t *inp, size_t idx) { return TRUNNEL_DYNARRAY_GET(&inp->sig, idx); } uint8_t rsa_ed_crosscert_getconst_sig(const rsa_ed_crosscert_t *inp, size_t idx) { return rsa_ed_crosscert_get_sig((rsa_ed_crosscert_t*)inp, idx); } int rsa_ed_crosscert_set_sig(rsa_ed_crosscert_t *inp, size_t idx, uint8_t elt) { TRUNNEL_DYNARRAY_SET(&inp->sig, idx, elt); return 0; } int rsa_ed_crosscert_add_sig(rsa_ed_crosscert_t *inp, uint8_t elt) { #if SIZE_MAX >= UINT8_MAX if (inp->sig.n_ == UINT8_MAX) goto trunnel_alloc_failed; #endif TRUNNEL_DYNARRAY_ADD(uint8_t, &inp->sig, elt, {}); return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } uint8_t * rsa_ed_crosscert_getarray_sig(rsa_ed_crosscert_t *inp) { return inp->sig.elts_; } const uint8_t * rsa_ed_crosscert_getconstarray_sig(const rsa_ed_crosscert_t *inp) { return (const uint8_t *)rsa_ed_crosscert_getarray_sig((rsa_ed_crosscert_t*)inp); } int rsa_ed_crosscert_setlen_sig(rsa_ed_crosscert_t *inp, size_t newlen) { uint8_t *newptr; #if UINT8_MAX < SIZE_MAX if (newlen > UINT8_MAX) goto trunnel_alloc_failed; #endif newptr = trunnel_dynarray_setlen(&inp->sig.allocated_, &inp->sig.n_, inp->sig.elts_, newlen, sizeof(inp->sig.elts_[0]), (trunnel_free_fn_t) NULL, &inp->trunnel_error_code_); if (newlen != 0 && newptr == NULL) goto trunnel_alloc_failed; inp->sig.elts_ = newptr; return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } const char * rsa_ed_crosscert_check(const rsa_ed_crosscert_t *obj) { if (obj == NULL) return "Object was NULL"; if (obj->trunnel_error_code_) return "A set function failed on this object"; if (TRUNNEL_DYNARRAY_LEN(&obj->sig) != obj->sig_len) return "Length mismatch for sig"; return NULL; } ssize_t rsa_ed_crosscert_encoded_len(const rsa_ed_crosscert_t *obj) { ssize_t result = 0; if (NULL != rsa_ed_crosscert_check(obj)) return -1; /* Length of u8 ed_key[32] */ result += 32; /* Length of u32 expiration */ result += 4; /* Length of u8 sig_len */ result += 1; /* Length of u8 sig[sig_len] */ result += TRUNNEL_DYNARRAY_LEN(&obj->sig); return result; } int rsa_ed_crosscert_clear_errors(rsa_ed_crosscert_t *obj) { int r = obj->trunnel_error_code_; obj->trunnel_error_code_ = 0; return r; } ssize_t rsa_ed_crosscert_encode(uint8_t *output, const size_t avail, const rsa_ed_crosscert_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 = rsa_ed_crosscert_encoded_len(obj); #endif if (NULL != (msg = rsa_ed_crosscert_check(obj))) goto check_failed; #ifdef TRUNNEL_CHECK_ENCODED_LEN trunnel_assert(encoded_len >= 0); #endif /* Encode u8 ed_key[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->ed_key, 32); written += 32; ptr += 32; /* Encode u32 expiration */ trunnel_assert(written <= avail); if (avail - written < 4) goto truncated; trunnel_set_uint32(ptr, trunnel_htonl(obj->expiration)); written += 4; ptr += 4; /* Encode u8 sig_len */ trunnel_assert(written <= avail); if (avail - written < 1) goto truncated; trunnel_set_uint8(ptr, (obj->sig_len)); written += 1; ptr += 1; /* Encode u8 sig[sig_len] */ { size_t elt_len = TRUNNEL_DYNARRAY_LEN(&obj->sig); trunnel_assert(obj->sig_len == elt_len); trunnel_assert(written <= avail); if (avail - written < elt_len) goto truncated; if (elt_len) memcpy(ptr, obj->sig.elts_, elt_len); written += elt_len; ptr += elt_len; } 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 rsa_ed_crosscert_parse(), but do not allocate the output * object. */ static ssize_t rsa_ed_crosscert_parse_into(rsa_ed_crosscert_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 ed_key[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->ed_key, ptr, 32); remaining -= 32; ptr += 32; /* Parse u32 expiration */ CHECK_REMAINING(4, truncated); obj->expiration = trunnel_ntohl(trunnel_get_uint32(ptr)); remaining -= 4; ptr += 4; obj->end_of_signed = ptr; /* Parse u8 sig_len */ CHECK_REMAINING(1, truncated); obj->sig_len = (trunnel_get_uint8(ptr)); remaining -= 1; ptr += 1; /* Parse u8 sig[sig_len] */ CHECK_REMAINING(obj->sig_len, truncated); TRUNNEL_DYNARRAY_EXPAND(uint8_t, &obj->sig, obj->sig_len, {}); obj->sig.n_ = obj->sig_len; if (obj->sig_len) memcpy(obj->sig.elts_, ptr, obj->sig_len); ptr += obj->sig_len; remaining -= obj->sig_len; trunnel_assert(ptr + remaining == input + len_in); return len_in - remaining; truncated: return -2; trunnel_alloc_failed: return -1; } ssize_t rsa_ed_crosscert_parse(rsa_ed_crosscert_t **output, const uint8_t *input, const size_t len_in) { ssize_t result; *output = rsa_ed_crosscert_new(); if (NULL == *output) return -1; result = rsa_ed_crosscert_parse_into(*output, input, len_in); if (result < 0) { rsa_ed_crosscert_free(*output); *output = NULL; } return result; } auth1_t * auth1_new(void) { auth1_t *val = trunnel_calloc(1, sizeof(auth1_t)); if (NULL == val) return NULL; return val; } /** Release all storage held inside 'obj', but do not free 'obj'. */ static void auth1_clear(auth1_t *obj) { (void) obj; TRUNNEL_DYNARRAY_WIPE(&obj->sig); TRUNNEL_DYNARRAY_CLEAR(&obj->sig); } void auth1_free(auth1_t *obj) { if (obj == NULL) return; auth1_clear(obj); trunnel_memwipe(obj, sizeof(auth1_t)); trunnel_free_(obj); } size_t auth1_getlen_type(const auth1_t *inp) { (void)inp; return 8; } uint8_t auth1_get_type(auth1_t *inp, size_t idx) { trunnel_assert(idx < 8); return inp->type[idx]; } uint8_t auth1_getconst_type(const auth1_t *inp, size_t idx) { return auth1_get_type((auth1_t*)inp, idx); } int auth1_set_type(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 8); inp->type[idx] = elt; return 0; } uint8_t * auth1_getarray_type(auth1_t *inp) { return inp->type; } const uint8_t * auth1_getconstarray_type(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_type((auth1_t*)inp); } size_t auth1_getlen_cid(const auth1_t *inp) { (void)inp; return 32; } uint8_t auth1_get_cid(auth1_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->cid[idx]; } uint8_t auth1_getconst_cid(const auth1_t *inp, size_t idx) { return auth1_get_cid((auth1_t*)inp, idx); } int auth1_set_cid(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->cid[idx] = elt; return 0; } uint8_t * auth1_getarray_cid(auth1_t *inp) { return inp->cid; } const uint8_t * auth1_getconstarray_cid(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_cid((auth1_t*)inp); } size_t auth1_getlen_sid(const auth1_t *inp) { (void)inp; return 32; } uint8_t auth1_get_sid(auth1_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->sid[idx]; } uint8_t auth1_getconst_sid(const auth1_t *inp, size_t idx) { return auth1_get_sid((auth1_t*)inp, idx); } int auth1_set_sid(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->sid[idx] = elt; return 0; } uint8_t * auth1_getarray_sid(auth1_t *inp) { return inp->sid; } const uint8_t * auth1_getconstarray_sid(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_sid((auth1_t*)inp); } size_t auth1_getlen_u1_cid_ed(const auth1_t *inp) { (void)inp; return 32; } uint8_t auth1_get_u1_cid_ed(auth1_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->u1_cid_ed[idx]; } uint8_t auth1_getconst_u1_cid_ed(const auth1_t *inp, size_t idx) { return auth1_get_u1_cid_ed((auth1_t*)inp, idx); } int auth1_set_u1_cid_ed(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->u1_cid_ed[idx] = elt; return 0; } uint8_t * auth1_getarray_u1_cid_ed(auth1_t *inp) { return inp->u1_cid_ed; } const uint8_t * auth1_getconstarray_u1_cid_ed(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_u1_cid_ed((auth1_t*)inp); } size_t auth1_getlen_u1_sid_ed(const auth1_t *inp) { (void)inp; return 32; } uint8_t auth1_get_u1_sid_ed(auth1_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->u1_sid_ed[idx]; } uint8_t auth1_getconst_u1_sid_ed(const auth1_t *inp, size_t idx) { return auth1_get_u1_sid_ed((auth1_t*)inp, idx); } int auth1_set_u1_sid_ed(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->u1_sid_ed[idx] = elt; return 0; } uint8_t * auth1_getarray_u1_sid_ed(auth1_t *inp) { return inp->u1_sid_ed; } const uint8_t * auth1_getconstarray_u1_sid_ed(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_u1_sid_ed((auth1_t*)inp); } size_t auth1_getlen_slog(const auth1_t *inp) { (void)inp; return 32; } uint8_t auth1_get_slog(auth1_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->slog[idx]; } uint8_t auth1_getconst_slog(const auth1_t *inp, size_t idx) { return auth1_get_slog((auth1_t*)inp, idx); } int auth1_set_slog(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->slog[idx] = elt; return 0; } uint8_t * auth1_getarray_slog(auth1_t *inp) { return inp->slog; } const uint8_t * auth1_getconstarray_slog(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_slog((auth1_t*)inp); } size_t auth1_getlen_clog(const auth1_t *inp) { (void)inp; return 32; } uint8_t auth1_get_clog(auth1_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->clog[idx]; } uint8_t auth1_getconst_clog(const auth1_t *inp, size_t idx) { return auth1_get_clog((auth1_t*)inp, idx); } int auth1_set_clog(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->clog[idx] = elt; return 0; } uint8_t * auth1_getarray_clog(auth1_t *inp) { return inp->clog; } const uint8_t * auth1_getconstarray_clog(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_clog((auth1_t*)inp); } size_t auth1_getlen_scert(const auth1_t *inp) { (void)inp; return 32; } uint8_t auth1_get_scert(auth1_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->scert[idx]; } uint8_t auth1_getconst_scert(const auth1_t *inp, size_t idx) { return auth1_get_scert((auth1_t*)inp, idx); } int auth1_set_scert(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->scert[idx] = elt; return 0; } uint8_t * auth1_getarray_scert(auth1_t *inp) { return inp->scert; } const uint8_t * auth1_getconstarray_scert(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_scert((auth1_t*)inp); } size_t auth1_getlen_tlssecrets(const auth1_t *inp) { (void)inp; return 32; } uint8_t auth1_get_tlssecrets(auth1_t *inp, size_t idx) { trunnel_assert(idx < 32); return inp->tlssecrets[idx]; } uint8_t auth1_getconst_tlssecrets(const auth1_t *inp, size_t idx) { return auth1_get_tlssecrets((auth1_t*)inp, idx); } int auth1_set_tlssecrets(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 32); inp->tlssecrets[idx] = elt; return 0; } uint8_t * auth1_getarray_tlssecrets(auth1_t *inp) { return inp->tlssecrets; } const uint8_t * auth1_getconstarray_tlssecrets(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_tlssecrets((auth1_t*)inp); } const uint8_t * auth1_get_end_of_fixed_part(const auth1_t *inp) { return inp->end_of_fixed_part; } size_t auth1_getlen_rand(const auth1_t *inp) { (void)inp; return 24; } uint8_t auth1_get_rand(auth1_t *inp, size_t idx) { trunnel_assert(idx < 24); return inp->rand[idx]; } uint8_t auth1_getconst_rand(const auth1_t *inp, size_t idx) { return auth1_get_rand((auth1_t*)inp, idx); } int auth1_set_rand(auth1_t *inp, size_t idx, uint8_t elt) { trunnel_assert(idx < 24); inp->rand[idx] = elt; return 0; } uint8_t * auth1_getarray_rand(auth1_t *inp) { return inp->rand; } const uint8_t * auth1_getconstarray_rand(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_rand((auth1_t*)inp); } const uint8_t * auth1_get_end_of_signed(const auth1_t *inp) { return inp->end_of_signed; } size_t auth1_getlen_sig(const auth1_t *inp) { return TRUNNEL_DYNARRAY_LEN(&inp->sig); } uint8_t auth1_get_sig(auth1_t *inp, size_t idx) { return TRUNNEL_DYNARRAY_GET(&inp->sig, idx); } uint8_t auth1_getconst_sig(const auth1_t *inp, size_t idx) { return auth1_get_sig((auth1_t*)inp, idx); } int auth1_set_sig(auth1_t *inp, size_t idx, uint8_t elt) { TRUNNEL_DYNARRAY_SET(&inp->sig, idx, elt); return 0; } int auth1_add_sig(auth1_t *inp, uint8_t elt) { TRUNNEL_DYNARRAY_ADD(uint8_t, &inp->sig, elt, {}); return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } uint8_t * auth1_getarray_sig(auth1_t *inp) { return inp->sig.elts_; } const uint8_t * auth1_getconstarray_sig(const auth1_t *inp) { return (const uint8_t *)auth1_getarray_sig((auth1_t*)inp); } int auth1_setlen_sig(auth1_t *inp, size_t newlen) { uint8_t *newptr; newptr = trunnel_dynarray_setlen(&inp->sig.allocated_, &inp->sig.n_, inp->sig.elts_, newlen, sizeof(inp->sig.elts_[0]), (trunnel_free_fn_t) NULL, &inp->trunnel_error_code_); if (newlen != 0 && newptr == NULL) goto trunnel_alloc_failed; inp->sig.elts_ = newptr; return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } const char * auth1_check(const auth1_t *obj, const auth_ctx_t *auth_ctx_ctx) { if (obj == NULL) return "Object was NULL"; if (obj->trunnel_error_code_) return "A set function failed on this object"; if (auth_ctx_ctx == NULL) return "Context was NULL"; switch (auth_ctx_ctx->is_ed) { case 0: break; case 1: break; default: return "Bad tag for union"; break; } return NULL; } ssize_t auth1_encoded_len(const auth1_t *obj, const auth_ctx_t *auth_ctx_ctx) { ssize_t result = 0; if (NULL != auth1_check(obj, auth_ctx_ctx)) return -1; /* Length of u8 type[8] */ result += 8; /* Length of u8 cid[32] */ result += 32; /* Length of u8 sid[32] */ result += 32; switch (auth_ctx_ctx->is_ed) { case 0: break; case 1: /* Length of u8 u1_cid_ed[32] */ result += 32; /* Length of u8 u1_sid_ed[32] */ result += 32; break; default: trunnel_assert(0); break; } /* Length of u8 slog[32] */ result += 32; /* Length of u8 clog[32] */ result += 32; /* Length of u8 scert[32] */ result += 32; /* Length of u8 tlssecrets[32] */ result += 32; /* Length of u8 rand[24] */ result += 24; /* Length of u8 sig[] */ result += TRUNNEL_DYNARRAY_LEN(&obj->sig); return result; } int auth1_clear_errors(auth1_t *obj) { int r = obj->trunnel_error_code_; obj->trunnel_error_code_ = 0; return r; } ssize_t auth1_encode(uint8_t *output, const size_t avail, const auth1_t *obj, const auth_ctx_t *auth_ctx_ctx) { 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 = auth1_encoded_len(obj, auth_ctx_ctx); #endif if (NULL != (msg = auth1_check(obj, auth_ctx_ctx))) goto check_failed; #ifdef TRUNNEL_CHECK_ENCODED_LEN trunnel_assert(encoded_len >= 0); #endif /* Encode u8 type[8] */ trunnel_assert(written <= avail); if (avail - written < 8) goto truncated; memcpy(ptr, obj->type, 8); written += 8; ptr += 8; /* Encode u8 cid[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->cid, 32); written += 32; ptr += 32; /* Encode u8 sid[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->sid, 32); written += 32; ptr += 32; /* Encode union u1[auth_ctx.is_ed] */ trunnel_assert(written <= avail); switch (auth_ctx_ctx->is_ed) { case 0: break; case 1: /* Encode u8 u1_cid_ed[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->u1_cid_ed, 32); written += 32; ptr += 32; /* Encode u8 u1_sid_ed[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->u1_sid_ed, 32); written += 32; ptr += 32; break; default: trunnel_assert(0); break; } /* Encode u8 slog[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->slog, 32); written += 32; ptr += 32; /* Encode u8 clog[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->clog, 32); written += 32; ptr += 32; /* Encode u8 scert[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->scert, 32); written += 32; ptr += 32; /* Encode u8 tlssecrets[32] */ trunnel_assert(written <= avail); if (avail - written < 32) goto truncated; memcpy(ptr, obj->tlssecrets, 32); written += 32; ptr += 32; /* Encode u8 rand[24] */ trunnel_assert(written <= avail); if (avail - written < 24) goto truncated; memcpy(ptr, obj->rand, 24); written += 24; ptr += 24; /* Encode u8 sig[] */ { size_t elt_len = TRUNNEL_DYNARRAY_LEN(&obj->sig); trunnel_assert(written <= avail); if (avail - written < elt_len) goto truncated; if (elt_len) memcpy(ptr, obj->sig.elts_, elt_len); written += elt_len; ptr += elt_len; } 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 auth1_parse(), but do not allocate the output object. */ static ssize_t auth1_parse_into(auth1_t *obj, const uint8_t *input, const size_t len_in, const auth_ctx_t *auth_ctx_ctx) { const uint8_t *ptr = input; size_t remaining = len_in; ssize_t result = 0; (void)result; if (auth_ctx_ctx == NULL) return -1; /* Parse u8 type[8] */ CHECK_REMAINING(8, truncated); memcpy(obj->type, ptr, 8); remaining -= 8; ptr += 8; /* Parse u8 cid[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->cid, ptr, 32); remaining -= 32; ptr += 32; /* Parse u8 sid[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->sid, ptr, 32); remaining -= 32; ptr += 32; /* Parse union u1[auth_ctx.is_ed] */ switch (auth_ctx_ctx->is_ed) { case 0: break; case 1: /* Parse u8 u1_cid_ed[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->u1_cid_ed, ptr, 32); remaining -= 32; ptr += 32; /* Parse u8 u1_sid_ed[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->u1_sid_ed, ptr, 32); remaining -= 32; ptr += 32; break; default: goto fail; break; } /* Parse u8 slog[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->slog, ptr, 32); remaining -= 32; ptr += 32; /* Parse u8 clog[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->clog, ptr, 32); remaining -= 32; ptr += 32; /* Parse u8 scert[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->scert, ptr, 32); remaining -= 32; ptr += 32; /* Parse u8 tlssecrets[32] */ CHECK_REMAINING(32, truncated); memcpy(obj->tlssecrets, ptr, 32); remaining -= 32; ptr += 32; obj->end_of_fixed_part = ptr; /* Parse u8 rand[24] */ CHECK_REMAINING(24, truncated); memcpy(obj->rand, ptr, 24); remaining -= 24; ptr += 24; obj->end_of_signed = ptr; /* Parse u8 sig[] */ TRUNNEL_DYNARRAY_EXPAND(uint8_t, &obj->sig, remaining, {}); obj->sig.n_ = remaining; if (remaining) memcpy(obj->sig.elts_, ptr, remaining); ptr += remaining; remaining -= remaining; trunnel_assert(ptr + remaining == input + len_in); return len_in - remaining; truncated: return -2; trunnel_alloc_failed: return -1; fail: result = -1; return result; } ssize_t auth1_parse(auth1_t **output, const uint8_t *input, const size_t len_in, const auth_ctx_t *auth_ctx_ctx) { ssize_t result; *output = auth1_new(); if (NULL == *output) return -1; result = auth1_parse_into(*output, input, len_in, auth_ctx_ctx); if (result < 0) { auth1_free(*output); *output = NULL; } return result; } certs_cell_t * certs_cell_new(void) { certs_cell_t *val = trunnel_calloc(1, sizeof(certs_cell_t)); if (NULL == val) return NULL; return val; } /** Release all storage held inside 'obj', but do not free 'obj'. */ static void certs_cell_clear(certs_cell_t *obj) { (void) obj; { unsigned idx; for (idx = 0; idx < TRUNNEL_DYNARRAY_LEN(&obj->certs); ++idx) { certs_cell_cert_free(TRUNNEL_DYNARRAY_GET(&obj->certs, idx)); } } TRUNNEL_DYNARRAY_WIPE(&obj->certs); TRUNNEL_DYNARRAY_CLEAR(&obj->certs); } void certs_cell_free(certs_cell_t *obj) { if (obj == NULL) return; certs_cell_clear(obj); trunnel_memwipe(obj, sizeof(certs_cell_t)); trunnel_free_(obj); } uint8_t certs_cell_get_n_certs(const certs_cell_t *inp) { return inp->n_certs; } int certs_cell_set_n_certs(certs_cell_t *inp, uint8_t val) { inp->n_certs = val; return 0; } size_t certs_cell_getlen_certs(const certs_cell_t *inp) { return TRUNNEL_DYNARRAY_LEN(&inp->certs); } struct certs_cell_cert_st * certs_cell_get_certs(certs_cell_t *inp, size_t idx) { return TRUNNEL_DYNARRAY_GET(&inp->certs, idx); } const struct certs_cell_cert_st * certs_cell_getconst_certs(const certs_cell_t *inp, size_t idx) { return certs_cell_get_certs((certs_cell_t*)inp, idx); } int certs_cell_set_certs(certs_cell_t *inp, size_t idx, struct certs_cell_cert_st * elt) { certs_cell_cert_t *oldval = TRUNNEL_DYNARRAY_GET(&inp->certs, idx); if (oldval && oldval != elt) certs_cell_cert_free(oldval); return certs_cell_set0_certs(inp, idx, elt); } int certs_cell_set0_certs(certs_cell_t *inp, size_t idx, struct certs_cell_cert_st * elt) { TRUNNEL_DYNARRAY_SET(&inp->certs, idx, elt); return 0; } int certs_cell_add_certs(certs_cell_t *inp, struct certs_cell_cert_st * elt) { #if SIZE_MAX >= UINT8_MAX if (inp->certs.n_ == UINT8_MAX) goto trunnel_alloc_failed; #endif TRUNNEL_DYNARRAY_ADD(struct certs_cell_cert_st *, &inp->certs, elt, {}); return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } struct certs_cell_cert_st * * certs_cell_getarray_certs(certs_cell_t *inp) { return inp->certs.elts_; } const struct certs_cell_cert_st * const * certs_cell_getconstarray_certs(const certs_cell_t *inp) { return (const struct certs_cell_cert_st * const *)certs_cell_getarray_certs((certs_cell_t*)inp); } int certs_cell_setlen_certs(certs_cell_t *inp, size_t newlen) { struct certs_cell_cert_st * *newptr; #if UINT8_MAX < SIZE_MAX if (newlen > UINT8_MAX) goto trunnel_alloc_failed; #endif newptr = trunnel_dynarray_setlen(&inp->certs.allocated_, &inp->certs.n_, inp->certs.elts_, newlen, sizeof(inp->certs.elts_[0]), (trunnel_free_fn_t) certs_cell_cert_free, &inp->trunnel_error_code_); if (newlen != 0 && newptr == NULL) goto trunnel_alloc_failed; inp->certs.elts_ = newptr; return 0; trunnel_alloc_failed: TRUNNEL_SET_ERROR_CODE(inp); return -1; } const char * certs_cell_check(const certs_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; unsigned idx; for (idx = 0; idx < TRUNNEL_DYNARRAY_LEN(&obj->certs); ++idx) { if (NULL != (msg = certs_cell_cert_check(TRUNNEL_DYNARRAY_GET(&obj->certs, idx)))) return msg; } } if (TRUNNEL_DYNARRAY_LEN(&obj->certs) != obj->n_certs) return "Length mismatch for certs"; return NULL; } ssize_t certs_cell_encoded_len(const certs_cell_t *obj) { ssize_t result = 0; if (NULL != certs_cell_check(obj)) return -1; /* Length of u8 n_certs */ result += 1; /* Length of struct certs_cell_cert certs[n_certs] */ { unsigned idx; for (idx = 0; idx < TRUNNEL_DYNARRAY_LEN(&obj->certs); ++idx) { result += certs_cell_cert_encoded_len(TRUNNEL_DYNARRAY_GET(&obj->certs, idx)); } } return result; } int certs_cell_clear_errors(certs_cell_t *obj) { int r = obj->trunnel_error_code_; obj->trunnel_error_code_ = 0; return r; } ssize_t certs_cell_encode(uint8_t *output, const size_t avail, const certs_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 = certs_cell_encoded_len(obj); #endif if (NULL != (msg = certs_cell_check(obj))) goto check_failed; #ifdef TRUNNEL_CHECK_ENCODED_LEN trunnel_assert(encoded_len >= 0); #endif /* Encode u8 n_certs */ trunnel_assert(written <= avail); if (avail - written < 1) goto truncated; trunnel_set_uint8(ptr, (obj->n_certs)); written += 1; ptr += 1; /* Encode struct certs_cell_cert certs[n_certs] */ { unsigned idx; for (idx = 0; idx < TRUNNEL_DYNARRAY_LEN(&obj->certs); ++idx) { trunnel_assert(written <= avail); result = certs_cell_cert_encode(ptr, avail - written, TRUNNEL_DYNARRAY_GET(&obj->certs, 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 certs_cell_parse(), but do not allocate the output object. */ static ssize_t certs_cell_parse_into(certs_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 u8 n_certs */ CHECK_REMAINING(1, truncated); obj->n_certs = (trunnel_get_uint8(ptr)); remaining -= 1; ptr += 1; /* Parse struct certs_cell_cert certs[n_certs] */ TRUNNEL_DYNARRAY_EXPAND(certs_cell_cert_t *, &obj->certs, obj->n_certs, {}); { certs_cell_cert_t * elt; unsigned idx; for (idx = 0; idx < obj->n_certs; ++idx) { result = certs_cell_cert_parse(&elt, ptr, remaining); if (result < 0) goto relay_fail; trunnel_assert((size_t)result <= remaining); remaining -= result; ptr += result; TRUNNEL_DYNARRAY_ADD(certs_cell_cert_t *, &obj->certs, elt, {certs_cell_cert_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 certs_cell_parse(certs_cell_t **output, const uint8_t *input, const size_t len_in) { ssize_t result; *output = certs_cell_new(); if (NULL == *output) return -1; result = certs_cell_parse_into(*output, input, len_in); if (result < 0) { certs_cell_free(*output); *output = NULL; } return result; }