/* * Copyright 2016-2017 The OpenSSL Project Authors. All Rights Reserved. * * Licensed under the OpenSSL license (the "License"). You may not use * this file except in compliance with the License. You can obtain a copy * in the file LICENSE in the source distribution or at * https://www.openssl.org/source/license.html */ #include "e_os.h" #include #include #include #include #include /* For d2i_DSAPrivateKey */ #include #include #include #include /* For the PKCS8 stuff o.O */ #include /* For d2i_RSAPrivateKey */ #include #include #include #include /* For the PKCS8 stuff o.O */ #include "internal/asn1_int.h" #include "internal/ctype.h" #include "internal/o_dir.h" #include "internal/cryptlib.h" #include "internal/store_int.h" #include "store_locl.h" #ifdef _WIN32 # define stat _stat #endif /*- * Password prompting * ------------------ */ static char *file_get_pass(const UI_METHOD *ui_method, char *pass, size_t maxsize, const char *prompt_info, void *data) { UI *ui = UI_new(); char *prompt = NULL; if (ui == NULL) { OSSL_STOREerr(OSSL_STORE_F_FILE_GET_PASS, ERR_R_MALLOC_FAILURE); return NULL; } if (ui_method != NULL) UI_set_method(ui, ui_method); UI_add_user_data(ui, data); if ((prompt = UI_construct_prompt(ui, "pass phrase", prompt_info)) == NULL) { OSSL_STOREerr(OSSL_STORE_F_FILE_GET_PASS, ERR_R_MALLOC_FAILURE); pass = NULL; } else if (!UI_add_input_string(ui, prompt, UI_INPUT_FLAG_DEFAULT_PWD, pass, 0, maxsize - 1)) { OSSL_STOREerr(OSSL_STORE_F_FILE_GET_PASS, ERR_R_UI_LIB); pass = NULL; } else { switch (UI_process(ui)) { case -2: OSSL_STOREerr(OSSL_STORE_F_FILE_GET_PASS, OSSL_STORE_R_UI_PROCESS_INTERRUPTED_OR_CANCELLED); pass = NULL; break; case -1: OSSL_STOREerr(OSSL_STORE_F_FILE_GET_PASS, ERR_R_UI_LIB); pass = NULL; break; default: break; } } OPENSSL_free(prompt); UI_free(ui); return pass; } struct pem_pass_data { const UI_METHOD *ui_method; void *data; const char *prompt_info; }; static int file_fill_pem_pass_data(struct pem_pass_data *pass_data, const char *prompt_info, const UI_METHOD *ui_method, void *ui_data) { if (pass_data == NULL) return 0; pass_data->ui_method = ui_method; pass_data->data = ui_data; pass_data->prompt_info = prompt_info; return 1; } /* This is used anywhere a pem_password_cb is needed */ static int file_get_pem_pass(char *buf, int num, int w, void *data) { struct pem_pass_data *pass_data = data; char *pass = file_get_pass(pass_data->ui_method, buf, num, pass_data->prompt_info, pass_data->data); return pass == NULL ? 0 : strlen(pass); } /*- * The file scheme decoders * ------------------------ * * Each possible data type has its own decoder, which either operates * through a given PEM name, or attempts to decode to see if the blob * it's given is decodable for its data type. The assumption is that * only the correct data type will match the content. */ /*- * The try_decode function is called to check if the blob of data can * be used by this handler, and if it can, decodes it into a supported * OpenSSL type and returns a OSSL_STORE_INFO with the decoded data. * Input: * pem_name: If this blob comes from a PEM file, this holds * the PEM name. If it comes from another type of * file, this is NULL. * pem_header: If this blob comes from a PEM file, this holds * the PEM headers. If it comes from another type of * file, this is NULL. * blob: The blob of data to match with what this handler * can use. * len: The length of the blob. * handler_ctx: For a handler marked repeatable, this pointer can * be used to create a context for the handler. IT IS * THE HANDLER'S RESPONSIBILITY TO CREATE AND DESTROY * THIS CONTEXT APPROPRIATELY, i.e. create on first call * and destroy when about to return NULL. * matchcount: A pointer to an int to count matches for this data. * Usually becomes 0 (no match) or 1 (match!), but may * be higher in the (unlikely) event that the data matches * more than one possibility. The int will always be * zero when the function is called. * ui_method: Application UI method for getting a password, pin * or any other interactive data. * ui_data: Application data to be passed to ui_method when * it's called. * Output: * a OSSL_STORE_INFO */ typedef OSSL_STORE_INFO *(*file_try_decode_fn)(const char *pem_name, const char *pem_header, const unsigned char *blob, size_t len, void **handler_ctx, int *matchcount, const UI_METHOD *ui_method, void *ui_data); /* * The eof function should return 1 if there's no more data to be found * with the handler_ctx, otherwise 0. This is only used when the handler is * marked repeatable. */ typedef int (*file_eof_fn)(void *handler_ctx); /* * The destroy_ctx function is used to destroy the handler_ctx that was * intiated by a repeatable try_decode fuction. This is only used when * the handler is marked repeatable. */ typedef void (*file_destroy_ctx_fn)(void **handler_ctx); typedef struct file_handler_st { const char *name; file_try_decode_fn try_decode; file_eof_fn eof; file_destroy_ctx_fn destroy_ctx; /* flags */ int repeatable; } FILE_HANDLER; /* * PKCS#12 decoder. It operates by decoding all of the blob content, * extracting all the interesting data from it and storing them internally, * then serving them one piece at a time. */ static OSSL_STORE_INFO *try_decode_PKCS12(const char *pem_name, const char *pem_header, const unsigned char *blob, size_t len, void **pctx, int *matchcount, const UI_METHOD *ui_method, void *ui_data) { OSSL_STORE_INFO *store_info = NULL; STACK_OF(OSSL_STORE_INFO) *ctx = *pctx; if (ctx == NULL) { /* Initial parsing */ PKCS12 *p12; int ok = 0; if (pem_name != NULL) /* No match, there is no PEM PKCS12 tag */ return NULL; if ((p12 = d2i_PKCS12(NULL, &blob, len)) != NULL) { char *pass = NULL; char tpass[PEM_BUFSIZE]; EVP_PKEY *pkey = NULL; X509 *cert = NULL; STACK_OF(X509) *chain = NULL; *matchcount = 1; if (PKCS12_verify_mac(p12, "", 0) || PKCS12_verify_mac(p12, NULL, 0)) { pass = ""; } else { if ((pass = file_get_pass(ui_method, tpass, PEM_BUFSIZE, "PKCS12 import password", ui_data)) == NULL) { OSSL_STOREerr(OSSL_STORE_F_TRY_DECODE_PKCS12, OSSL_STORE_R_PASSPHRASE_CALLBACK_ERROR); goto p12_end; } if (!PKCS12_verify_mac(p12, pass, strlen(pass))) { OSSL_STOREerr(OSSL_STORE_F_TRY_DECODE_PKCS12, OSSL_STORE_R_ERROR_VERIFYING_PKCS12_MAC); goto p12_end; } } if (PKCS12_parse(p12, pass, &pkey, &cert, &chain)) { OSSL_STORE_INFO *si_pkey = NULL; OSSL_STORE_INFO *si_cert = NULL; OSSL_STORE_INFO *si_ca = NULL; if ((ctx = sk_OSSL_STORE_INFO_new_null()) != NULL && (si_pkey = OSSL_STORE_INFO_new_PKEY(pkey)) != NULL && sk_OSSL_STORE_INFO_push(ctx, si_pkey) != 0 && (si_cert = OSSL_STORE_INFO_new_CERT(cert)) != NULL && sk_OSSL_STORE_INFO_push(ctx, si_cert) != 0) { ok = 1; si_pkey = NULL; si_cert = NULL; while(sk_X509_num(chain) > 0) { X509 *ca = sk_X509_value(chain, 0); if ((si_ca = OSSL_STORE_INFO_new_CERT(ca)) == NULL || sk_OSSL_STORE_INFO_push(ctx, si_ca) == 0) { ok = 0; break; } si_ca = NULL; (void)sk_X509_shift(chain); } } if (!ok) { OSSL_STORE_INFO_free(si_ca); OSSL_STORE_INFO_free(si_cert); OSSL_STORE_INFO_free(si_pkey); sk_OSSL_STORE_INFO_pop_free(ctx, OSSL_STORE_INFO_free); EVP_PKEY_free(pkey); X509_free(cert); sk_X509_pop_free(chain, X509_free); ctx = NULL; } *pctx = ctx; } } p12_end: PKCS12_free(p12); if (!ok) return NULL; } if (ctx != NULL) { *matchcount = 1; store_info = sk_OSSL_STORE_INFO_shift(ctx); } return store_info; } static int eof_PKCS12(void *ctx_) { STACK_OF(OSSL_STORE_INFO) *ctx = ctx_; return ctx == NULL || sk_OSSL_STORE_INFO_num(ctx) == 0; } static void destroy_ctx_PKCS12(void **pctx) { STACK_OF(OSSL_STORE_INFO) *ctx = *pctx; sk_OSSL_STORE_INFO_pop_free(ctx, OSSL_STORE_INFO_free); *pctx = NULL; } static FILE_HANDLER PKCS12_handler = { "PKCS12", try_decode_PKCS12, eof_PKCS12, destroy_ctx_PKCS12, 1 /* repeatable */ }; /* * Encrypted PKCS#8 decoder. It operates by just decrypting the given blob * into a new blob, which is returned as an EMBEDDED STORE_INFO. The whole * decoding process will then start over with the new blob. */ static OSSL_STORE_INFO *try_decode_PKCS8Encrypted(const char *pem_name, const char *pem_header, const unsigned char *blob, size_t len, void **pctx, int *matchcount, const UI_METHOD *ui_method, void *ui_data) { X509_SIG *p8 = NULL; char kbuf[PEM_BUFSIZE]; char *pass = NULL; const X509_ALGOR *dalg = NULL; const ASN1_OCTET_STRING *doct = NULL; OSSL_STORE_INFO *store_info = NULL; BUF_MEM *mem = NULL; unsigned char *new_data = NULL; int new_data_len; if (pem_name != NULL) { if (strcmp(pem_name, PEM_STRING_PKCS8) != 0) return NULL; *matchcount = 1; } if ((p8 = d2i_X509_SIG(NULL, &blob, len)) == NULL) return NULL; *matchcount = 1; if ((mem = BUF_MEM_new()) == NULL) { OSSL_STOREerr(OSSL_STORE_F_TRY_DECODE_PKCS8ENCRYPTED, ERR_R_MALLOC_FAILURE); goto nop8; } if ((pass = file_get_pass(ui_method, kbuf, PEM_BUFSIZE, "PKCS8 decrypt password", ui_data)) == NULL) { OSSL_STOREerr(OSSL_STORE_F_TRY_DECODE_PKCS8ENCRYPTED, OSSL_STORE_R_BAD_PASSWORD_READ); goto nop8; } X509_SIG_get0(p8, &dalg, &doct); if (!PKCS12_pbe_crypt(dalg, pass, strlen(pass), doct->data, doct->length, &new_data, &new_data_len, 0)) goto nop8; mem->data = (char *)new_data; mem->max = mem->length = (size_t)new_data_len; X509_SIG_free(p8); store_info = ossl_store_info_new_EMBEDDED(PEM_STRING_PKCS8INF, mem); if (store_info == NULL) { OSSL_STOREerr(OSSL_STORE_F_TRY_DECODE_PKCS8ENCRYPTED, ERR_R_MALLOC_FAILURE); goto nop8; } return store_info; nop8: X509_SIG_free(p8); BUF_MEM_free(mem); return NULL; } static FILE_HANDLER PKCS8Encrypted_handler = { "PKCS8Encrypted", try_decode_PKCS8Encrypted }; /* * Private key decoder. Decodes all sorts of private keys, both PKCS#8 * encoded ones and old style PEM ones (with the key type is encoded into * the PEM name). */ int pem_check_suffix(const char *pem_str, const char *suffix); static OSSL_STORE_INFO *try_decode_PrivateKey(const char *pem_name, const char *pem_header, const unsigned char *blob, size_t len, void **pctx, int *matchcount, const UI_METHOD *ui_method, void *ui_data) { OSSL_STORE_INFO *store_info = NULL; EVP_PKEY *pkey = NULL; const EVP_PKEY_ASN1_METHOD *ameth = NULL; if (pem_name != NULL) { if (strcmp(pem_name, PEM_STRING_PKCS8INF) == 0) { PKCS8_PRIV_KEY_INFO *p8inf = d2i_PKCS8_PRIV_KEY_INFO(NULL, &blob, len); *matchcount = 1; if (p8inf != NULL) pkey = EVP_PKCS82PKEY(p8inf); PKCS8_PRIV_KEY_INFO_free(p8inf); } else { int slen; if ((slen = pem_check_suffix(pem_name, "PRIVATE KEY")) > 0 && (ameth = EVP_PKEY_asn1_find_str(NULL, pem_name, slen)) != NULL) { *matchcount = 1; pkey = d2i_PrivateKey(ameth->pkey_id, NULL, &blob, len); } } } else { int i; for (i = 0; i < EVP_PKEY_asn1_get_count(); i++) { EVP_PKEY *tmp_pkey = NULL; const unsigned char *tmp_blob = blob; ameth = EVP_PKEY_asn1_get0(i); if (ameth->pkey_flags & ASN1_PKEY_ALIAS) continue; tmp_pkey = d2i_PrivateKey(ameth->pkey_id, NULL, &tmp_blob, len); if (tmp_pkey != NULL) { if (pkey != NULL) EVP_PKEY_free(tmp_pkey); else pkey = tmp_pkey; (*matchcount)++; } } if (*matchcount > 1) { EVP_PKEY_free(pkey); pkey = NULL; } } if (pkey == NULL) /* No match */ return NULL; store_info = OSSL_STORE_INFO_new_PKEY(pkey); if (store_info == NULL) EVP_PKEY_free(pkey); return store_info; } static FILE_HANDLER PrivateKey_handler = { "PrivateKey", try_decode_PrivateKey }; /* * Public key decoder. Only supports SubjectPublicKeyInfo formated keys. */ static OSSL_STORE_INFO *try_decode_PUBKEY(const char *pem_name, const char *pem_header, const unsigned char *blob, size_t len, void **pctx, int *matchcount, const UI_METHOD *ui_method, void *ui_data) { OSSL_STORE_INFO *store_info = NULL; EVP_PKEY *pkey = NULL; if (pem_name != NULL) { if (strcmp(pem_name, PEM_STRING_PUBLIC) != 0) /* No match */ return NULL; *matchcount = 1; } if ((pkey = d2i_PUBKEY(NULL, &blob, len)) != NULL) { *matchcount = 1; store_info = OSSL_STORE_INFO_new_PKEY(pkey); } return store_info; } static FILE_HANDLER PUBKEY_handler = { "PUBKEY", try_decode_PUBKEY }; /* * Key parameter decoder. */ static OSSL_STORE_INFO *try_decode_params(const char *pem_name, const char *pem_header, const unsigned char *blob, size_t len, void **pctx, int *matchcount, const UI_METHOD *ui_method, void *ui_data) { OSSL_STORE_INFO *store_info = NULL; int slen = 0; EVP_PKEY *pkey = NULL; const EVP_PKEY_ASN1_METHOD *ameth = NULL; int ok = 0; if (pem_name != NULL) { if ((slen = pem_check_suffix(pem_name, "PARAMETERS")) == 0) return NULL; *matchcount = 1; } if (slen > 0) { if ((pkey = EVP_PKEY_new()) == NULL) { OSSL_STOREerr(OSSL_STORE_F_TRY_DECODE_PARAMS, ERR_R_EVP_LIB); return NULL; } if (EVP_PKEY_set_type_str(pkey, pem_name, slen) && (ameth = EVP_PKEY_get0_asn1(pkey)) != NULL && ameth->param_decode != NULL && ameth->param_decode(pkey, &blob, len)) ok = 1; } else { int i; EVP_PKEY *tmp_pkey = NULL; for (i = 0; i < EVP_PKEY_asn1_get_count(); i++) { const unsigned char *tmp_blob = blob; if (tmp_pkey == NULL && (tmp_pkey = EVP_PKEY_new()) == NULL) { OSSL_STOREerr(OSSL_STORE_F_TRY_DECODE_PARAMS, ERR_R_EVP_LIB); break; } ameth = EVP_PKEY_asn1_get0(i); if (ameth->pkey_flags & ASN1_PKEY_ALIAS) continue; if (EVP_PKEY_set_type(tmp_pkey, ameth->pkey_id) && (ameth = EVP_PKEY_get0_asn1(tmp_pkey)) != NULL && ameth->param_decode != NULL && ameth->param_decode(tmp_pkey, &tmp_blob, len)) { if (pkey != NULL) EVP_PKEY_free(tmp_pkey); else pkey = tmp_pkey; tmp_pkey = NULL; (*matchcount)++; } } EVP_PKEY_free(tmp_pkey); if (*matchcount == 1) { ok = 1; } } if (ok) store_info = OSSL_STORE_INFO_new_PARAMS(pkey); if (store_info == NULL) EVP_PKEY_free(pkey); return store_info; } static FILE_HANDLER params_handler = { "params", try_decode_params }; /* * X.509 certificate decoder. */ static OSSL_STORE_INFO *try_decode_X509Certificate(const char *pem_name, const char *pem_header, const unsigned char *blob, size_t len, void **pctx, int *matchcount, const UI_METHOD *ui_method, void *ui_data) { OSSL_STORE_INFO *store_info = NULL; X509 *cert = NULL; /* * In most cases, we can try to interpret the serialized data as a trusted * cert (X509 + X509_AUX) and fall back to reading it as a normal cert * (just X509), but if the PEM name specifically declares it as a trusted * cert, then no fallback should be engaged. |ignore_trusted| tells if * the fallback can be used (1) or not (0). */ int ignore_trusted = 1; if (pem_name != NULL) { if (strcmp(pem_name, PEM_STRING_X509_TRUSTED) == 0) ignore_trusted = 0; else if (strcmp(pem_name, PEM_STRING_X509_OLD) != 0 && strcmp(pem_name, PEM_STRING_X509) != 0) /* No match */ return NULL; *matchcount = 1; } if ((cert = d2i_X509_AUX(NULL, &blob, len)) != NULL || (ignore_trusted && (cert = d2i_X509(NULL, &blob, len)) != NULL)) { *matchcount = 1; store_info = OSSL_STORE_INFO_new_CERT(cert); } if (store_info == NULL) X509_free(cert); return store_info; } static FILE_HANDLER X509Certificate_handler = { "X509Certificate", try_decode_X509Certificate }; /* * X.509 CRL decoder. */ static OSSL_STORE_INFO *try_decode_X509CRL(const char *pem_name, const char *pem_header, const unsigned char *blob, size_t len, void **pctx, int *matchcount, const UI_METHOD *ui_method, void *ui_data) { OSSL_STORE_INFO *store_info = NULL; X509_CRL *crl = NULL; if (pem_name != NULL) { if (strcmp(pem_name, PEM_STRING_X509_CRL) != 0) /* No match */ return NULL; *matchcount = 1; } if ((crl = d2i_X509_CRL(NULL, &blob, len)) != NULL) { *matchcount = 1; store_info = OSSL_STORE_INFO_new_CRL(crl); } if (store_info == NULL) X509_CRL_free(crl); return store_info; } static FILE_HANDLER X509CRL_handler = { "X509CRL", try_decode_X509CRL }; /* * To finish it all off, we collect all the handlers. */ static const FILE_HANDLER *file_handlers[] = { &PKCS12_handler, &PKCS8Encrypted_handler, &X509Certificate_handler, &X509CRL_handler, ¶ms_handler, &PUBKEY_handler, &PrivateKey_handler, }; /*- * The loader itself * ----------------- */ struct ossl_store_loader_ctx_st { enum { is_raw = 0, is_pem, is_dir } type; int errcnt; #define FILE_FLAG_SECMEM (1<<0) unsigned int flags; union { struct { /* Used with is_raw and is_pem */ BIO *file; /* * The following are used when the handler is marked as * repeatable */ const FILE_HANDLER *last_handler; void *last_handler_ctx; } file; struct { /* Used with is_dir */ OPENSSL_DIR_CTX *ctx; int end_reached; char *uri; /* * The directory reading utility we have combines opening with * reading the first name. To make sure we can detect the end * at the right time, we read early and cache the name. */ const char *last_entry; int last_errno; } dir; } _; }; static void OSSL_STORE_LOADER_CTX_free(OSSL_STORE_LOADER_CTX *ctx) { if (ctx->type == is_dir) { OPENSSL_free(ctx->_.dir.uri); } else { if (ctx->_.file.last_handler != NULL) { ctx->_.file.last_handler->destroy_ctx(&ctx->_.file.last_handler_ctx); ctx->_.file.last_handler_ctx = NULL; ctx->_.file.last_handler = NULL; } } OPENSSL_free(ctx); } static OSSL_STORE_LOADER_CTX *file_open(const OSSL_STORE_LOADER *loader, const char *uri, const UI_METHOD *ui_method, void *ui_data) { OSSL_STORE_LOADER_CTX *ctx = NULL; struct stat st; struct { const char *path; unsigned int check_absolute:1; } path_data[2]; size_t path_data_n = 0, i; const char *path; /* * First step, just take the URI as is. */ path_data[path_data_n].check_absolute = 0; path_data[path_data_n++].path = uri; /* * Second step, if the URI appears to start with the 'file' scheme, * extract the path and make that the second path to check. * There's a special case if the URI also contains an authority, then * the full URI shouldn't be used as a path anywhere. */ if (strncasecmp(uri, "file:", 5) == 0) { const char *p = &uri[5]; if (strncmp(&uri[5], "//", 2) == 0) { path_data_n--; /* Invalidate using the full URI */ if (strncasecmp(&uri[7], "localhost/", 10) == 0) { p = &uri[16]; } else if (uri[7] == '/') { p = &uri[7]; } else { OSSL_STOREerr(OSSL_STORE_F_FILE_OPEN, OSSL_STORE_R_URI_AUTHORITY_UNSUPPORTED); return NULL; } } path_data[path_data_n].check_absolute = 1; #ifdef _WIN32 /* Windows file: URIs with a drive letter start with a / */ if (p[0] == '/' && p[2] == ':' && p[3] == '/') { char c = ossl_tolower(p[1]); if (c >= 'a' && c <= 'z') { p++; /* We know it's absolute, so no need to check */ path_data[path_data_n].check_absolute = 0; } } #endif path_data[path_data_n++].path = p; } for (i = 0, path = NULL; path == NULL && i < path_data_n; i++) { /* * If the scheme "file" was an explicit part of the URI, the path must * be absolute. So says RFC 8089 */ if (path_data[i].check_absolute && path_data[i].path[0] != '/') { OSSL_STOREerr(OSSL_STORE_F_FILE_OPEN, OSSL_STORE_R_PATH_MUST_BE_ABSOLUTE); ERR_add_error_data(1, path_data[i].path); return NULL; } if (stat(path_data[i].path, &st) < 0) { SYSerr(SYS_F_STAT, errno); ERR_add_error_data(1, path_data[i].path); } else { path = path_data[i].path; } } if (path == NULL) { return NULL; } /* Successfully found a working path, clear possible collected errors */ ERR_clear_error(); ctx = OPENSSL_zalloc(sizeof(*ctx)); if (ctx == NULL) { OSSL_STOREerr(OSSL_STORE_F_FILE_OPEN, ERR_R_MALLOC_FAILURE); return NULL; } if ((st.st_mode & S_IFDIR) == S_IFDIR) { /* * Try to copy everything, even if we know that some of them must be * NULL for the moment. This prevents errors in the future, when more * components may be used. */ ctx->_.dir.uri = OPENSSL_strdup(uri); ctx->type = is_dir; if (ctx->_.dir.uri == NULL) goto err; ctx->_.dir.last_entry = OPENSSL_DIR_read(&ctx->_.dir.ctx, path); ctx->_.dir.last_errno = errno; if (ctx->_.dir.last_entry == NULL) { if (ctx->_.dir.last_errno != 0) { char errbuf[256]; errno = ctx->_.dir.last_errno; openssl_strerror_r(errno, errbuf, sizeof(errbuf)); OSSL_STOREerr(OSSL_STORE_F_FILE_OPEN, ERR_R_SYS_LIB); ERR_add_error_data(1, errbuf); goto err; } ctx->_.dir.end_reached = 1; } } else { BIO *buff = NULL; char peekbuf[4096] = { 0, }; if ((buff = BIO_new(BIO_f_buffer())) == NULL || (ctx->_.file.file = BIO_new_file(path, "rb")) == NULL) { BIO_free_all(buff); goto err; } ctx->_.file.file = BIO_push(buff, ctx->_.file.file); if (BIO_buffer_peek(ctx->_.file.file, peekbuf, sizeof(peekbuf) - 1) > 0) { peekbuf[sizeof(peekbuf) - 1] = '\0'; if (strstr(peekbuf, "-----BEGIN ") != NULL) ctx->type = is_pem; } } return ctx; err: OSSL_STORE_LOADER_CTX_free(ctx); return NULL; } static int file_ctrl(OSSL_STORE_LOADER_CTX *ctx, int cmd, va_list args) { int ret = 1; switch (cmd) { case OSSL_STORE_C_USE_SECMEM: { int on = *(va_arg(args, int *)); switch (on) { case 0: ctx->flags &= ~FILE_FLAG_SECMEM; break; case 1: ctx->flags |= FILE_FLAG_SECMEM; break; default: OSSL_STOREerr(OSSL_STORE_F_FILE_CTRL, ERR_R_PASSED_INVALID_ARGUMENT); ret = 0; break; } } break; default: break; } return ret; } /* Internal function to decode an already opened PEM file */ OSSL_STORE_LOADER_CTX *ossl_store_file_attach_pem_bio_int(BIO *bp) { OSSL_STORE_LOADER_CTX *ctx = OPENSSL_zalloc(sizeof(*ctx)); if (ctx == NULL) { OSSL_STOREerr(OSSL_STORE_F_OSSL_STORE_FILE_ATTACH_PEM_BIO_INT, ERR_R_MALLOC_FAILURE); return NULL; } ctx->_.file.file = bp; ctx->type = is_pem; return ctx; } static OSSL_STORE_INFO *file_load_try_decode(OSSL_STORE_LOADER_CTX *ctx, const char *pem_name, const char *pem_header, unsigned char *data, size_t len, const UI_METHOD *ui_method, void *ui_data, int *matchcount) { OSSL_STORE_INFO *result = NULL; BUF_MEM *new_mem = NULL; char *new_pem_name = NULL; int t = 0; again: { size_t i = 0; void *handler_ctx = NULL; const FILE_HANDLER **matching_handlers = OPENSSL_zalloc(sizeof(*matching_handlers) * OSSL_NELEM(file_handlers)); if (matching_handlers == NULL) { OSSL_STOREerr(OSSL_STORE_F_FILE_LOAD_TRY_DECODE, ERR_R_MALLOC_FAILURE); goto err; } *matchcount = 0; for (i = 0; i < OSSL_NELEM(file_handlers); i++) { const FILE_HANDLER *handler = file_handlers[i]; int try_matchcount = 0; void *tmp_handler_ctx = NULL; OSSL_STORE_INFO *tmp_result = handler->try_decode(pem_name, pem_header, data, len, &tmp_handler_ctx, &try_matchcount, ui_method, ui_data); if (try_matchcount > 0) { matching_handlers[*matchcount] = handler; if (handler_ctx) handler->destroy_ctx(&handler_ctx); handler_ctx = tmp_handler_ctx; if ((*matchcount += try_matchcount) > 1) { /* more than one match => ambiguous, kill any result */ OSSL_STORE_INFO_free(result); OSSL_STORE_INFO_free(tmp_result); if (handler->destroy_ctx != NULL) handler->destroy_ctx(&handler_ctx); handler_ctx = NULL; tmp_result = NULL; result = NULL; } if (result == NULL) result = tmp_result; } } if (*matchcount == 1 && matching_handlers[0]->repeatable) { ctx->_.file.last_handler = matching_handlers[0]; ctx->_.file.last_handler_ctx = handler_ctx; } OPENSSL_free(matching_handlers); } err: OPENSSL_free(new_pem_name); BUF_MEM_free(new_mem); if (result != NULL && (t = OSSL_STORE_INFO_get_type(result)) == OSSL_STORE_INFO_EMBEDDED) { pem_name = new_pem_name = ossl_store_info_get0_EMBEDDED_pem_name(result); new_mem = ossl_store_info_get0_EMBEDDED_buffer(result); data = (unsigned char *)new_mem->data; len = new_mem->length; OPENSSL_free(result); result = NULL; goto again; } if (result != NULL) ERR_clear_error(); return result; } static OSSL_STORE_INFO *file_load_try_repeat(OSSL_STORE_LOADER_CTX *ctx, const UI_METHOD *ui_method, void *ui_data) { OSSL_STORE_INFO *result = NULL; int try_matchcount = 0; if (ctx->_.file.last_handler != NULL) { result = ctx->_.file.last_handler->try_decode(NULL, NULL, NULL, 0, &ctx->_.file.last_handler_ctx, &try_matchcount, ui_method, ui_data); if (result == NULL) { ctx->_.file.last_handler->destroy_ctx(&ctx->_.file.last_handler_ctx); ctx->_.file.last_handler_ctx = NULL; ctx->_.file.last_handler = NULL; } } return result; } static void pem_free_flag(void *pem_data, int secure, size_t num) { if (secure) OPENSSL_secure_clear_free(pem_data, num); else OPENSSL_free(pem_data); } static int file_read_pem(BIO *bp, char **pem_name, char **pem_header, unsigned char **data, long *len, const UI_METHOD *ui_method, void *ui_data, int secure) { int i = secure ? PEM_read_bio_ex(bp, pem_name, pem_header, data, len, PEM_FLAG_SECURE | PEM_FLAG_EAY_COMPATIBLE) : PEM_read_bio(bp, pem_name, pem_header, data, len); if (i <= 0) return 0; /* * 10 is the number of characters in "Proc-Type:", which * PEM_get_EVP_CIPHER_INFO() requires to be present. * If the PEM header has less characters than that, it's * not worth spending cycles on it. */ if (strlen(*pem_header) > 10) { EVP_CIPHER_INFO cipher; struct pem_pass_data pass_data; if (!PEM_get_EVP_CIPHER_INFO(*pem_header, &cipher) || !file_fill_pem_pass_data(&pass_data, "PEM", ui_method, ui_data) || !PEM_do_header(&cipher, *data, len, file_get_pem_pass, &pass_data)) { return 0; } } return 1; } static int file_read_asn1(BIO *bp, unsigned char **data, long *len) { BUF_MEM *mem = NULL; if (asn1_d2i_read_bio(bp, &mem) < 0) return 0; *data = (unsigned char *)mem->data; *len = (long)mem->length; OPENSSL_free(mem); return 1; } static int ends_with_dirsep(const char *uri) { if (*uri != '\0') uri += strlen(uri) - 1; #if defined __VMS if (*uri == ']' || *uri == '>' || *uri == ':') return 1; #elif defined _WIN32 if (*uri == '\\') return 1; #endif return *uri == '/'; } static int file_name_to_uri(OSSL_STORE_LOADER_CTX *ctx, const char *name, char **data) { assert(name != NULL); assert(data != NULL); { const char *pathsep = ends_with_dirsep(ctx->_.dir.uri) ? "" : "/"; long calculated_length = strlen(ctx->_.dir.uri) + strlen(pathsep) + strlen(name) + 1 /* \0 */; *data = OPENSSL_zalloc(calculated_length); if (*data == NULL) { OSSL_STOREerr(OSSL_STORE_F_FILE_NAME_TO_URI, ERR_R_MALLOC_FAILURE); return 0; } OPENSSL_strlcat(*data, ctx->_.dir.uri, calculated_length); OPENSSL_strlcat(*data, pathsep, calculated_length); OPENSSL_strlcat(*data, name, calculated_length); } return 1; } static int file_eof(OSSL_STORE_LOADER_CTX *ctx); static int file_error(OSSL_STORE_LOADER_CTX *ctx); static OSSL_STORE_INFO *file_load(OSSL_STORE_LOADER_CTX *ctx, const UI_METHOD *ui_method, void *ui_data) { OSSL_STORE_INFO *result = NULL; ctx->errcnt = 0; ERR_clear_error(); if (ctx->type == is_dir) { do { char *newname = NULL; if (ctx->_.dir.last_entry == NULL) { if (!ctx->_.dir.end_reached) { char errbuf[256]; assert(ctx->_.dir.last_errno != 0); errno = ctx->_.dir.last_errno; ctx->errcnt++; openssl_strerror_r(errno, errbuf, sizeof(errbuf)); OSSL_STOREerr(OSSL_STORE_F_FILE_LOAD, ERR_R_SYS_LIB); ERR_add_error_data(1, errbuf); } return NULL; } if (ctx->_.dir.last_entry[0] != '.' && !file_name_to_uri(ctx, ctx->_.dir.last_entry, &newname)) return NULL; /* * On the first call (with a NULL context), OPENSSL_DIR_read() * cares about the second argument. On the following calls, it * only cares that it isn't NULL. Therefore, we can safely give * it our URI here. */ ctx->_.dir.last_entry = OPENSSL_DIR_read(&ctx->_.dir.ctx, ctx->_.dir.uri); ctx->_.dir.last_errno = errno; if (ctx->_.dir.last_entry == NULL && ctx->_.dir.last_errno == 0) ctx->_.dir.end_reached = 1; if (newname != NULL && (result = OSSL_STORE_INFO_new_NAME(newname)) == NULL) { OPENSSL_free(newname); OSSL_STOREerr(OSSL_STORE_F_FILE_LOAD, ERR_R_OSSL_STORE_LIB); return NULL; } } while (result == NULL && !file_eof(ctx)); } else { int matchcount = -1; result = file_load_try_repeat(ctx, ui_method, ui_data); if (result != NULL) return result; if (file_eof(ctx)) return NULL; do { char *pem_name = NULL; /* PEM record name */ char *pem_header = NULL; /* PEM record header */ unsigned char *data = NULL; /* DER encoded data */ long len = 0; /* DER encoded data length */ matchcount = -1; if (ctx->type == is_pem) { if (!file_read_pem(ctx->_.file.file, &pem_name, &pem_header, &data, &len, ui_method, ui_data, (ctx->flags & FILE_FLAG_SECMEM) != 0)) { ctx->errcnt++; goto endloop; } } else { if (!file_read_asn1(ctx->_.file.file, &data, &len)) { ctx->errcnt++; goto endloop; } } result = file_load_try_decode(ctx, pem_name, pem_header, data, len, ui_method, ui_data, &matchcount); if (result != NULL) goto endloop; /* * If a PEM name matches more than one handler, the handlers are * badly coded. */ if (!ossl_assert(pem_name == NULL || matchcount <= 1)) { ctx->errcnt++; goto endloop; } if (matchcount > 1) { OSSL_STOREerr(OSSL_STORE_F_FILE_LOAD, OSSL_STORE_R_AMBIGUOUS_CONTENT_TYPE); } else if (matchcount == 1) { /* * If there are other errors on the stack, they already show * what the problem is. */ if (ERR_peek_error() == 0) { OSSL_STOREerr(OSSL_STORE_F_FILE_LOAD, OSSL_STORE_R_UNSUPPORTED_CONTENT_TYPE); if (pem_name != NULL) ERR_add_error_data(3, "PEM type is '", pem_name, "'"); } } if (matchcount > 0) ctx->errcnt++; endloop: pem_free_flag(pem_name, (ctx->flags & FILE_FLAG_SECMEM) != 0, 0); pem_free_flag(pem_header, (ctx->flags & FILE_FLAG_SECMEM) != 0, 0); pem_free_flag(data, (ctx->flags & FILE_FLAG_SECMEM) != 0, len); } while (matchcount == 0 && !file_eof(ctx) && !file_error(ctx)); /* We bail out on ambiguity */ if (matchcount > 1) return NULL; } return result; } static int file_error(OSSL_STORE_LOADER_CTX *ctx) { return ctx->errcnt > 0; } static int file_eof(OSSL_STORE_LOADER_CTX *ctx) { if (ctx->type == is_dir) return ctx->_.dir.end_reached; if (ctx->_.file.last_handler != NULL && !ctx->_.file.last_handler->eof(ctx->_.file.last_handler_ctx)) return 0; return BIO_eof(ctx->_.file.file); } static int file_close(OSSL_STORE_LOADER_CTX *ctx) { if (ctx->type == is_dir) { OPENSSL_DIR_end(&ctx->_.dir.ctx); } else { BIO_free_all(ctx->_.file.file); } OSSL_STORE_LOADER_CTX_free(ctx); return 1; } int ossl_store_file_detach_pem_bio_int(OSSL_STORE_LOADER_CTX *ctx) { OSSL_STORE_LOADER_CTX_free(ctx); return 1; } static OSSL_STORE_LOADER file_loader = { "file", NULL, file_open, file_ctrl, file_load, file_eof, file_error, file_close }; static void store_file_loader_deinit(void) { ossl_store_unregister_loader_int(file_loader.scheme); } int ossl_store_file_loader_init(void) { int ret = ossl_store_register_loader_int(&file_loader); OPENSSL_atexit(store_file_loader_deinit); return ret; }