/* Serval Distributed Numbering Architecture (DNA) Copyright (C) 2010 Paul Gardner-Stephen This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "serval.h" #include "rhizome.h" #include <stdlib.h> /* Import a bundle from the inbox folder. The bundle is contained a pair of files, one containing the manifest and the optional other containing the payload. The logic is all in rhizome_add_manifest(). This function just wraps that function and manages file and object buffers and lifetimes. */ int rhizome_bundle_import(rhizome_manifest *m_in, rhizome_manifest **m_out, char *bundle, char *groups[], int ttl, int verifyP, int checkFileP, int signP) { if (m_out) *m_out = NULL; char filename[1024]; char manifestname[1024]; if (snprintf(filename, sizeof(filename), "%s/import/file.%s", rhizome_datastore_path, bundle) >= sizeof(filename) || snprintf(manifestname, sizeof(manifestname), "%s/import/manifest.%s", rhizome_datastore_path, bundle) >= sizeof(manifestname)) { return WHY("Manifest bundle name too long"); } /* Read manifest file if no manifest was given */ rhizome_manifest *m = m_in; if (!m_in) { m = rhizome_read_manifest_file(manifestname, 0 /* file not buffer */, RHIZOME_VERIFY); if (!m) return WHY("Could not read manifest file."); } else { if (debug&DEBUG_RHIZOMESYNC) fprintf(stderr,"Importing direct from manifest structure hashP=%d\n",m->fileHashedP); } /* Add the manifest and its associated file to the Rhizome database. */ rhizome_manifest *dupm; int ret = rhizome_add_manifest(m, &dupm, filename, groups, ttl, verifyP, checkFileP, signP); unlink(filename); if (ret == -1) { unlink(manifestname); } else { /* >>> For testing, write manifest file back to disk and leave it there */ // unlink(manifestname); if (rhizome_write_manifest_file(m, manifestname)) ret = WHY("Could not write manifest file."); } /* If the manifest structure was allocated in this function, and it is not being returned to the caller, then this function is responsible for freeing it */ if (m_out) *m_out = m; else if (!m_in) rhizome_manifest_free(m); return ret; } /* Add a manifest/payload pair ("bundle") to the rhizome data store. Fills in any missing manifest fields (generating a new, random manifest ID if necessary), optionally performs consistency checks (see below), adds the manifest to the given groups (for which private keys must be held), optionally signs it, and inserts the manifest and payload into the rhizome store unless the store already contains a manifest with the same ID and a higher version number or an identical manifest (in which case the stored version number is bumped to the maximum of the two). This function is called in three different situations: (a) when the user injects a file (with or without a complete manifest) into rhizome, (b) when a manifest is received via the mesh and the file is already present in the rhizome store, (c) when a file is received via the mesh for a manifest that was received previously. The following arguments distinguish these situations: ttl - In case (a) ttl will be typically set to the initial (maximum?) TTL for a manifest. In cases (b) and (c) ttl will be the TTL of the received manifest decremented by one. This function clamps the supplied value into the legal range 0..255, so callers need not perform range checking after decrement. verifyP - If set, then checks that no signature verifications failed when the manifest was loaded. (If checkFileP is given, then also checks that the payload and manifest are consistent.) This is used in case (a) if the user provided a manifest file, and always for cases (b) and (c). It ensures the integrity of the received/provided manifest, and ensures that the received/provided payload is actually the one that the manifest belongs to. If verifyP is false, then the new manifest will be overwritten with the correct values for the payload. checkFileP - If set then checks that the payload file is readable, and will cause verifyP to also check that the payload matches the values in the manifest, specifically length and content hash. This is always used in cases (a) and (c), but not in case (b) because in that case, the file's contents with the given file hash are known to be already in the database. signP - If set, then signs the manifest after all its fields have been filled in. Only used in case (a), because in cases (b) and (c) the manifest has already been signed, since it is already on the air. A bundle can either be an ordinary manifest-payload pair, or a group description. - Group descriptions are manifests with no payload that have the "isagroup" variable set. They get stored in the manifests table AND a reference is added to the grouplist table. Any manifest, including any group manifest, may be a member of zero or one group. This allows a nested, i.e., multi-level group hierarchy where sub-groups will only typically be discovered by joining the parent group. */ int rhizome_add_manifest(rhizome_manifest *m_in, rhizome_manifest **m_out, const char *filename, char *groups[], int ttl, int verifyP, // verify that file's hash is consistent with manifest int checkFileP, int signP ) { if (m_out) *m_out = NULL; /* Ensure manifest meets basic sanity checks. */ const char *name = rhizome_manifest_get(m_in, "name", NULL, 0); if (name == NULL || !name[0]) return WHY("Manifest missing 'name' field"); if (rhizome_manifest_get_ll(m_in, "date") == -1) return WHY("Manifest missing 'date' field"); /* Keep payload file name handy for later */ m_in->dataFileName = strdup(filename); /* Store time to live, clamped to within legal range */ m_in->ttl = ttl < 0 ? 0 : ttl > 254 ? 254 : ttl; /* Check payload file is accessible and discover its length, then check that it matches the file size stored in the manifest */ if (checkFileP) { struct stat stat; if (lstat(filename,&stat)) return WHY("Could not stat() payload file"); m_in->fileLength = stat.st_size; long long mfilesize = rhizome_manifest_get_ll(m_in, "filesize"); if (mfilesize != -1 && mfilesize != m_in->fileLength) { WHYF("Manifest.filesize (%lld) != actual file size (%lld)", mfilesize, m_in->fileLength); if (verifyP) return -1; } } /* Bail out now if errors occurred loading the manifest file, eg signature failed to validate */ if (verifyP && m_in->errors) return WHYF("Manifest.errors (%d) is non-zero", m_in->errors); /* Compute hash of payload unless we know verification has already failed */ if (checkFileP || signP) { char hexhash[SHA512_DIGEST_STRING_LENGTH]; if (rhizome_hash_file(filename, hexhash)) return WHY("Could not hash file."); memcpy(&m_in->fileHexHash[0], &hexhash[0], SHA512_DIGEST_STRING_LENGTH); m_in->fileHashedP = 1; } /* Check that payload hash matches manifest */ if (checkFileP) { const char *mhexhash = rhizome_manifest_get(m_in, "filehash", NULL, 0); if (mhexhash && strcmp(m_in->fileHexHash, mhexhash)) { WHYF("Manifest.filehash (%s) does not match payload hash (%s)", mhexhash, m_in->fileHexHash); if (verifyP) return -1; } } /* Fill in the manifest so that duplicate detection can be performed, and to avoid redundant work by rhizome_manifest_finalise() below. */ if (checkFileP) { rhizome_manifest_set(m_in, "filehash", m_in->fileHexHash); rhizome_manifest_set_ll(m_in, "first_byte", 0); rhizome_manifest_set_ll(m_in, "last_byte", m_in->fileLength); } /* Check if a manifest is already stored for the same payload with the same details. This catches the case of "dna rhizome add file <filename>" on the same file more than once. (Debounce!) */ rhizome_manifest *dupm = NULL; if (rhizome_find_duplicate(m_in, &dupm) == -1) return WHY("Errors encountered searching for duplicate manifest"); if (dupm) { if (debug & DEBUG_RHIZOME) fprintf(stderr, "Not adding manifest for payload name=\"%s\" hexhash=%s - duplicate found in rhizome store\n", name, m_in->fileHexHash); #if 0 /* TODO Upgrade the version of the duplicate? */ long long version = rhizome_manifest_get_ll(m_in, "version"); long long dupversion = rhizome_manifest_get_ll(dupm, "version"); if (version > dupversion) { rhizome_manifest_set_ll(dupm, "version", version); ... } #endif if (m_out) { /* Finish completing the manifest */ if (rhizome_manifest_finalise(dupm, 0)) return WHY("Failed to finalise manifest.\n"); *m_out = dupm; } else rhizome_manifest_free(dupm); return 0; } /* Supply manifest version number if missing, so we can do the version check below */ if (rhizome_manifest_get(m_in, "version", NULL, 0) == NULL) { rhizome_manifest_set_ll(m_in, "version", overlay_gettime_ms()); } /* If the manifest already has an ID */ char *id = NULL; if ((id = rhizome_manifest_get(m_in, "id", NULL, 0))) { /* Discard the new manifest it is older than the most recent known version with the same ID */ long long storedversion = sqlite_exec_int64("SELECT version from manifests where id='%s';", id); if (storedversion > rhizome_manifest_get_ll(m_in, "version")) { return WHY("Newer version exists"); } /* Check if we know its private key */ rhizome_hex_to_bytes(id, m_in->cryptoSignPublic, crypto_sign_edwards25519sha512batch_PUBLICKEYBYTES*2); if (!rhizome_find_keypair_bytes(m_in->cryptoSignPublic, m_in->cryptoSignSecret)) m_in->haveSecret=1; } else { /* The manifest had no ID (256 bit random string being a public key in the NaCl CryptoSign crypto system), so create one. */ printf("manifest does not have an id\n"); rhizome_manifest_createid(m_in); /* The ID is implicit in transit, but we need to store it in the file, so that reimporting manifests on receiver nodes works easily. We might implement something that strips the id variable out of the manifest when sending it, or some other scheme to avoid sending all the extra bytes. */ id = rhizome_bytes_to_hex(m_in->cryptoSignPublic, crypto_sign_edwards25519sha512batch_PUBLICKEYBYTES); rhizome_manifest_set(m_in, "id", id); } /* Add group memberships */ if (groups) { int i; for(i = 0; groups[i]; i++) rhizome_manifest_add_group(m_in, groups[i]); } /* Finish completing the manifest */ if (rhizome_manifest_finalise(m_in, signP)) return WHY("Failed to finalise manifest.\n"); /* Okay, it is written, and can be put directly into the rhizome database now */ if (rhizome_store_bundle(m_in, filename) == -1) return WHY("rhizome_store_bundle() failed."); if (m_out) *m_out = m_in; return 0; } /* Update an existing Rhizome bundle */ int rhizome_bundle_push_update(char *id,long long version,unsigned char *data,int appendP) { return WHY("Not implemented"); } char nybltochar(int nybl) { if (nybl<0) return '?'; if (nybl>15) return '?'; if (nybl<10) return '0'+nybl; return 'A'+nybl-10; } int chartonybl(int c) { if (c>='A'&&c<='F') return 0x0a+(c-'A'); if (c>='a'&&c<='f') return 0x0a+(c-'a'); if (c>='0'&&c<='9') return 0x00+(c-'0'); return 0; } int rhizome_hex_to_bytes(char *in,unsigned char *out,int hexChars) { int i; for(i=0;i<hexChars;i++) { int byte=i>>1; int nybl=chartonybl(in[i]); out[byte]=out[byte]<<4; out[byte]|=nybl; } return 0; }