serval-dna/meshmb.c
2017-04-19 14:46:36 +09:30

475 lines
14 KiB
C

#include "serval.h"
#include "serval_types.h"
#include "dataformats.h"
#include "log.h"
#include "debug.h"
#include "conf.h"
#include "overlay_buffer.h"
#include "keyring.h"
#include "crypto.h"
#include "mem.h"
#include "meshmb.h"
struct feed_metadata{
size_t tree_depth;
struct message_ply ply; // (ply starts with a rhizome_bid_t, so this is consistent with a nibble tree)
struct meshmb_feed_details details;
// what is the offset of their last message
uint64_t last_message_offset;
// what is the last message we processed?
uint64_t last_seen;
// our cached value for the last known size of their ply
uint64_t size;
};
struct meshmb_feeds{
struct tree_root root;
keyring_identity *id;
sign_keypair_t bundle_keypair;
bool_t dirty;
};
// only remember this many bytes of ply names & last messages
#define MAX_NAME_LEN (256) // ??
#define MAX_MSG_LEN (256) // ??
static void update_stats(struct meshmb_feeds *feeds, struct feed_metadata *metadata, struct message_ply_read *reader)
{
if (!metadata->ply.found){
// get the current size from the db
sqlite_retry_state retry = SQLITE_RETRY_STATE_DEFAULT;
if (sqlite_exec_uint64_retry(&retry, &metadata->ply.size,
"SELECT filesize FROM manifests WHERE id = ?",
RHIZOME_BID_T, &metadata->ply.bundle_id,
END) == SQLITE_ROW)
metadata->ply.found = 1;
else
return;
}
if (metadata->size == metadata->ply.size)
return;
if (!message_ply_is_open(reader)
&& message_ply_read_open(reader, &metadata->ply.bundle_id)!=0)
return;
// TODO remember if user has overridden the name?
if (metadata->details.name){
free((void*)metadata->details.name);
metadata->details.name = NULL;
}
if (reader->name){
size_t len = strlen(reader->name);
if (len >= MAX_NAME_LEN)
len = MAX_NAME_LEN -1;
metadata->details.name = strn_edup(reader->name, len);
}
reader->read.offset = reader->read.length;
time_s_t timestamp = 0;
while (message_ply_read_prev(reader) == 0){
if (reader->type == MESSAGE_BLOCK_TYPE_TIME){
if (reader->record_length<4){
WARN("Malformed ply, expected 4 byte timestamp");
continue;
}
timestamp = read_uint32(reader->record);
}else if(reader->type == MESSAGE_BLOCK_TYPE_MESSAGE){
if (metadata->last_message_offset == reader->record_end_offset)
break;
metadata->last_message_offset = reader->record_end_offset;
if (metadata->details.last_message)
free((void*)metadata->details.last_message);
size_t len = reader->record_length;
if (len >= MAX_MSG_LEN)
len = MAX_MSG_LEN -1;
metadata->details.last_message = strn_edup((const char *)reader->record, len);
metadata->details.timestamp = timestamp;
break;
}
}
metadata->size = metadata->ply.size;
// TODO assemble ACK list for unified reading....?
feeds->dirty=1;
return;
}
// TODO, might be quicker to fetch all meshmb bundles and test if they are in the feed list
static int update_stats_tree(void **record, void *context)
{
struct feed_metadata *metadata = (struct feed_metadata *)*record;
struct meshmb_feeds *feeds = (struct meshmb_feeds *)context;
struct message_ply_read reader;
bzero(&reader, sizeof(reader));
update_stats(feeds, metadata, &reader);
message_ply_read_close(&reader);
return 0;
}
// eg, if a bundle_add trigger occurs while the feed list is open
void meshmb_bundle_update(struct meshmb_feeds *feeds, rhizome_manifest *m, struct message_ply_read *reader)
{
struct feed_metadata *metadata;
if (strcmp(m->service, RHIZOME_SERVICE_MESHMB) == 0
&& tree_find(&feeds->root, (void**)&metadata, m->keypair.public_key.binary, sizeof m->keypair.public_key.binary, NULL, NULL)==0){
metadata->ply.found = 1;
metadata->ply.size = m->filesize;
update_stats(feeds, metadata, reader);
}
}
int meshmb_update(struct meshmb_feeds *feeds)
{
return tree_walk(&feeds->root, NULL, 0, update_stats_tree, feeds);
}
static int write_metadata(void **record, void *context)
{
struct feed_metadata *metadata = (struct feed_metadata *)*record;
struct rhizome_write *write = (struct rhizome_write *)context;
assert(metadata->size >= metadata->last_message_offset);
assert(metadata->size >= metadata->last_seen);
unsigned name_len = (metadata->details.name ? strlen(metadata->details.name) : 0) + 1;
assert(name_len <= MAX_NAME_LEN);
unsigned msg_len = (metadata->details.last_message ? strlen(metadata->details.last_message) : 0) + 1;
assert(msg_len <= MAX_MSG_LEN);
uint8_t buffer[sizeof (rhizome_bid_t) + 1 + 12*4 + name_len + msg_len];
bcopy(metadata->ply.bundle_id.binary, buffer, sizeof (rhizome_bid_t));
size_t len = sizeof (rhizome_bid_t);
buffer[len++]=0;// flags?
len+=pack_uint(&buffer[len], metadata->size);
len+=pack_uint(&buffer[len], metadata->size - metadata->last_message_offset);
len+=pack_uint(&buffer[len], metadata->size - metadata->last_seen);
len+=pack_uint(&buffer[len], metadata->details.timestamp);
if (name_len > 1)
strncpy_nul((char *)&buffer[len], metadata->details.name, name_len);
else
buffer[len]=0;
len+=name_len;
if (msg_len > 1)
strncpy_nul((char *)&buffer[len], metadata->details.last_message, msg_len);
else
buffer[len]=0;
len+=msg_len;
assert(len < sizeof buffer);
DEBUGF(meshmb, "Write %u bytes of metadata for %s", len, alloca_tohex_rhizome_bid_t(metadata->ply.bundle_id));
return rhizome_write_buffer(write, buffer, len);
}
#define CURRENT_VERSION 0
int meshmb_flush(struct meshmb_feeds *feeds)
{
if (!feeds->dirty){
DEBUGF(meshmb, "Ignoring flush, not dirty");
return 0;
}
rhizome_manifest *mout = NULL;
rhizome_manifest *m = rhizome_new_manifest();
if (!m)
return -1;
int ret =-1;
struct rhizome_bundle_result result = rhizome_private_bundle(m, &feeds->bundle_keypair);
switch(result.status){
case RHIZOME_BUNDLE_STATUS_SAME:
rhizome_manifest_set_version(m, m->version + 1);
rhizome_manifest_set_filesize(m, RHIZOME_SIZE_UNSET);
rhizome_manifest_set_filehash(m, NULL);
// fallthrough
case RHIZOME_BUNDLE_STATUS_NEW:
{
struct rhizome_write write;
bzero(&write, sizeof(write));
enum rhizome_payload_status pstatus = rhizome_write_open_manifest(&write, m);
if (pstatus==RHIZOME_PAYLOAD_STATUS_NEW){
uint8_t version = CURRENT_VERSION;
rhizome_write_buffer(&write, &version, 1);
if (tree_walk(&feeds->root, NULL, 0, write_metadata, &write)==0){
pstatus = rhizome_finish_write(&write);
if (pstatus == RHIZOME_PAYLOAD_STATUS_NEW){
rhizome_manifest_set_filehash(m, &write.id);
rhizome_manifest_set_filesize(m, write.file_length);
struct rhizome_bundle_result result = rhizome_manifest_finalise(m, &mout, 1);
if (result.status == RHIZOME_BUNDLE_STATUS_NEW){
ret = 0;
feeds->dirty = 0;
}
rhizome_bundle_result_free(&result);
}
}
}
if (ret!=0)
rhizome_fail_write(&write);
break;
}
default:
break;
}
rhizome_manifest_free(m);
return ret;
}
static int free_feed(void **record, void *context)
{
struct meshmb_feeds *feeds = (struct meshmb_feeds *)context;
struct feed_metadata *f = *record;
if (f->details.name)
free((void *)f->details.name);
if (f->details.last_message)
free((void *)f->details.last_message);
free(f);
DEBUGF(meshmb, "free feed");
*record = NULL;
feeds->dirty = 1;
return 0;
}
void meshmb_close(struct meshmb_feeds *feeds)
{
tree_walk(&feeds->root, NULL, 0, free_feed, feeds);
free(feeds);
}
static void* alloc_feed(void *context, const uint8_t *binary, size_t UNUSED(bin_length))
{
struct meshmb_feeds *feeds = (struct meshmb_feeds *)context;
struct feed_metadata *feed = emalloc_zero(sizeof(struct feed_metadata));
if (feed){
feed->ply.bundle_id = *(rhizome_bid_t *)binary;
feeds->dirty = 1;
DEBUGF(meshmb, "Allocated feed");
}
return feed;
}
static int read_metadata(struct meshmb_feeds *feeds, struct rhizome_read *read)
{
struct rhizome_read_buffer buff;
bzero(&buff, sizeof(buff));
uint8_t buffer[sizeof (rhizome_bid_t) + 12*3 + MAX_NAME_LEN + MAX_MSG_LEN];
uint8_t version=0xFF;
if (rhizome_read_buffered(read, &buff, &version, 1)==-1)
return -1;
if (version > CURRENT_VERSION)
return WHYF("Unknown file format version (got 0x%02x)", version);
while(1){
ssize_t bytes = rhizome_read_buffered(read, &buff, buffer, sizeof buffer);
if (bytes==0)
break;
uint64_t delta=0;
uint64_t size;
uint64_t last_message_offset;
uint64_t last_seen;
uint64_t timestamp;
int unpacked;
const rhizome_bid_t *bid = (const rhizome_bid_t *)&buffer[0];
unsigned offset = sizeof(rhizome_bid_t);
if (offset >= (unsigned)bytes)
return WHY("Buffer overflow while parsing metadata");
//uint8_t flags = buffer[offset++];
offset++;
if (offset >= (unsigned)bytes)
return WHY("Buffer overflow while parsing metadata");
if ((unpacked = unpack_uint(buffer+offset, bytes-offset, &size)) == -1)
return WHY("Buffer overflow while parsing metadata");
offset += unpacked;
if ((unpacked = unpack_uint(buffer+offset, bytes-offset, &delta)) == -1)
return WHY("Buffer overflow while parsing metadata");
offset += unpacked;
last_message_offset = size - delta;
if ((unpacked = unpack_uint(buffer+offset, bytes-offset, &delta)) == -1)
return WHY("Buffer overflow while parsing metadata");
offset += unpacked;
last_seen = size - delta;
if ((unpacked = unpack_uint(buffer+offset, bytes-offset, &timestamp)) == -1)
return WHY("Buffer overflow while parsing metadata");
offset += unpacked;
const char *name = (const char *)&buffer[offset];
while(buffer[offset++]){
if (offset >= (unsigned)bytes)
return WHY("Buffer overflow while parsing metadata");
}
const char *msg = (const char *)&buffer[offset];
while(buffer[offset++]){
if (offset >= (unsigned)bytes)
return WHY("Buffer overflow while parsing metadata");
}
read->offset += offset - bytes;
struct feed_metadata *result;
if (tree_find(&feeds->root, (void**)&result, bid->binary, sizeof *bid, alloc_feed, feeds)<0)
return WHY("Failed to allocate metadata");
result->last_message_offset = last_message_offset;
result->last_seen = last_seen;
result->size = size;
result->details.bundle_id = *bid;
result->details.name = (name && *name) ? str_edup(name) : NULL;
result->details.last_message = (msg && *msg) ? str_edup(msg) : NULL;
result->details.timestamp = timestamp;
DEBUGF(meshmb, "Processed %u bytes of metadata for %s", offset, alloca_tohex_rhizome_bid_t(result->ply.bundle_id));
}
feeds->dirty = 0;
return 0;
}
int meshmb_open(keyring_identity *id, struct meshmb_feeds **feeds)
{
int ret = -1;
*feeds = emalloc_zero(sizeof(struct meshmb_feeds));
if (*feeds){
(*feeds)->root.binary_length = sizeof(rhizome_bid_t);
(*feeds)->id = id;
rhizome_manifest *m = rhizome_new_manifest();
if (m){
crypto_seed_keypair(&(*feeds)->bundle_keypair,
"91656c3d62e9fe2678a1a81fabe3f413%s5a37120ca55d911634560e4d4dc1283f",
alloca_tohex(id->sign_keypair->private_key.binary, sizeof id->sign_keypair->private_key));
struct rhizome_bundle_result result = rhizome_private_bundle(m, &(*feeds)->bundle_keypair);
DEBUGF(meshmb, "Private bundle %s, %s",
alloca_tohex_identity_t(&(*feeds)->bundle_keypair.public_key),
alloca_rhizome_bundle_result(result));
switch(result.status){
case RHIZOME_BUNDLE_STATUS_SAME:{
struct rhizome_read read;
bzero(&read, sizeof(read));
enum rhizome_payload_status pstatus = rhizome_open_decrypt_read(m, &read);
if (pstatus == RHIZOME_PAYLOAD_STATUS_STORED){
if (read_metadata(*feeds, &read)==-1)
WHYF("Failed to read metadata");
else
ret = 0;
}else
WHYF("Failed to read metadata: %s", rhizome_payload_status_message(pstatus));
rhizome_read_close(&read);
}break;
case RHIZOME_BUNDLE_STATUS_NEW:
ret = 0;
break;
case RHIZOME_BUNDLE_STATUS_BUSY:
break;
default:
// everything else should be impossible.
FATALF("Cannot create manifest: %s", alloca_rhizome_bundle_result(result));
}
rhizome_bundle_result_free(&result);
}
rhizome_manifest_free(m);
}
if (ret!=0){
meshmb_close(*feeds);
*feeds=NULL;
}
return ret;
}
int meshmb_follow(struct meshmb_feeds *feeds, rhizome_bid_t *bid)
{
struct feed_metadata *metadata;
DEBUGF(meshmb, "Attempting to follow %s", alloca_tohex_rhizome_bid_t(*bid));
// TODO load the manifest and check the service!
if (tree_find(&feeds->root, (void**)&metadata, bid->binary, sizeof *bid, alloc_feed, feeds)!=TREE_FOUND)
return WHYF("Failed to follow feed");
struct message_ply_read reader;
bzero(&reader, sizeof(reader));
update_stats(feeds, metadata, &reader);
message_ply_read_close(&reader);
return 0;
}
int meshmb_ignore(struct meshmb_feeds *feeds, rhizome_bid_t *bid)
{
DEBUGF(meshmb, "Attempting to ignore %s", alloca_tohex_rhizome_bid_t(*bid));
tree_walk_prefix(&feeds->root, bid->binary, sizeof *bid, free_feed, feeds);
return 0;
}
struct enum_context{
meshmb_callback callback;
void *context;
};
static int enum_callback(void **record, void *context)
{
struct feed_metadata *feed = *record;
struct enum_context *enum_context = context;
return enum_context->callback(&feed->details, enum_context->context);
}
int meshmb_enum(struct meshmb_feeds *feeds, rhizome_bid_t *restart_from, meshmb_callback callback, void *context)
{
DEBUGF(meshmb, "Enumerating feeds from %s",
restart_from?alloca_tohex_rhizome_bid_t(*restart_from):"the beginning");
struct enum_context enum_context = {
.callback = callback,
.context = context
};
return tree_walk(&feeds->root, restart_from ? restart_from->binary : NULL, sizeof *restart_from, enum_callback, &enum_context);
}
int meshmb_send(const keyring_identity *id, const char *message, size_t message_len,
unsigned nassignments, const struct rhizome_manifest_field_assignment *assignments){
const char *did=NULL, *name=NULL;
struct message_ply ply;
bzero(&ply, sizeof ply);
ply.bundle_id = id->sign_keypair->public_key;
ply.known_bid = 1;
struct overlay_buffer *b = ob_new();
message_ply_append_message(b, message, message_len);
message_ply_append_timestamp(b);
assert(!ob_overrun(b));
keyring_identity_extract(id, &did, &name);
int ret = message_ply_append(id, RHIZOME_SERVICE_MESHMB, NULL, &ply, b, name, nassignments, assignments);
ob_free(b);
return ret;
}