int txop_ward_init(shpeer_t *cli_peer, tx_ward_t *ward)
{
unsigned char context[128];
shkey_t sig_key;
tx_context_t ctx;
tx_t *tx;
int err;
if (ward->ward_stamp == SHTIME_UNDEFINED)
ward->ward_stamp = shtime();
if (ward->ward_expire == SHTIME_UNDEFINED)
ward->ward_expire = shtime_adj(shtime(), MAX_SHARE_SESSION_TIME);
memcpy(&ward->ward_tx.tx_peer, shpeer_kpriv(sharedaemon_peer()), sizeof(shpeer_t));
memset(&ctx, 0, sizeof(ctx));
err = inittx_context(&ctx, get_tx_key(ward), ashkey_uniq());
if (err)
return (err);
err = tx_save(&ctx);
if (err)
return (err);
/* store key reference to generated context */
memcpy(&ward->ward_ctx, &ctx.ctx_tx.tx_key, sizeof(ward->ward_ctx));
return (0);
}
int txop_contract_confirm(shpeer_t *peer, tx_contract_t *contract)
{
shtime_t now;
shkey_t *key;
int sig_ok;
if (0 != strcmp(contract->con_cur, COIN_USDE) &&
0 != strcmp(contract->con_cur, COIN_GMC) &&
0 != strcmp(contract->con_cur, COIN_SYS))
return (SHERR_INVAL);
now = shtime();
if (shtime_before(shtime(), contract->con_birth) ||
shtime_before(shtime(), contract->con_stamp) ||
shtime_after(contract->con_birth, contract->con_stamp))
return (SHERR_TIME);
key = shkey_hexgen(contract->con_key + 8);
if (!key)
return (SHERR_NOKEY);
sig_ok = shkey_cmp(key, &contract->con_sig);
shkey_free(&key);
if (!sig_ok)
return (SHERR_KEYREJECTED);
return (0);
}
static int shgeodb_geo_sql_cb(void *p, int arg_nr, char **args, char **cols)
{
shgeo_t *value_p = (shgeo_t *)p;
shtime_t stamp = SHTIME_UNDEFINED;
shnum_t lat = 0;
shnum_t lon = 0;
int alt = 0;
if (arg_nr == 2) {
if (args[0])
lat = (shnum_t)atof(args[0]);
if (args[1])
lon = (shnum_t)atof(args[1]);
#if 0
if (args[2])
alt = atoi(args[2]);
#endif
shgeo_set(value_p, lat, lon, alt);
#if 0
if (args[3])
value_p->geo_stamp = (shtime_t)atoll(args[3]);
#endif
if (value_p->geo_stamp == SHTIME_UNDEFINED)
value_p->geo_stamp = shtime();
}
return (0);
}
uint64_t shrand(void)
{
char buf[MAX_RANDOM_SEED_SIZE];
int i;
memset(buf, 0, sizeof(buf));
FILE *ran = fopen("/dev/urandom", "r");
if (ran) {
fread(buf, 1, sizeof(buf), ran);
fclose(ran);
} else {
static int init;
if (!init) {
init = 1;
srand((unsigned int)shtime());
}
unsigned int rval;
for (i = 0; i < MAX_RANDOM_SEED_SIZE; i += 4) {
rval = rand();
memcpy(buf + i, &rval, sizeof(rval));
}
}
return (shcrc(buf, sizeof(buf)));
}
int txop_contract_init(shpeer_t *cli_peer, tx_contract_t *contract)
{
shkey_t *key;
contract->con_birth = shtime();
key = shkey_hexgen(contract->con_key + 8);
if (!key)
return (SHERR_NOKEY);
memcpy(&contract->con_sig, key, sizeof(contract->con_sig));
shkey_free(&key);
contract->con_stamp = shtime();
return (0);
}
int create_bond_asset(shkey_t *id_key, tx_bond_t *bond, size_t bond_nr, tx_asset_t **asset_p)
{
tx_asset_t *asset;
shpeer_t *peer;
size_t len;
int err;
peer = load_asset_peer(id_key);
if (!peer)
return (SHERR_INVAL);
len = sizeof(tx_asset_t) + (sizeof(tx_bond_t) * bond_nr);
asset = (tx_asset_t *)calloc(len, sizeof(char));
if (!asset)
return (SHERR_NOMEM);
asset->ass.ass_birth = shtime();
asset->ass_type = TX_BOND;
/* asset content */
asset->ass_size = (sizeof(tx_bond_t) * bond_nr);
memcpy((unsigned char *)asset->ass_data,
(unsigned char *)bond, (sizeof(tx_bond_t) * bond_nr));
/* generate signature based on identity's priveleged key */
memcpy(&asset->ass.ass_id, id_key, sizeof(asset->ass.ass_id));
generate_asset_signature(asset, peer);
err = tx_init(NULL, (tx_t *)asset, TX_ASSET);
if (err)
return (err);
return (0);
}
int install_sexe_userdata(sexe_t *S, char *tag)
{
SHFL *fl;
shjson_t *udata;
shfs_t *fs;
shbuf_t *buff;
shkey_t *k;
char path[PATH_MAX+1];
int is_new;
k = shkey_str(tag);
sprintf(path, "/sys/data/sexe/%s", shkey_hex(k));
memcpy(&S->pname, k, sizeof(S->pname));
shkey_free(&k);
buff = shbuf_init();
fs = shfs_init(NULL);
fl = shfs_file_find(fs, path);
is_new = shfs_read(fl, buff);
udata = shjson_init(shbuf_size(buff) ? (char *)shbuf_data(buff) : NULL);
shbuf_free(&buff);
if (is_new)
shjson_num_add(udata, "birth", shtimef(shtime()));
sexe_table_set(S, udata);
lua_setglobal(S, "userdata");
shjson_free(&udata);
shfs_free(&fs);
return (0);
}
int shpam_pshadow_set(shfs_ino_t *file, shseed_t *seed, shkey_t *sess_key)
{
shadow_t save;
int err;
err = shpam_shadow_load(file, seed->seed_uid, &save);
if (err)
return (err);
/* validate session key */
if (shtime_after(shtime(), save.sh_expire))
return (SHERR_KEYEXPIRED);
if (!shkey_cmp(&save.sh_sess, sess_key))
return (SHERR_KEYREJECTED);
err = shpam_shadow_session_expire(file, seed->seed_uid, sess_key);
if (err)
return (err);
err = shpam_pshadow_store(file, seed);
if (err)
return (err);
return (0);
}
int shpam_shadow_remove(shfs_ino_t *file, uint64_t uid, shkey_t *sess_key)
{
shadow_t *ent;
shadow_t save;
shkey_t *key;
int err;
if (!sess_key)
return (SHERR_NOKEY);
err = shpam_shadow_load(file, uid, &save);
if (err) {
return (err);
}
if (shtime_after(shtime(), save.sh_expire))
return (SHERR_KEYEXPIRED);
if (!shkey_cmp(&save.sh_sess, sess_key))
return (SHERR_KEYREJECTED);
key = shkey_bin((char *)&uid, sizeof(uid));
err = shfs_cred_remove(file, key);
shkey_free(&key);
if (err) {
return (err);
}
return (0);
}
static int shgeodb_scan_sql_cb(void *p, int arg_nr, char **args, char **cols)
{
shgeo_t *value_p = (shgeo_t *)p;
shnum_t lat = 0;
shnum_t lon = 0;
int idx;
for (idx = 0; idx < MAX_SHGEO_SCAN_RECORDS; idx++) {
if (value_p[idx].geo_stamp == SHTIME_UNDEFINED)
break;
}
if (idx == MAX_SHGEO_SCAN_RECORDS)
return (0); /* full list */
if (arg_nr == 2) {
if (args[0] == NULL || args[1] == NULL)
return (0);
lat = (shnum_t)atof(args[0]);
lon = (shnum_t)atof(args[1]);
shgeo_set(value_p + idx, lat, lon, 0);
if (value_p[idx].geo_stamp == SHTIME_UNDEFINED)
value_p[idx].geo_stamp = shtime();
}
return (0);
}
static void shproc_state_set(shproc_t *proc, int state)
{
int ostate = proc->proc_state;
if (state < 0 || state >= MAX_SHPROC_STATES)
return;
if (proc->proc_state == state)
return;
if (proc->proc_stamp) {
proc->stat.span_tot[ostate] += (shtimef(shtime()) - shtimef(proc->proc_stamp));
proc->stat.span_cnt[ostate]++;
}
proc->proc_stamp = shtime();
proc->proc_state = state;
}
void shlog_write(shbuf_t *buff, int level, int err_code, char *log_str)
{
static char log_path[PATH_MAX+1];
char line[640];
char *beg_line;
size_t mem_size;
if (!buff)
return;
if (!*log_path) {
char *label;
shpeer_t peer;
memcpy(&peer, ashpeer(), sizeof(peer));
label = (!*peer.label ? PACKAGE_NAME : peer.label);
sprintf(log_path, "%s%s.log", shlog_path(label), label);
}
if (*log_path && !_shlog_file) {
_shlog_file = fopen(log_path, "ab");
}
beg_line = shbuf_data(buff) + shbuf_size(buff);
sprintf(line, "%s", shstrtime(shtime(), "[%x %T] "));
shbuf_catstr(buff, line);
if (level == SHLOG_ERROR) {
shbuf_catstr(buff, "error");
} else if (level == SHLOG_WARNING) {
shbuf_catstr(buff, "warning");
} else {
shbuf_catstr(buff, "info");
}
if (err_code) {
memset(line, 0, sizeof(line));
snprintf(line, sizeof(line) - 1,
": %s [code %d]", strerror(-(err_code)), (err_code));
shbuf_catstr(buff, line);
}
if (log_str) {
shbuf_catstr(buff, ": ");
shbuf_catstr(buff, log_str);
}
mem_size = shlog_mem_size();
if (mem_size > 100000) {
sprintf(line, " (mem:%dm)", (mem_size / 1000));
shbuf_catstr(buff, line);
}
shbuf_catstr(buff, "\n");
}
int shcert_init_default(shcert_t *cert)
{
int i;
/* certificate version */
cert->cert_ver = 3;
/* certificate's issuer peer entity */
memcpy(&cert->cert_sub.ent_peer, ashpeer(), sizeof(cert->cert_sub.ent_peer));
/* set birth and expiration time-stamps */
cert->cert_sub.ent_sig.sig_stamp = shtime_adj(shtime(), -1);
cert->cert_sub.ent_sig.sig_expire =
shtime_adj(shtime(), SHARE_DEFAULT_EXPIRE_TIME);
/* fill with random serial number */
shcert_init_serial(shcert_sub_ser(cert));
}
void shgeo_set(shgeo_t *geo, shnum_t lat, shnum_t lon, int alt)
{
alt = MIN(alt, 1584000000);
geo->geo_stamp = shtime();
shnum_set((shnum_t)lat, &geo->geo_lat);
shnum_set((shnum_t)lon, &geo->geo_lon);
geo->geo_alt = (uint32_t)alt;
}
void
dcc_partyline(sock_t *sender, char *msg)
{
sock_t *sock = main_sock;
char msgbuf[BUFSIZE];
snprintf(msgbuf, BUFSIZE, "(%s) (%s) %s\n", shtime(), sender->name, msg);
for (; sock; sock = sock->next)
if (sock->flags & (SOCK_DCC|SOCK_TELNET) && sock->flags & SOCK_AUTH &&
(sock != sender || sender->flags & SOCK_DCC_ECHO))
write(sock->socket, msgbuf, strlen(msgbuf));
}
int tx_send(shpeer_t *cli_peer, tx_t *tx)
{
unsigned char *data = (unsigned char *)tx;
size_t data_len;
tx_ledger_t *l;
int err;
txop_t *op;
if (!data)
return (SHERR_INVAL);
data_len = get_tx_size(tx);
if (!data_len)
return (0);
op = get_tx_op(tx->tx_op);
if (!op)
return (SHERR_INVAL);
if (op->op_send) {
err = op->op_send(cli_peer, data);
if (err) {
if (err == SHERR_OPNOTSUPP)
return (0);
return (err);
}
}
if (is_tx_stored(tx->tx_op)) {
l = ledger_load(shpeer_kpriv(sharedaemon_peer()), shtime());
if (l) {
ledger_tx_add(l, (tx_t *)data);
ledger_close(l);
}
}
#if 0
/* encapsulate for network transfer. */
tx_wrap(shpeer_kpriv(cli_peer), (tx_t *)tx);
#endif
if (cli_peer) {
sched_tx_sink(shpeer_kpriv(cli_peer), data, data_len);
} else {
sched_tx(data, data_len);
}
return (0);
}
void generate_asset_signature(tx_asset_t *asset, shpeer_t *peer)
{
shkey_t *sig_key;
uint64_t crc;
if (asset->ass.ass_expire == SHTIME_UNDEFINED)
asset->ass.ass_expire = shtime_adj(shtime(), SHARE_DEFAULT_EXPIRE_TIME);
crc = shcrc((unsigned char *)asset->ass_data, asset->ass_size);
sig_key = shkey_cert(shpeer_kpriv(peer), crc, asset->ass.ass_expire);
memcpy(&asset->ass.ass_sig, sig_key, sizeof(shkey_t));
shkey_free(&sig_key);
}
void shmap_print(shmap_t *h, shbuf_t *ret_buff)
{
shmap_entry_t *ent;
shmap_value_t mval;
shmap_index_t *hi;
shkey_t *key;
char buf[256];
char *val;
char str[4096];
ssize_t len;
int flag;
int idx;
int i;
if (!h || !ret_buff)
return; /* all done */
i = 0;
for (hi = shmap_first(h); hi; hi = shmap_next(hi)) {
shmap_self(hi, &key, &val, &len, &flag);
if (!len || !val)
continue;
flag &= ~SHMAP_ALLOC;
memset(&mval, 0, sizeof(mval));
memcpy(&mval.name, key, sizeof(mval.name));
mval.magic = SHMEM32_MAGIC;
mval.stamp = shtime();
mval.crc = shcrc(val, len);
mval.pf = flag;
mval.sz = len;
shbuf_cat(ret_buff, &mval, sizeof(shmap_value_t));
shbuf_cat(ret_buff, val, len);
#if 0
hdr = (shmap_value_t *)val;
memcpy(&hdr->name, key, sizeof(shkey_t));
shbuf_cat(ret_buff, hdr, sizeof(shmap_value_t));
shbuf_cat(ret_buff, ((char *)val + sizeof(shmap_value_t)), hdr->sz);
#endif
i++;
}
}
int shpam_shadow_session(shfs_ino_t *file, shseed_t *seed, shkey_t **sess_p, shtime_t *expire_p)
{
shadow_t *ent;
shadow_t save;
shkey_t *sess_key;
shkey_t *ret_key;
shkey_t *seed_key;
shtime_t stamp;
shtime_t now;
uint64_t crc;
int err;
if (!file->tree)
return (SHERR_INVAL);
err = shpam_shadow_load(file, seed->seed_uid, &save);
if (err) {
return (err);
}
now = shtime();
if (shtime_after(now, save.sh_expire)) {
/* generate new session key with default expiration */
stamp = shtime_adj(now, MAX_SHARE_SESSION_TIME);
sess_key = _shpam_shadow_session_gen(seed, &save.sh_id, stamp);
if (!sess_key)
return (SHERR_KEYREVOKED);
save.sh_expire = stamp;
memcpy(&save.sh_sess, sess_key, sizeof(save.sh_sess));
err = shpam_shadow_store(file, &save);
shkey_free(&sess_key);
if (err) {
return (err);
}
}
if (expire_p)
*expire_p = save.sh_expire;
if (sess_p) {
ret_key = (shkey_t *)calloc(1, sizeof(shkey_t));
memcpy(ret_key, &save.sh_sess, sizeof(shkey_t));
*sess_p = ret_key;
}
return (0);
}
void
alldcc(char *tosend, ...)
{
sock_t *sock = main_sock;
char msgbuf[BUFSIZE], sendbuf[BUFSIZE], *temp = shtime();
va_list ap;
va_start(ap, tosend);
leet_vsprintf(msgbuf, tosend, ap);
for (; sock; sock = sock->next)
if (sock->flags & (SOCK_DCC|SOCK_TELNET) && sock->flags & SOCK_AUTH) {
memset(sendbuf, 0, BUFSIZE);
snprintf(sendbuf, BUFSIZE, "(%s) %s\n", temp, msgbuf);
write(sock->socket, sendbuf, strlen(sendbuf));
}
va_end(ap);
}
/**
* Manually set the device's current location.
*/
void shgeo_local_set(shgeo_t *geo)
{
shnum_t lat, lon;
char buf[256];
if (!geo)
return;
/* set in-memory */
memcpy(&_local_geo_index, geo, sizeof(_local_geo_index));
_local_geo_index.geo_stamp = shtime();
/* set persistent */
shgeo_loc(geo, &lat, &lon, NULL);
sprintf(buf, "%Lf,%Lf", lat, lon);
shpref_set(SHPREF_ACC_GEO, buf);
}
/** Associated a particular context with releasing a ward. */
void txward_context_sign(tx_ward_t *ward, tx_context_t *ctx)
{
shkey_t *sig_key;
if (!ward || !ctx)
return;
if (!shkey_cmp(&ward->ward_ref, &ctx->ctx_ref))
return (SHERR_INVAL);
if (ward->ward_tx.tx_stamp == SHTIME_UNDEFINED)
ward->ward_tx.tx_stamp = shtime();
sig_key = shkey_cert(&ctx->ctx_sig,
shkey_crc(&ctx->ctx_ref), ward->ward_tx.tx_stamp);
memcpy(&ward->ward_sig, sig_key, sizeof(ward->ward_sig));
shkey_free(&sig_key);
}
int shpam_shadow_session_expire(shfs_ino_t *file, uint64_t uid, shkey_t *sess_key)
{
shadow_t *ent;
shadow_t save;
int err;
err = shpam_shadow_load(file, uid, &save);
if (err)
return (err);
if (shtime_after(shtime(), save.sh_expire))
return (SHERR_KEYEXPIRED);
if (!shkey_cmp(&save.sh_sess, sess_key))
return (SHERR_KEYREJECTED);
save.sh_expire = 0;
err = shpam_shadow_store(file, &save);
if (err)
return (err);
return (0);
}
int shcert_verify(shcert_t *cert, shcert_t *parent)
{
shtime_t now;
int err;
if (!(cert->cert_flag & SHCERT_CERT_CHAIN)) {
/* initial (CA) chain entity */
if (parent)
return (SHERR_INVAL);
return (0);
}
/* supplemental chain entity */
if (!parent)
return (SHERR_INVAL);
/* The Issuer of each certificate (except the last one) matches the Subject of the next (parent) certificate in the list. */
if (0 != strcasecmp(cert->cert_iss.ent_name,
parent->cert_sub.ent_name)) {
return (SHERR_ACCESS);
}
now = shtime();
if (!shtime_after(now, shcert_sub_stamp(cert))) {
return (SHERR_ACCESS);
}
if (!shtime_before(now, shcert_sub_expire(cert))) {
return (SHERR_KEYEXPIRED);
}
/* The signature of one certificate can be verified using the public key contained in the following certificate. */
err = shcert_sign_verify(cert, parent);
if (err)
return (err);
return (0);
}
time_t shgeo_lifespan(shgeo_t *geo)
{
return ((time_t)shtime_diff(shtime(), geo->geo_stamp));
}
static int _lfunc_sexe_time(lua_State *L)
{
lua_pushnumber(L, shtimef(shtime()));
return 1; /* 'time' */
}
int sharedaemon_bcast_recv(void)
{
struct sockaddr_in addr;
socklen_t addr_len;
struct timeval to;
fd_set read_set;
shpeer_t *peer;
char dgram[512];
ssize_t r_len;
int err;
err = bcast_recv_init();
if (err) {
return (err);
}
FD_ZERO(&read_set);
FD_SET(_bcast_recv_fd, &read_set);
/* nonblocking read */
memset(&to, 0, sizeof(to));
err = select(_bcast_recv_fd+1, &read_set, NULL, NULL, &to);
if (err < 0) {
return (-errno);
}
if (err == 0) {
//fprintf(stderr, "\rWaiting for select(_bcast_recv_fd)..");
//fflush(stderr);
return (0); /* nothing to read */
}
addr_len = sizeof(addr);
memset(&addr, 0, addr_len);
r_len = recvfrom(_bcast_recv_fd,
dgram, sizeof dgram, 0, &addr, &addr_len);
if (r_len < 0) {
fprintf(stderr, "DEBUG: %d = recvfrom()\n", r_len);
return (-errno);
}
/* and who are you? */
if (r_len < sizeof(shpeer_t)) {
fprintf(stderr, "DEBUG: <%d bytes> pending..\n", r_len);
return (SHERR_INVAL);
}
#if 0
now = shtime();
tx = (tx_t *)dgram;
if (shtime_after(tx->tx_stamp, now) ||
shtime_before(tx->tx_stamp, shtime_adj(now, -BROADCAST_TIMEOUT))) {
/* broadcast message must indicate sane time-frame. */
return (SHERR_TIME);
}
switch (tx->tx_op) {
case TX_PEER:
peer_tx = (tx_peer_t *)dgram;
if (0 != shkey_cmp(&tx->tx_peer, shpeer_kpriv(&peer_tx->peer)))
return (SHERR_INVAL); /* only accept self-referencing broadcast */
}
#endif
/* share-daemon broadcasting it's peer address. */
peer = (shpeer_t *)dgram;
if (!shkey_cmp(shpeer_kpub(sharedaemon_peer()), shpeer_kpub(peer))) {
/* this is not a shared peer */
return (0); /* all done */
}
if (!shkey_cmp(shpeer_kpub(sharedaemon_peer()), shpeer_kpub(peer))) {
fprintf(stderr, "DEBUG: invalid key\n");
/* this is a peer referencing ourselves. */
//err = sharedaemon_netclient_alias(&addr);
}
switch (peer->type) {
case SHNET_PEER_LOCAL:
case SHNET_PEER_IPV4:
/*
memset(&addr, '\000', sizeof(struct sockaddr_in));
memcpy(&addr, &peer_tx->peer.addr, sizeof(peer_tx->peer.addr));
*/
fprintf(stderr, "DEBUG: received UDP broadcast with peer \"%s\"\n", shpeer_print(peer));
fprintf(stderr, "DEBUG: received UDP broadcast for \"%s\" port %d\n", inet_ntoa(addr.sin_addr), ntohs(addr.sin_port));
if (!peer->addr.sin_port)
break; /* otay */
addr.sin_family = AF_INET;
err = sharedaemon_netclient_conn(peer, &addr);
if (err)
return (err);
break;
}
fprintf(stderr, "DEBUG: processed bcast recv\n");
return (0);
}
int tx_recv(shpeer_t *cli_peer, tx_t *tx)
{
tx_ledger_t *l;
tx_t *rec_tx;
txop_t *op;
int err;
if (!tx)
return (SHERR_INVAL);
#if 0
if (ledger_tx_load(shpeer_kpriv(cli_peer), tx->hash, tx->tx_stamp)) {
fprintf(stderr, "DEBUG: tx_recv: skipping duplicate tx '%s'\n", tx->hash);
return (SHERR_NOTUNIQ);
}
#endif
op = get_tx_op(tx->tx_op);
if (!op)
return (SHERR_INVAL);
if (tx->tx_flag & TXF_WARD) {
err = txward_confirm(tx);
if (err)
return (err);
}
/* check for dup in ledger (?) */
rec_tx = (tx_t *)tx_load(tx->tx_op, get_tx_key(tx));
if (!rec_tx) {
rec_tx = (tx_t *)calloc(1, op->op_size);
if (!rec_tx)
return (SHERR_NOMEM);
memcpy(rec_tx, tx, op->op_size);
#if 0
err = tx_init(cli_peer, rec_tx);
if (err) {
pstore_free(rec_tx);
return (err);
}
#endif
err = tx_save(rec_tx);
if (err) {
pstore_free(rec_tx);
return (err);
}
}
if (op->op_recv) {
err = op->op_recv(cli_peer, tx);
if (err) {
pstore_free(rec_tx);
return (err);
}
}
pstore_free(rec_tx);
if (is_tx_stored(tx->tx_op)) {
l = ledger_load(shpeer_kpriv(cli_peer), shtime());
if (l) {
ledger_tx_add(l, tx);
ledger_close(l);
}
}
return (0);
}
