CSTUB_FN(int, tmerge)(struct usr_inv_cap *uc,
spdid_t spdid, td_t td, td_t td_into, char *param, int len)
{
int ret;
long fault = 0;
struct __sg_tmerge_data *d;
cbuf_t cb;
int sz = len + sizeof(struct __sg_tmerge_data);
assert(param && len > 0);
assert(param[len-1] == '\0');
d = cbuf_alloc_ext(sz, &cb, CBUF_TMEM);
if (!d) return -1;
d->td = td;
d->td_into = td_into;
d->len[0] = 0;
d->len[1] = len;
memcpy(&d->data[0], param, len);
CSTUB_INVOKE(ret, fault, uc, 3, spdid, cb, sz);
cbuf_free(cb);
return ret;
}
CSTUB_FN(int, twmeta)(struct usr_inv_cap *uc,
spdid_t spdid, td_t td, const char *key,
unsigned int klen, const char *val, unsigned int vlen)
{
int ret;
long fault = 0;
cbuf_t cb;
int sz = sizeof(struct __sg_twmeta_data) + klen + vlen + 1;
struct __sg_twmeta_data *d;
assert(key && val && klen > 0 && vlen > 0);
assert(key[klen] == '\0' && val[vlen] == '\0' && sz <= PAGE_SIZE);
d = cbuf_alloc_ext(sz, &cb, CBUF_TMEM);
if (!d) assert(0); //return -1;
d->td = td;
d->klen = klen;
d->vlen = vlen;
memcpy(&d->data[0], key, klen + 1);
memcpy(&d->data[klen + 1], val, vlen + 1);
CSTUB_INVOKE(ret, fault, uc, 3, spdid, cb, sz);
cbuf_free(cb);
return ret;
}
CSTUB_FN(int, trmeta)(struct usr_inv_cap *uc,
spdid_t spdid, td_t td, const char *key,
unsigned int klen, char *retval, unsigned int max_rval_len)
{
int ret;
long fault = 0;
cbuf_t cb;
int sz = sizeof(struct __sg_trmeta_data) + klen + max_rval_len + 1;
struct __sg_trmeta_data *d;
assert(key && retval && klen > 0 && max_rval_len > 0);
assert(key[klen] == '\0' && sz <= PAGE_SIZE);
d = cbuf_alloc_ext(sz, &cb, CBUF_TMEM);
if (!d) return -1;
d->td = td;
d->klen = klen;
d->retval_len = max_rval_len;
memcpy(&d->data[0], key, klen + 1);
CSTUB_INVOKE(ret, fault, uc, 3, spdid, cb, sz);
if (ret >= 0) {
if ((unsigned int)ret > max_rval_len) { // as ret >= 0, cast it to unsigned int to omit compiler warning
cbuf_free(cb);
return -EIO;
}
memcpy(retval, &d->data[klen + 1], ret + 1);
}
cbuf_free(cb);
return ret;
}
CSTUB_FN(void, trelease)(struct usr_inv_cap *uc,
spdid_t spdid, td_t tid)
{
int ret;
long fault = 0;
printc("<<<rtorrent In: call trelease (thread %d) >>>\n", cos_get_thd_id());
struct rec_data_tor *rd;
redo:
/* printc("<<< In: call trelease (thread %d) >>>\n", cos_get_thd_id()); */
rd = rd_update(tid, STATE_TRELEASE);
assert(rd);
CSTUB_INVOKE(ret, fault, uc, 2, spdid, rd->s_tid);
if (unlikely(fault)) {
CSTUB_FAULT_UPDATE();
goto redo;
}
map_rd_delete(rd->c_tid);
return;
}
/* Here we have reset the owner to be 0 on the client side, so we do
* not goto redo */
CSTUB_FN(int, lock_component_release) (struct usr_inv_cap *uc,
spdid_t spdid, unsigned long lock_id)
{
long fault = 0;
int ret;
struct rec_data_lk *rd = NULL;
redo:
rd = rd_update(lock_id, LOCK_RELEASE);
assert(rd);
/* if (!rd) { */
/* printc("try to release a non-tracking lock\n"); */
/* return -1; */
/* } */
CSTUB_INVOKE(ret, fault, uc, 2, spdid, rd->s_lkid);
if (unlikely (fault)){
/* printc("cli:thd %d see a fault in lock_component_release!\n", */
/* cos_get_thd_id()); */
CSTUB_FAULT_UPDATE();
goto redo;
}
if (ret == -EINVAL) {
/* printc("cli:thd %d lock_component_release return EINVAL\n", cos_get_thd_id()); */
/* rd_recover_state(rd); */
/* goto redo; */
ret = 0;
}
/* printc("cli:thd %d lock_component_release return %d\n", cos_get_thd_id(), ret); */
return ret;
}
CSTUB_FN(vaddr_t, mman_get_page) (struct usr_inv_cap *uc,
spdid_t spdid, vaddr_t addr, int flags)
{
long fault = 0;
long ret;
if (first == 0 && cos_spd_id() != 5) {
cvect_init_static(&rec_mm_vect);
cvect_init_static(&parent_rec_mm_vect);
first = 1;
}
unsigned long long start, end;
redo:
if (cos_spd_id() != 5) {
printc("cli: (spd %ld) call mman_get_page addr %p\n",
cos_spd_id(), addr);
}
CSTUB_INVOKE(ret, fault, uc, 3, spdid,addr, flags);
if (unlikely (fault)){
printc("found a fault in mman_get_page!!!!!\n");
CSTUB_FAULT_UPDATE();
goto redo;
}
if (cos_spd_id() != 5) {
printc("cli: (in spd %ld) mman_get_page return ret %p\n",
cos_spd_id(), ret);
}
return ret;
}
CSTUB_FN(td_t, tsplit)(struct usr_inv_cap *uc,
spdid_t spdid, td_t tid, char * param,
int len, tor_flags_t tflags, long evtid)
{
long fault = 0;
td_t ret;
struct __sg_tsplit_data *d;
cbuf_t cb;
int sz = len + sizeof(struct __sg_tsplit_data);
assert(param && len >= 0);
assert(param[len] == '\0');
d = cbuf_alloc_ext(sz, &cb, CBUF_TMEM);
if (!d) return -6;
d->tid = tid;
d->tflags = tflags;
d->evtid = evtid;
d->len[0] = 0;
d->len[1] = len;
memcpy(&d->data[0], param, len + 1);
CSTUB_INVOKE(ret, fault, uc, 3, spdid, cb, sz);
cbuf_free(cb);
return ret;
}
CSTUB_FN(int, twrite)(struct usr_inv_cap *uc,
spdid_t spdid, td_t td, int cbid, int sz)
{
int ret;
long fault = 0;
CSTUB_INVOKE(ret, fault, uc, 4, spdid, td, cbid, sz);
return ret;
}
CSTUB_FN(unsigned long, lock_component_alloc) (struct usr_inv_cap *uc,
spdid_t spdid)
{
long fault;
unsigned long ret;
struct rec_data_lk *rd = NULL;
unsigned long ser_lkid, cli_lkid;
if (first == 0) {
cos_map_init_static(&uniq_lkids);
first = 1;
}
#ifdef BENCHMARK_MEAS_CREATION_TIME
rdtscll(meas_start);
#endif
redo:
#ifdef BENCHMARK_MEAS_ALLOC
rdtscll(meas_end);
if (test_flag) {
test_flag = 0;
printc("recovery a lock cost: %llu\n", meas_end - meas_start);
}
#endif
CSTUB_INVOKE(ret, fault, uc, 1, spdid);
if (unlikely (fault)){
#ifdef BENCHMARK_MEAS_ALLOC
test_flag = 1;
rdtscll(meas_start);
#endif
CSTUB_FAULT_UPDATE();
goto redo;
}
assert(ret > 0);
cli_lkid = rdlk_alloc();
assert(cli_lkid >= 1);
rd = rdlk_lookup(cli_lkid);
assert(rd);
rd_cons(rd, cos_spd_id(), cli_lkid, ret, LOCK_ALLOC);
ret = cli_lkid;
#ifdef BENCHMARK_MEAS_CREATION_TIME
rdtscll(meas_end);
printc("creating a lock costs %llu\n", meas_end - meas_start);
#endif
return ret;
}
transition|terminal
// block_cli_if_invoke pred 6 end
// block_cli_if_invoke 6 start
static inline int block_cli_if_invoke_IDL_fname(IDL_parsdecl, int ret, long *fault, struct usr_inv_cap *uc) {
long __fault = 0;
CSTUB_INVOKE(ret, __fault, uc, IDL_pars_len, IDL_params);
*fault = __fault;
return ret;
}
__attribute__((regparm(1))) int
SS_ipc_client_marshal_args(struct usr_inv_cap *uc, long p0, long p1, long p2, long p3)
{
int ret, done;
do {
CSTUB_INVOKE(ret, done, uc, 4, p0, p1, p2, p3);
} while (unlikely(done != 1));
return ret;
}
CSTUB_FN(int, lock_component_take) (struct usr_inv_cap *uc,
spdid_t spdid,
unsigned long lock_id, unsigned short int thd)
{
long fault = 0;
int ret;
struct rec_data_lk *rd = NULL;
redo:
rd = rd_update(lock_id, LOCK_TAKE);
assert(rd);
#ifdef BENCHMARK_MEAS_TAKE
rdtscll(meas_end);
/* printc("now take again(thd %d, end %llu)!!!!\n", cos_get_thd_id(), meas_end); */
if (test_flag) {
test_flag = 0;
printc("recovery a lock cost: %llu\n", meas_end - meas_start);
}
#endif
CSTUB_INVOKE(ret, fault, uc, 3, spdid, rd->s_lkid, thd);
if (unlikely (fault)){
/* printc("cli:thd %d see a fault in lock_component_take!\n", cos_get_thd_id()); */
lock_component_take_ubenchmark_flag = 1;
rdtscll(ubenchmark_start);
#ifdef BENCHMARK_MEAS_TAKE
test_flag = 1;
rdtscll(meas_start);
/* printc("a fault(thd %d start %llu)!!!!\n", cos_get_thd_id(), meas_start); */
#endif
CSTUB_FAULT_UPDATE();
goto redo;
/* rd = rd_update(lock_id, LOCK_TAKE); */
/* ret = 0; */
/* rdtscll(ubenchmark_end); */
/* if (lock_component_take_ubenchmark_flag) { */
/* lock_component_take_ubenchmark_flag = 0; */
/* printc */
/* ("lock_component_take(C3):recover per object end-end cost: %llu\n", */
/* ubenchmark_end - ubenchmark_start); */
/* } */
}
if (ret == -EINVAL) {
/* printc("cli:thd %d lock_component_take return EINVAL\n", cos_get_thd_id()); */
rd_recover_state(rd);
goto redo;
}
/* printc("cli:thd %d lock_component_take return %d\n", cos_get_thd_id(), ret); */
return ret;
}
static inline int block_cli_if_invoke_sched_wakeup(spdid_t spdid, u16_t thdid,
int ret, long *fault,
struct usr_inv_cap *uc)
{
long __fault = 0;
CSTUB_INVOKE(ret, __fault, uc, 2, spdid, thdid);
*fault = __fault;
return ret;
}
// block_cli_if_invoke pred 3 start
desc_dep_create_none
creation
// block_cli_if_invoke pred 3 end
// block_cli_if_invoke 3 start
static inline int block_cli_if_invoke_IDL_fname(IDL_parsdecl, int ret, long *fault, struct usr_inv_cap *uc) {
long __fault = 0;
CSTUB_INVOKE(ret, __fault, uc, IDL_pars_len, IDL_params);
*fault = __fault;
return ret;
}
static inline int block_cli_if_invoke_sched_timeout(spdid_t spdid, ul_t amnt,
int ret, long *fault,
struct usr_inv_cap *uc)
{
long __fault = 0;
CSTUB_INVOKE(ret, __fault, uc, 2, spdid, amnt);
*fault = __fault;
return ret;
}
CSTUB_FN(int, twritep)(struct usr_inv_cap *uc,
spdid_t spdid, td_t td, int cbuf_id, int start, int sz)
{
int ret;
long fault = 0;
int temp = (td << 16) | (cbuf_id & 0xFFFF);
CSTUB_INVOKE(ret, fault, uc, 4, spdid, temp, start, sz);
return ret;
}
transition|terminal
// block_cli_if_invoke pred 5 end
// block_cli_if_invoke 5 start
static inline int block_cli_if_invoke_IDL_fname(IDL_parsdecl, int ret, long *fault, struct usr_inv_cap *uc) {
struct desc_track *desc = call_desc_lookup(IDL_id);
long __fault = 0;
if (desc) { // might be created in the same component
CSTUB_INVOKE(ret, __fault, uc, IDL_pars_len, IDL_server_id_params);
} else { // might be created in different component
CSTUB_INVOKE(ret, __fault, uc, IDL_pars_len, IDL_params);
if (ret == -1) { // desc not exist TODO: change to error code
block_cli_if_recover(IDL_id);// need upcall
assert((desc = call_desc_lookup(IDL_id)));
CSTUB_INVOKE(ret, __fault, uc, IDL_pars_len, IDL_params);
}
}
*fault = __fault;
return ret;
}
static inline int block_cli_if_invoke_sched_block(spdid_t spdid,
u16_t dependency_thd, int ret,
long *fault,
struct usr_inv_cap *uc)
{
long __fault = 0;
CSTUB_INVOKE(ret, __fault, uc, 2, spdid, dependency_thd);
*fault = __fault;
return ret;
}
static inline int block_cli_if_invoke_sched_component_take(spdid_t spdid,
int ret, long *fault,
struct usr_inv_cap
*uc)
{
long __fault = 0;
CSTUB_INVOKE(ret, __fault, uc, 1, spdid);
*fault = __fault;
return ret;
}
static inline int block_cli_if_invoke_sched_create_thd(spdid_t spdid,
u32_t sched_param0,
u32_t sched_param1,
u32_t sched_param2,
int ret, long *fault,
struct usr_inv_cap *uc)
{
long __fault = 0;
CSTUB_INVOKE(ret, __fault, uc, 4, spdid, sched_param0, sched_param1,
sched_param2);
*fault = __fault;
return ret;
}
static inline int block_cli_if_invoke_evt_trigger(spdid_t spdid, long evtid,
int ret, long *fault,
struct usr_inv_cap *uc)
{
long __fault = 0;
struct desc_track *desc = call_desc_lookup(evtid);
//if (desc) { // might be created in the same component
// CSTUB_INVOKE(ret, __fault, uc, 2, spdid, evtid);
//} else { // might be created in different component
CSTUB_INVOKE(ret, __fault, uc, 2, spdid, evtid);
if (ret == -1) { // desc not exist TODO: change to error code
block_cli_if_recover(evtid); // need upcall
assert((desc = call_desc_lookup(evtid)));
CSTUB_INVOKE(ret, __fault, uc, 2, spdid, evtid);
}
*fault = __fault;
return ret;
}
CSTUB_FN(vaddr_t, mman_revoke_page) (struct usr_inv_cap *uc,
spdid_t spdid, vaddr_t addr, int flags)
{
long fault = 0;
long ret;
struct rec_data_mm *rd = NULL;
if (first == 0 && cos_spd_id() != 5) {
cvect_init_static(&rec_mm_vect);
cvect_init_static(&parent_rec_mm_vect);
first = 1;
}
if (cos_spd_id() == 5) goto con;
redo:
rd_update(addr, PAGE_STATE_REVOKE);
printc("cli: mman_revoke_page 1\n");
con:
CSTUB_INVOKE(ret, fault, uc, 3, spdid, addr, flags);
if (unlikely (fault)){
printc("found a fault in mman_revoke_page!!!!\n");
CSTUB_FAULT_UPDATE();
goto redo;
}
if (cos_spd_id() == 5) goto done;
if (ret == -EINVAL) {
rd_update_subtree(addr, PAGE_STATE_REVOKE);
goto redo;
}
/* here is one issue: if we always remove all tracking
* descriptors here, a page that was aliased (and tracked) in
* another component might not be removed explicitly through
* the revoke functoin. So we do non remove the descriptors*/
/* rd_remove(addr);*/
/* revoke does not reomve itself, only subtree. So the created
* rd is not reomved here. release_page does.*/
/* rdmm_dealloc(rd); */
done:
printc("cli: mman_revoke_page return %d\n", ret);
return ret;
}
static inline int block_cli_if_invoke_evt_split(spdid_t spdid,
long parent_evtid, int grp,
int ret, long *fault,
struct usr_inv_cap *uc)
{
struct desc_track *parent_desc = NULL;
if ((parent_evtid > 1)
&& (parent_desc = call_desc_lookup(parent_evtid))) {
parent_evtid = parent_desc->evtid;
}
long __fault = 0;
CSTUB_INVOKE(ret, __fault, uc, 3, spdid, parent_evtid, grp);
*fault = __fault;
return ret;
}
CSTUB_FN(int, tmerge)(struct usr_inv_cap *uc, spdid_t spdid, td_t td,
td_t td_into, char * param, int len)
{
long fault = 0;
td_t ret;
struct __sg_tmerge_data *d;
struct rec_data_tor *rd;
cbuf_t cb;
int sz = len + sizeof(struct __sg_tmerge_data);
/* printc("<<< rtorrent In: call tmerge (thread %d) >>>\n", cos_get_thd_id()); */
assert(param && len > 0);
assert(param[len] == '\0');
redo:
/* printc("<<< In: call tmerge (thread %d) >>>\n", cos_get_thd_id()); */
rd = rd_update(td, STATE_TMERGE);
assert(rd);
d = cbuf_alloc(sz, &cb);
if (!d) return -1;
/* printc("c: tmerge td %d (server td %d) len %d param %s\n", td, rd->s_tid, len, param); */
d->td = rd->s_tid; /* actual server side torrent id */
d->td_into = td_into;
d->len[0] = 0;
d->len[1] = len;
memcpy(&d->data[0], param, len);
CSTUB_INVOKE(ret, fault, uc, 3, spdid, cb, sz);
if (unlikely(fault)) {
CSTUB_FAULT_UPDATE();
cbuf_free(cb);
goto redo;
}
cbuf_free(cb);
if (!ret) map_rd_delete(rd->c_tid);
return ret;
}
// block_cli_if_invoke pred 2 start
desc_dep_create_diff
creation
// block_cli_if_invoke pred 2 end
// block_cli_if_invoke 2 start
static inline int block_cli_if_invoke_IDL_fname(IDL_parsdecl, int ret, long *fault, struct usr_inv_cap *uc) {
struct desc_track *parent_desc = NULL;
if ((IDL_parent_id > 1) && (parent_desc = call_desc_lookup(IDL_parent_id))) {
IDL_parent_id = parent_desc->IDL_server_id;
} /* else { // td_root, or in a different component */
/* IDL_parent_id = IDL_parent_id; */
/* } */
long __fault = 0;
CSTUB_INVOKE(ret, __fault, uc, IDL_pars_len, IDL_params);
*fault = __fault;
return ret;
}
CSTUB_FN(int, trmeta)(struct usr_inv_cap *uc,
spdid_t spdid, td_t td, const char *key,
unsigned int klen, char *retval, unsigned int max_rval_len)
{
int ret;
long fault = 0;
cbuf_t cb;
int sz = sizeof(struct __sg_trmeta_data) + klen + max_rval_len + 1;
struct __sg_trmeta_data *d;
struct rec_data_tor *rd;
assert(key && retval && klen > 0 && max_rval_len > 0);
assert(key[klen] == '\0' && sz <= PAGE_SIZE);
redo:
printc("<<< In: call trmeta (thread %d) >>>\n", cos_get_thd_id());
rd = rd_update(td, STATE_TRMETA);
assert(rd);
d = cbuf_alloc(sz, &cb);
if (!d) return -1;
d->td = rd->s_tid;
d->klen = klen;
d->retval_len = max_rval_len;
memcpy(&d->data[0], key, klen + 1);
CSTUB_INVOKE(ret, fault, uc, 3, spdid, cb, sz);
if (unlikely(fault)) {
CSTUB_FAULT_UPDATE();
goto redo;
}
if (ret >= 0) {
if ((unsigned int)ret > max_rval_len) { // as ret >= 0, cast it to unsigned int to omit compiler warning
cbuf_free(cb);
return -EIO;
}
memcpy(retval, &d->data[klen + 1], ret + 1);
}
cbuf_free(cb);
return ret;
}
CSTUB_FN(int, lock_component_pretake) (struct usr_inv_cap *uc,
spdid_t spdid, unsigned long lock_id,
unsigned short int thd)
{
long fault = 0;
int ret;
struct rec_data_lk *rd = NULL;
redo:
rd = rd_update(lock_id, LOCK_PRETAKE);
assert(rd);
#ifdef BENCHMARK_MEAS_PRETAKE
rdtscll(meas_end);
if (test_flag) {
test_flag = 0;
printc("recovery a lock cost: %llu\n", meas_end - meas_start);
}
#endif
CSTUB_INVOKE(ret, fault, uc, 3, spdid, rd->s_lkid, thd);
if (unlikely(fault)){
printc("cli:thd %d see a fault in lock_component_pretake!\n",
cos_get_thd_id());
#ifdef BENCHMARK_MEAS_PRETAKE
test_flag = 1;
rdtscll(meas_start);
#endif
CSTUB_FAULT_UPDATE();
goto redo; // update the generation number
}
if (ret == -EINVAL) {
/* printc("cli:thd %d lock_component_pretake return EINVAL\n", cos_get_thd_id()); */
rd_recover_state(rd);
goto redo;
}
/* printc("cli:thd %d lock_component_pretake return %d\n", cos_get_thd_id(), ret); */
return ret;
}
CSTUB_FN(int, twmeta)(struct usr_inv_cap *uc,
spdid_t spdid, td_t td, const char *key,
unsigned int klen, const char *val, unsigned int vlen)
{
int ret;
long fault = 0;
cbuf_t cb;
int sz = sizeof(struct __sg_twmeta_data) + klen + vlen + 1;
struct __sg_twmeta_data *d;
struct rec_data_tor *rd;
assert(key && val && klen > 0 && vlen > 0);
assert(key[klen] == '\0' && val[vlen] == '\0' && sz <= PAGE_SIZE);
redo:
printc("<<< In: call twmeta (thread %d) >>>\n", cos_get_thd_id());
rd = rd_update(td, STATE_TWMETA);
assert(rd);
d = cbuf_alloc(sz, &cb);
if (!d) assert(0); //return -1;
d->td = td; // do not pass rd->s_tid since this is only for recovery
d->klen = klen;
d->vlen = vlen;
memcpy(&d->data[0], key, klen + 1);
memcpy(&d->data[klen + 1], val, vlen + 1);
CSTUB_INVOKE(ret, fault, uc, 3, spdid, cb, sz);
if (unlikely(fault)) {
CSTUB_FAULT_UPDATE();
goto redo;
}
cbuf_free(cb);
return ret;
}
CSTUB_FN(int, twritep)(struct usr_inv_cap *uc,
spdid_t spdid, td_t td, int cb, int sz)
{
long fault = 0;
td_t ret;
struct rec_data_tor *rd;
redo:
/* printc("<<< In: call twrite (thread %d) >>>\n", cos_get_thd_id()); */
rd = rd_update(td, STATE_TWRITE);
assert(rd);
CSTUB_INVOKE(ret, fault, uc, 4, spdid, rd->s_tid, cb, sz);
if (unlikely(fault)) {
CSTUB_FAULT_UPDATE();
goto redo;
}
/* we can not save the infor here since we need track the offset and
* uniq file id any way */
return ret;
}
CSTUB_FN(td_t, tsplit)(struct usr_inv_cap *uc,
spdid_t spdid, td_t parent_tid, char * param,
int len, tor_flags_t tflags, long evtid)
{
long fault = 0;
td_t ret;
struct __sg_tsplit_data *d = NULL;
cbuf_t cb = 0;
struct rec_data_tor *rd = NULL;
int sz = len + sizeof(struct __sg_tsplit_data);
td_t curr_ptid = 0;
td_t cli_tid = 0;
td_t ser_tid = 0;
/* printc("cli: tsplit passed in param %s\n", param); */
assert(parent_tid >= 1);
assert(param && len >= 0);
assert(param[len] == '\0');
if (first == 0) {
cos_map_init_static(&uniq_tids);
first = 1;
}
redo:
/* printc("<<< cli rtorrent: call tsplit (thread %d, spd %ld and parent tid %d) >>>\n", */
/* cos_get_thd_id(), cos_spd_id(), parent_tid); */
rd = rd_update(parent_tid, STATE_TSPLIT_PARENT);
if (rd) {
curr_ptid = rd->s_tid;
} else {
curr_ptid = parent_tid;
}
/* printc("<<< In: call tsplit (thread %d, , spd %ld and curr_parent tid %d) >>>\n", */
/* cos_get_thd_id(), cos_spd_id(), curr_ptid); */
d = cbuf_alloc(sz, &cb);
assert(d);
if (!d) return -1;
d->parent_tid = curr_ptid;
d->tflags = tflags;
d->evtid = evtid;
d->len[0] = 0;
d->len[1] = len;
memcpy(&d->data[0], param, len + 1);
CSTUB_INVOKE(ret, fault, uc, 3, spdid, cb, sz);
if (unlikely(fault)) {
CSTUB_FAULT_UPDATE();
memset(&d->data[0], 0, len);
cbuf_free(cb);
printc("tsplit found a fault and ready to go to redo\n");
goto redo;
}
cbuf_free(cb);
ser_tid = ret;
/* printc("passed in param %s (ser_tid %d)\n", param, ser_tid); */
assert(ser_tid >= 1);
char *l_param = "";
if (len > 0) {
l_param = param_save(param, len);
assert(l_param);
}
cli_tid = map_rd_create();
assert(cli_tid >= 2);
rd = map_rd_lookup(cli_tid);
assert(rd);
rd_cons(rd, curr_ptid, cli_tid, ser_tid, l_param, len, tflags, evtid);
/* printc("tsplit done!!! return new client tid %d\n\n", cli_tid); */
return cli_tid;
}
