int mirroring_receive(phv_data_t *phv, int *metadata_recirc, void *pkt_data,
int len, uint64_t packet_id,
pkt_instance_type_t instance_type) {
int mirror_id = fields_get_clone_spec(phv);
coalescing_session_t *coalescing_session = get_coalescing_session(mirror_id);
if(NULL != coalescing_session) {
RMT_LOG(P4_LOG_LEVEL_VERBOSE,
"Queuing digest for mirror %d %d\n", mirror_id, *metadata_recirc);
pkt_digest_t *pkt_digest = malloc(sizeof(pkt_digest_t));
pkt_digest->mirror_id = mirror_id;
pkt_digest->length = 0;
deparser_extract_digest(phv, metadata_recirc, pkt_digest->buffer, &(pkt_digest->length));
cb_write(rmt_mirroring_cb, pkt_digest);
}
else if(NULL != get_mirroring_mapping(mirror_id)) {
uint8_t *metadata;
deparser_produce_metadata(phv, &metadata);
//:: if enable_intrinsic:
//:: bytes = 0
//:: for header_instance in ordered_header_instances_non_virtual:
//:: h_info = header_info[header_instance]
//:: is_metadata = h_info["is_metadata"]
//:: if is_metadata: bytes += h_info["byte_width_phv"]
//:: #endfor
uint8_t extracted_metadata[${bytes}];
metadata_extract(extracted_metadata, metadata, NULL); /* NULL ? */
// do not set deflection_flag and dod bits for mirrored packet
metadata_set_deflection_flag(extracted_metadata, 0);
metadata_set_deflect_on_drop(extracted_metadata, 0);
metadata_dump(metadata, extracted_metadata);
//:: #endif
return queuing_receive(metadata, metadata_recirc, pkt_data, len, packet_id,
instance_type);
}
else {
RMT_LOG(P4_LOG_LEVEL_WARN,
"Received packet with invalid mirror id %d\n", mirror_id);
}
free(pkt_data);
free(metadata_recirc);
return 0;
}
int mirroring_receive(phv_data_t *phv, int *metadata_recirc, void *pkt_data,
int len, uint64_t packet_id,
pkt_instance_type_t instance_type) {
int mirror_id = fields_get_clone_spec(phv);
if(NULL != get_mirroring_mapping(mirror_id)) {
uint8_t *metadata;
deparser_produce_metadata(phv, &metadata);
return queuing_receive(metadata, metadata_recirc, pkt_data, len, packet_id,
instance_type);
}
else {
RMT_LOG(P4_LOG_LEVEL_WARN,
"Received packet with invalid mirror id %d\n", mirror_id);
}
free(pkt_data);
free(metadata_recirc);
return 0;
}
static void *processing_loop_egress(void *arg) {
pipeline_t *pipeline = (pipeline_t *) arg;
circular_buffer_t *cb_in = pipeline->cb_in;
//Added by Ming
#ifdef SWITCH_CPU_DEBUG
int i;
#endif
#ifdef RATE_LIMITING
struct timeval tv;
gettimeofday(&tv, NULL);
uint64_t next_deque = tv.tv_sec * 1000000 + tv.tv_usec + read_atomic_int(&USEC_INTERVAL);
#endif
while(1) {
#ifdef RATE_LIMITING
struct timeval tv;
gettimeofday(&tv, NULL);
uint64_t now_us = tv.tv_sec * 1000000 + tv.tv_usec;
//RMT_LOG(P4_LOG_LEVEL_TRACE, "next_deque %lu, now_us %lu\n", next_deque, now_us);
if(next_deque > now_us) {
usleep(next_deque - now_us);
}
next_deque += read_atomic_int(&USEC_INTERVAL);
#endif
egress_pkt_t *e_pkt = (egress_pkt_t *) cb_read(cb_in);
if (e_pkt == NULL) continue;
buffered_pkt_t *b_pkt = &e_pkt->pkt;
RMT_LOG(P4_LOG_LEVEL_TRACE, "egress_pipeline: packet dequeued\n");
phv_clean(pipeline->phv);
pipeline->phv->packet_id = b_pkt->pkt_id;
parser_parse_pkt(pipeline->phv,
b_pkt->pkt_data, b_pkt->pkt_len,
pipeline->parse_state_start);
parser_parse_metadata(pipeline->phv,
e_pkt->metadata, e_pkt->metadata_recirc);
assert(!fields_get_clone_spec(pipeline->phv));
//:: if enable_intrinsic:
/* Set dequeue metadata */
fields_set_deq_qdepth(pipeline->phv, cb_count(cb_in));
uint64_t enq_timestamp = fields_get_enq_timestamp(pipeline->phv);
fields_set_deq_timedelta(pipeline->phv, get_timestamp()-enq_timestamp);
//:: #endif
fields_set_instance_type(pipeline->phv, e_pkt->pkt.instance_type);
free(e_pkt->metadata);
free(e_pkt->metadata_recirc);
if(pipeline->table_entry_fn) /* empty egress pipeline ? */
pipeline->table_entry_fn(pipeline->phv);
uint8_t *pkt_data;
int pkt_len;
/* EGRESS MIRRORING */
if(fields_get_clone_spec(pipeline->phv)) {
RMT_LOG(P4_LOG_LEVEL_VERBOSE, "Egress mirroring\n");
pipeline->deparse_fn(pipeline->phv, &pkt_data, &pkt_len);
egress_cloning(pipeline, pkt_data, pkt_len, e_pkt->pkt.pkt_id);
fields_set_clone_spec(pipeline->phv, 0);
}
update_checksums(pipeline->phv);
pipeline->deparse_fn(pipeline->phv, &pkt_data, &pkt_len);
free(b_pkt->pkt_data);
//:: if "egress_drop_ctl" in extra_metadata_name_map:
// program uses the separate egress_drop_ctl register
// a non-zero value means drop
if(pipeline->phv->deparser_drop_signal ||
metadata_get_egress_drop_ctl(metadata)) {
//:: else:
if(pipeline->phv->deparser_drop_signal){
//:: #endif
RMT_LOG(P4_LOG_LEVEL_VERBOSE, "dropping packet at egress\n");
free(e_pkt);
continue;
}
int egress = fields_get_egress_port(pipeline->phv);
if(pipeline->phv->truncated_length && (pipeline->phv->truncated_length < pkt_len))
pkt_len = pipeline->phv->truncated_length;
#ifdef SWITCH_CPU_DEBUG
RMT_LOG(P4_LOG_LEVEL_TRACE, "Ming Packet Data: %d\n", b_pkt->pkt_len);
for (i = 0; i < 21; i++)
RMT_LOG(P4_LOG_LEVEL_TRACE, "%x ", b_pkt->pkt_data[i]);
RMT_LOG(P4_LOG_LEVEL_TRACE, "\n");
#endif
pkt_manager_transmit(egress, pkt_data, pkt_len, b_pkt->pkt_id);
free(e_pkt);
}
return NULL;
}
/* name has to be ingress or egress */
pipeline_t *pipeline_create(int id) {
pipeline_t *pipeline = malloc(sizeof(pipeline_t));
pipeline->name = "egress";
#ifdef RATE_LIMITING
pipeline->cb_in = cb_init(read_atomic_int(&EGRESS_CB_SIZE), CB_WRITE_DROP, CB_READ_RETURN);
#else
pipeline->cb_in = cb_init(read_atomic_int(&EGRESS_CB_SIZE), CB_WRITE_BLOCK, CB_READ_BLOCK);
#endif
pipeline->parse_state_start = parse_state_start;
//:: if egress_entry_table is not None:
pipeline->table_entry_fn = tables_apply_${egress_entry_table};
//:: else:
pipeline->table_entry_fn = NULL;
//:: #endif
pipeline->deparse_fn = deparser_produce_pkt;
pipeline->phv = phv_init(NB_THREADS_PER_PIPELINE + id, RMT_PIPELINE_EGRESS);
/* packet processing loop */
pthread_create(&pipeline->processing_thread, NULL,
processing_loop_egress, (void *) pipeline);
return pipeline;
}
