--- /dev/null
+/******************************************************************************
+*
+* Copyright (c) 2020 Intel.
+*
+* Licensed under the Apache License, Version 2.0 (the "License");
+* you may not use this file except in compliance with the License.
+* You may obtain a copy of the License at
+*
+* http://www.apache.org/licenses/LICENSE-2.0
+*
+* Unless required by applicable law or agreed to in writing, software
+* distributed under the License is distributed on an "AS IS" BASIS,
+* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+* See the License for the specific language governing permissions and
+* limitations under the License.
+*
+*******************************************************************************/
+
+/**
+ * @brief XRAN Callback processing functionality and helper functions
+ * @file xran_cb_proc.c
+ * @ingroup group_source_xran
+ * @author Intel Corporation
+ **/
+
+#include <unistd.h>
+#include <stdio.h>
+#include <immintrin.h>
+#include <rte_common.h>
+#include <rte_eal.h>
+#include <rte_errno.h>
+#include <rte_lcore.h>
+#include <rte_cycles.h>
+#include <rte_memory.h>
+#include <rte_memzone.h>
+#include <rte_mbuf.h>
+#include <rte_timer.h>
+
+#include "ethdi.h"
+#include "xran_fh_o_du.h"
+#include "xran_main.h"
+#include "xran_dev.h"
+#include "xran_common.h"
+#include "xran_cb_proc.h"
+#include "xran_mlog_lnx.h"
+#include "xran_lib_mlog_tasks_id.h"
+#include "xran_printf.h"
+
+typedef void (*rx_dpdk_sym_cb_fn)(struct rte_timer *tim, void *arg);
+
+void xran_timer_arm(struct rte_timer *tim, void* arg, void *p_dev_ctx)
+{
+ struct xran_device_ctx * p_xran_dev_ctx = (struct xran_device_ctx *)p_dev_ctx;
+ uint64_t t3 = MLogTick();
+
+ if (xran_if_current_state == XRAN_RUNNING){
+ rte_timer_cb_t fct = (rte_timer_cb_t)arg;
+ rte_timer_reset_sync(tim, 0, SINGLE, p_xran_dev_ctx->fh_init.io_cfg.timing_core, fct, p_dev_ctx);
+ }
+ MLogTask(PID_TIME_ARM_TIMER, t3, MLogTick());
+}
+
+void xran_timer_arm_cp_dl(struct rte_timer *tim, void* arg, void *p_dev_ctx)
+{
+ struct xran_device_ctx * p_xran_dev_ctx = (struct xran_device_ctx *)p_dev_ctx;
+ uint64_t t3 = MLogTick();
+
+ unsigned tim_lcore = xran_schedule_to_worker(XRAN_JOB_TYPE_CP_DL, p_xran_dev_ctx);
+
+ if (xran_if_current_state == XRAN_RUNNING){
+ rte_timer_cb_t fct = (rte_timer_cb_t)arg;
+ rte_timer_reset_sync(tim, 0, SINGLE, tim_lcore, fct, p_dev_ctx);
+ }
+ MLogTask(PID_TIME_ARM_TIMER, t3, MLogTick());
+}
+
+void xran_timer_arm_cp_ul(struct rte_timer *tim, void* arg, void *p_dev_ctx)
+{
+ struct xran_device_ctx * p_xran_dev_ctx = (struct xran_device_ctx *)p_dev_ctx;
+ uint64_t t3 = MLogTick();
+
+ unsigned tim_lcore = xran_schedule_to_worker(XRAN_JOB_TYPE_CP_UL, p_xran_dev_ctx);
+
+ if (xran_if_current_state == XRAN_RUNNING){
+ rte_timer_cb_t fct = (rte_timer_cb_t)arg;
+ rte_timer_reset_sync(tim, 0, SINGLE, tim_lcore, fct, p_dev_ctx);
+ }
+ MLogTask(PID_TIME_ARM_TIMER, t3, MLogTick());
+}
+
+void xran_timer_arm_for_deadline(struct rte_timer *tim, void* arg, void *p_dev_ctx)
+{
+ struct xran_device_ctx * p_xran_dev_ctx = (struct xran_device_ctx *)p_dev_ctx;
+ uint64_t t3 = MLogTick();
+
+ unsigned tim_lcore = xran_schedule_to_worker(XRAN_JOB_TYPE_DEADLINE, p_xran_dev_ctx);
+
+ int32_t rx_tti;
+ int32_t cc_id;
+ uint32_t nFrameIdx;
+ uint32_t nSubframeIdx;
+ uint32_t nSlotIdx;
+ uint64_t nSecond;
+
+ xran_get_slot_idx(p_xran_dev_ctx->xran_port_id, &nFrameIdx, &nSubframeIdx, &nSlotIdx, &nSecond);
+ rx_tti = nFrameIdx*SUBFRAMES_PER_SYSTEMFRAME*SLOTNUM_PER_SUBFRAME(p_xran_dev_ctx->interval_us_local)
+ + nSubframeIdx*SLOTNUM_PER_SUBFRAME(p_xran_dev_ctx->interval_us_local)
+ + nSlotIdx;
+
+ p_xran_dev_ctx->cb_timer_ctx[p_xran_dev_ctx->timer_put % MAX_CB_TIMER_CTX].tti_to_process = rx_tti;
+ if (xran_if_current_state == XRAN_RUNNING){
+ rte_timer_cb_t fct = (rte_timer_cb_t)arg;
+ rte_timer_reset_sync(tim, 0, SINGLE, tim_lcore, fct, p_xran_dev_ctx);
+ }
+
+ MLogTask(PID_TIME_ARM_TIMER_DEADLINE, t3, MLogTick());
+}
+
+void xran_timer_arm_user_cb(struct rte_timer *tim, void* arg, void *p_ctx)
+{
+ struct cb_user_per_sym_ctx* p_sym_cb_ctx = (struct cb_user_per_sym_ctx *)p_ctx;
+ struct xran_device_ctx * p_xran_dev_ctx = (struct xran_device_ctx *)p_sym_cb_ctx->p_dev;
+ uint64_t t3 = MLogTick();
+
+ unsigned tim_lcore = xran_schedule_to_worker(XRAN_JOB_TYPE_SYM_CB, NULL);
+
+ int32_t rx_tti;
+ int32_t cc_id;
+ uint32_t nFrameIdx = 0;
+ uint32_t nSubframeIdx = 0;
+ uint32_t nSlotIdx = 0;
+ uint64_t nSecond = 0;
+
+ xran_get_slot_idx(p_xran_dev_ctx->xran_port_id, &nFrameIdx, &nSubframeIdx, &nSlotIdx, &nSecond);
+ rx_tti = nFrameIdx*SUBFRAMES_PER_SYSTEMFRAME*SLOTNUM_PER_SUBFRAME(p_xran_dev_ctx->interval_us_local)
+ + nSubframeIdx*SLOTNUM_PER_SUBFRAME(p_xran_dev_ctx->interval_us_local)
+ + nSlotIdx;
+
+ p_sym_cb_ctx->user_cb_timer_ctx[p_sym_cb_ctx->user_timer_put % MAX_CB_TIMER_CTX].tti_to_process = rx_tti;
+ p_sym_cb_ctx->user_cb_timer_ctx[p_sym_cb_ctx->user_timer_put % MAX_CB_TIMER_CTX].ota_sym_idx = xran_lib_ota_sym_idx[p_xran_dev_ctx->xran_port_id];
+ p_sym_cb_ctx->user_cb_timer_ctx[p_sym_cb_ctx->user_timer_put % MAX_CB_TIMER_CTX].xran_sfn_at_sec_start = xran_getSfnSecStart();
+ p_sym_cb_ctx->user_cb_timer_ctx[p_sym_cb_ctx->user_timer_put % MAX_CB_TIMER_CTX].current_second = nSecond;
+
+ if (xran_if_current_state == XRAN_RUNNING){
+ rte_timer_cb_t fct = (rte_timer_cb_t)arg;
+ rte_timer_reset_sync(tim, 0, SINGLE, tim_lcore, fct, p_sym_cb_ctx);
+ if (++p_sym_cb_ctx->user_timer_put >= MAX_CB_TIMER_CTX)
+ p_sym_cb_ctx->user_timer_put = 0;
+ }
+
+ MLogTask(PID_TIME_ARM_USER_TIMER_DEADLINE, t3, MLogTick());
+}
+
+void xran_timer_arm_ex(struct rte_timer *tim, void* CbFct, void *CbArg, unsigned tim_lcore)
+{
+ uint64_t t3 = MLogTick();
+
+ if (xran_if_current_state == XRAN_RUNNING){
+ rte_timer_cb_t fct = (rte_timer_cb_t)CbFct;
+ rte_timer_reset_sync(tim, 0, SINGLE, tim_lcore, fct, CbArg);
+ }
+ MLogTask(PID_TIME_ARM_TIMER, t3, MLogTick());
+}
+
+int32_t
+xran_timing_create_cbs(void *args)
+{
+ int32_t res = XRAN_STATUS_SUCCESS;
+ int32_t do_reset = 0;
+ uint64_t t1 = 0;
+ int32_t result1,i,j;
+ uint32_t delay_cp_dl;
+ uint32_t delay_cp_ul;
+ uint32_t delay_up;
+ uint32_t time_diff_us;
+ uint32_t delay_cp2up;
+ uint32_t sym_cp_dl;
+ uint32_t sym_cp_ul;
+ uint32_t time_diff_nSymb;
+ int32_t sym_up;
+ struct xran_device_ctx * p_dev_ctx = (struct xran_device_ctx *)args;
+ uint64_t tWake = 0, tWakePrev = 0, tUsed = 0;
+ struct cb_elem_entry * cb_elm = NULL;
+ uint32_t interval_us_local = p_dev_ctx->interval_us_local;
+
+ /* ToS = Top of Second start +- 1.5us */
+ struct timespec ts;
+ char buff[100];
+
+ if (p_dev_ctx->fh_init.io_cfg.id == O_DU) {
+
+ delay_cp_dl = interval_us_local - p_dev_ctx->fh_cfg.T1a_max_cp_dl;
+ delay_cp_ul = interval_us_local - p_dev_ctx->fh_cfg.T1a_max_cp_ul;
+ delay_up = p_dev_ctx->fh_cfg.T1a_max_up;
+ time_diff_us = p_dev_ctx->fh_cfg.Ta4_max;
+
+ delay_cp2up = delay_up-delay_cp_dl;
+
+ sym_cp_dl = delay_cp_dl*1000/(interval_us_local*1000/N_SYM_PER_SLOT)+1;
+ sym_cp_ul = delay_cp_ul*1000/(interval_us_local*1000/N_SYM_PER_SLOT)+1;
+ time_diff_nSymb = time_diff_us*1000/(interval_us_local*1000/N_SYM_PER_SLOT);
+ p_dev_ctx->sym_up = sym_up = -(delay_up*1000/(interval_us_local*1000/N_SYM_PER_SLOT));
+ p_dev_ctx->sym_up_ul = time_diff_nSymb = (time_diff_us*1000/(interval_us_local*1000/N_SYM_PER_SLOT)+1);
+
+ printf("Start C-plane DL %d us after TTI [trigger on sym %d]\n", delay_cp_dl, sym_cp_dl);
+ printf("Start C-plane UL %d us after TTI [trigger on sym %d]\n", delay_cp_ul, sym_cp_ul);
+ printf("Start U-plane DL %d us before OTA [offset in sym %d]\n", delay_up, sym_up);
+ printf("Start U-plane UL %d us OTA [offset in sym %d]\n", time_diff_us, time_diff_nSymb);
+
+ printf("C-plane to U-plane delay %d us after TTI\n", delay_cp2up);
+ printf("Start Sym timer %ld ns\n", TX_TIMER_INTERVAL/N_SYM_PER_SLOT);
+
+ cb_elm = xran_create_cb(xran_timer_arm_cp_dl, tx_cp_dl_cb, (void*)p_dev_ctx);
+ if(cb_elm){
+ LIST_INSERT_HEAD(&p_dev_ctx->sym_cb_list_head[sym_cp_dl],
+ cb_elm,
+ pointers);
+ } else {
+ print_err("cb_elm is NULL\n");
+ res = XRAN_STATUS_FAIL;
+ goto err0;
+ }
+
+ cb_elm = xran_create_cb(xran_timer_arm_cp_ul, tx_cp_ul_cb, (void*)p_dev_ctx);
+ if(cb_elm){
+ LIST_INSERT_HEAD(&p_dev_ctx->sym_cb_list_head[sym_cp_ul],
+ cb_elm,
+ pointers);
+ } else {
+ print_err("cb_elm is NULL\n");
+ res = XRAN_STATUS_FAIL;
+ goto err0;
+ }
+
+ /* Full slot UL OTA + time_diff_us */
+ cb_elm = xran_create_cb(xran_timer_arm_for_deadline, rx_ul_deadline_full_cb, (void*)p_dev_ctx);
+ if(cb_elm){
+ LIST_INSERT_HEAD(&p_dev_ctx->sym_cb_list_head[time_diff_nSymb],
+ cb_elm,
+ pointers);
+ } else {
+ print_err("cb_elm is NULL\n");
+ res = XRAN_STATUS_FAIL;
+ goto err0;
+ }
+
+ /* Half slot UL OTA + time_diff_us*/
+ cb_elm = xran_create_cb(xran_timer_arm_for_deadline, rx_ul_deadline_half_cb, (void*)p_dev_ctx);
+ if(cb_elm){
+ LIST_INSERT_HEAD(&p_dev_ctx->sym_cb_list_head[time_diff_nSymb + N_SYM_PER_SLOT/2],
+ cb_elm,
+ pointers);
+ } else {
+ print_err("cb_elm is NULL\n");
+ res = XRAN_STATUS_FAIL;
+ goto err0;
+ }
+ } else { // APP_O_RU
+ /* calculate when to send UL U-plane */
+ delay_up = p_dev_ctx->fh_cfg.Ta3_min;
+ p_dev_ctx->sym_up = sym_up = delay_up*1000/(interval_us_local*1000/N_SYM_PER_SLOT)+1;
+ printf("Start UL U-plane %d us after OTA [offset in sym %d]\n", delay_up, sym_up);
+
+ /* calcualte when to Receive DL U-plane */
+ delay_up = p_dev_ctx->fh_cfg.T2a_max_up;
+ sym_up = delay_up*1000/(interval_us_local*1000/N_SYM_PER_SLOT)+1;
+ printf("Receive DL U-plane %d us after OTA [offset in sym %d]\n", delay_up, sym_up);
+
+ /* Full slot UL OTA + time_diff_us */
+ cb_elm = xran_create_cb(xran_timer_arm_for_deadline, rx_ul_deadline_full_cb, (void*)p_dev_ctx);
+ if(cb_elm){
+ LIST_INSERT_HEAD(&p_dev_ctx->sym_cb_list_head[sym_up],
+ cb_elm,
+ pointers);
+ } else {
+ print_err("cb_elm is NULL\n");
+ res = -1;
+ goto err0;
+ }
+
+ do {
+ timespec_get(&ts, TIME_UTC);
+ }while (ts.tv_nsec >1500);
+ struct tm * ptm = gmtime(&ts.tv_sec);
+ if(ptm){
+ strftime(buff, sizeof buff, "%D %T", ptm);
+ printf("RU: thread_run start time: %s.%09ld UTC [%d]\n", buff, ts.tv_nsec, interval_us_local);
+ }
+ }
+
+ return XRAN_STATUS_SUCCESS;
+
+ err0:
+ for (j = 0; j< XRAN_NUM_OF_SYMBOL_PER_SLOT; j++){
+ struct cb_elem_entry *cb_elm;
+ LIST_FOREACH(cb_elm, &p_dev_ctx->sym_cb_list_head[j], pointers){
+ if(cb_elm){
+ LIST_REMOVE(cb_elm, pointers);
+ xran_destroy_cb(cb_elm);
+ }
+ }
+ }
+
+ return XRAN_STATUS_FAIL;
+}
+int32_t
+xran_timing_destroy_cbs(void *args)
+{
+ int res = XRAN_STATUS_SUCCESS;
+ int32_t do_reset = 0;
+ uint64_t t1 = 0;
+ int32_t result1,i,j;
+ struct xran_device_ctx * p_dev_ctx = (struct xran_device_ctx *)args;
+ struct cb_elem_entry * cb_elm = NULL;
+
+ for (j = 0; j< XRAN_NUM_OF_SYMBOL_PER_SLOT; j++){
+ struct cb_elem_entry *cb_elm;
+ LIST_FOREACH(cb_elm, &p_dev_ctx->sym_cb_list_head[j], pointers){
+ if(cb_elm){
+ LIST_REMOVE(cb_elm, pointers);
+ xran_destroy_cb(cb_elm);
+ }
+ }
+ }
+
+ return XRAN_STATUS_SUCCESS;
+}
+
+static int32_t
+xran_reg_sym_cb_ota(struct xran_device_ctx * p_dev_ctx, xran_callback_sym_fn symCb, void * symCbParam, struct xran_sense_of_time* symCbTime, uint8_t symb,
+ struct cb_user_per_sym_ctx **p_sym_cb_ctx)
+{
+ int32_t ret = XRAN_STATUS_SUCCESS;
+ struct cb_user_per_sym_ctx *p_loc_sym_cb_ctx = &p_dev_ctx->symCbCtx[symb][XRAN_CB_SYM_OTA_TIME];
+ if(p_loc_sym_cb_ctx->status){
+ ret = XRAN_STATUS_RESOURCE;
+ print_err("timer sym %d type id %d was already created",symb, XRAN_CB_SYM_OTA_TIME);
+ return ret;
+ }
+ printf("requested symb %d OTA coresponds to symb %d OTA time\n", symb, symb);
+
+ p_loc_sym_cb_ctx->symb_num_req = symb;
+ p_loc_sym_cb_ctx->sym_diff = 0; /* OTA and Request Symb are the same */
+ p_loc_sym_cb_ctx->symb_num_ota = symb;
+ p_loc_sym_cb_ctx->cb_type_id = XRAN_CB_SYM_OTA_TIME;
+ p_loc_sym_cb_ctx->p_dev = p_dev_ctx;
+
+ p_loc_sym_cb_ctx->symCb = symCb;
+ p_loc_sym_cb_ctx->symCbParam = symCbParam;
+ p_loc_sym_cb_ctx->symCbTimeInfo = symCbTime;
+
+ p_loc_sym_cb_ctx->status = 1;
+
+ *p_sym_cb_ctx = p_loc_sym_cb_ctx;
+
+ return ret;
+}
+
+static int32_t
+xran_reg_sym_cb_rx_win_end(struct xran_device_ctx * p_dev_ctx, xran_callback_sym_fn symCb, void * symCbParam, struct xran_sense_of_time* symCbTime,
+ uint8_t symb, struct cb_user_per_sym_ctx **p_sym_cb_ctx)
+{
+ int32_t ret = XRAN_STATUS_SUCCESS;
+ struct cb_user_per_sym_ctx *p_loc_sym_cb_ctx = &p_dev_ctx->symCbCtx[symb][XRAN_CB_SYM_RX_WIN_END];
+ uint32_t time_diff_us = 0;
+ uint32_t time_diff_nSymb = 0;
+ uint32_t absolute_ota_sym = 0;
+ uint32_t interval_us_local = p_dev_ctx->interval_us_local;
+
+ if(p_loc_sym_cb_ctx->status) {
+ ret = XRAN_STATUS_RESOURCE;
+ print_err("timer sym %d type id %d was already created",symb, XRAN_CB_SYM_RX_WIN_END);
+ return ret;
+ }
+
+ time_diff_us = p_dev_ctx->fh_cfg.Ta4_max;
+ printf("RX WIN end Ta4_max is %d [us] where TTI is %d [us] \n", time_diff_us, interval_us_local);
+ time_diff_nSymb = time_diff_us*1000/(interval_us_local*1000/N_SYM_PER_SLOT);
+ if ((time_diff_nSymb/1000/(interval_us_local*1000/N_SYM_PER_SLOT)) < time_diff_us) {
+ time_diff_nSymb+=1;
+ printf("time duration %d rounded up to duration of %d symbols\n", time_diff_us, time_diff_nSymb);
+ }
+ printf("U-plane UL delay %d [us] measured against OTA time [offset in symbols is %d]\n", time_diff_us, time_diff_nSymb);
+ absolute_ota_sym = (symb + time_diff_nSymb) % XRAN_NUM_OF_SYMBOL_PER_SLOT;
+ printf("requested symb %d pkt arrival time [deadline] coresponds to symb %d OTA time\n", symb, absolute_ota_sym);
+
+ p_loc_sym_cb_ctx->symb_num_req = symb;
+ p_loc_sym_cb_ctx->sym_diff = -time_diff_nSymb;
+ p_loc_sym_cb_ctx->symb_num_ota = absolute_ota_sym;
+ p_loc_sym_cb_ctx->cb_type_id = XRAN_CB_SYM_RX_WIN_END;
+ p_loc_sym_cb_ctx->p_dev = p_dev_ctx;
+
+ p_loc_sym_cb_ctx->symCb = symCb;
+ p_loc_sym_cb_ctx->symCbParam = symCbParam;
+ p_loc_sym_cb_ctx->symCbTimeInfo = symCbTime;
+
+ p_loc_sym_cb_ctx->status = 1;
+
+ *p_sym_cb_ctx =p_loc_sym_cb_ctx;
+
+ return ret;
+}
+
+static int32_t
+xran_reg_sym_cb_rx_win_begin(struct xran_device_ctx * p_dev_ctx, xran_callback_sym_fn symCb, void * symCbParam, struct xran_sense_of_time* symCbTime,
+ uint8_t symb, struct cb_user_per_sym_ctx **p_sym_cb_ctx)
+{
+ int32_t ret = XRAN_STATUS_SUCCESS;
+ struct cb_user_per_sym_ctx *p_loc_sym_cb_ctx = &p_dev_ctx->symCbCtx[symb][XRAN_CB_SYM_RX_WIN_BEGIN];
+ uint32_t time_diff_us = 0;
+ uint32_t time_diff_nSymb = 0;
+ uint32_t absolute_ota_sym = 0;
+ uint32_t interval_us_local = p_dev_ctx->interval_us_local;
+
+ if(p_loc_sym_cb_ctx->status) {
+ ret = XRAN_STATUS_RESOURCE;
+ print_err("timer sym %d type id %d was already created",symb, XRAN_CB_SYM_RX_WIN_BEGIN);
+ return ret;
+ }
+
+ time_diff_us = p_dev_ctx->fh_cfg.Ta4_min;
+ printf("RX WIN begin Ta4_min is %d [us] where TTI is %d [us] \n", time_diff_us, interval_us_local);
+ time_diff_nSymb = time_diff_us*1000/(interval_us_local*1000/N_SYM_PER_SLOT);
+ printf("U-plane UL delay %d [us] measured against OTA time [offset in symbols is %d]\n", time_diff_us, time_diff_nSymb);
+ absolute_ota_sym = (symb + time_diff_nSymb) % XRAN_NUM_OF_SYMBOL_PER_SLOT;
+ printf("requested symb %d pkt arrival time [deadline] coresponds to symb %d OTA time\n", symb, absolute_ota_sym);
+
+ p_loc_sym_cb_ctx->symb_num_req = symb;
+ p_loc_sym_cb_ctx->sym_diff = -time_diff_nSymb;
+ p_loc_sym_cb_ctx->symb_num_ota = absolute_ota_sym;
+ p_loc_sym_cb_ctx->cb_type_id = XRAN_CB_SYM_RX_WIN_BEGIN;
+ p_loc_sym_cb_ctx->p_dev = p_dev_ctx;
+
+ p_loc_sym_cb_ctx->symCb = symCb;
+ p_loc_sym_cb_ctx->symCbParam = symCbParam;
+ p_loc_sym_cb_ctx->symCbTimeInfo = symCbTime;
+
+ p_loc_sym_cb_ctx->status = 1;
+
+ *p_sym_cb_ctx =p_loc_sym_cb_ctx;
+
+ return ret;
+}
+
+static int32_t
+xran_reg_sym_cb_tx_win_end(struct xran_device_ctx * p_dev_ctx, xran_callback_sym_fn symCb, void * symCbParam, struct xran_sense_of_time* symCbTime,
+ uint8_t symb, struct cb_user_per_sym_ctx **p_sym_cb_ctx)
+{
+ int32_t ret = XRAN_STATUS_SUCCESS;
+ struct cb_user_per_sym_ctx *p_loc_sym_cb_ctx = &p_dev_ctx->symCbCtx[symb][XRAN_CB_SYM_TX_WIN_END];
+ uint32_t time_diff_us = 0;
+ uint32_t time_diff_nSymb = 0;
+ uint32_t absolute_ota_sym = 0;
+ uint32_t interval_us_local = p_dev_ctx->interval_us_local;
+
+ if(p_loc_sym_cb_ctx->status) {
+ ret = XRAN_STATUS_RESOURCE;
+ print_err("timer sym %d type id %d was already created",symb, XRAN_CB_SYM_TX_WIN_END);
+ return ret;
+ }
+
+ time_diff_us = p_dev_ctx->fh_cfg.T1a_min_up;
+ printf("TX WIN end -T1a_min_up is %d [us] where TTI is %d [us] \n", time_diff_us, interval_us_local);
+ time_diff_nSymb = time_diff_us*1000/(interval_us_local*1000/N_SYM_PER_SLOT);
+ if ((time_diff_nSymb/1000/(interval_us_local*1000/N_SYM_PER_SLOT)) < time_diff_us) {
+ time_diff_nSymb +=1;
+ printf("time duration %d rounded up to duration of %d symbols\n", time_diff_us, time_diff_nSymb);
+ }
+ printf("U-plane DL advance is %d [us] measured against OTA time [offset in symbols is %d]\n", time_diff_us, -time_diff_nSymb);
+ absolute_ota_sym = ((symb + XRAN_NUM_OF_SYMBOL_PER_SLOT) - time_diff_nSymb) % XRAN_NUM_OF_SYMBOL_PER_SLOT;
+ printf("requested symb %d pkt tx time [deadline] corresponds to symb %d OTA time\n", symb, absolute_ota_sym);
+
+ p_loc_sym_cb_ctx->symb_num_req = symb;
+ p_loc_sym_cb_ctx->sym_diff = time_diff_nSymb;
+ p_loc_sym_cb_ctx->symb_num_ota = absolute_ota_sym;
+ p_loc_sym_cb_ctx->cb_type_id = XRAN_CB_SYM_TX_WIN_END;
+ p_loc_sym_cb_ctx->p_dev = p_dev_ctx;
+
+ p_loc_sym_cb_ctx->symCb = symCb;
+ p_loc_sym_cb_ctx->symCbParam = symCbParam;
+ p_loc_sym_cb_ctx->symCbTimeInfo = symCbTime;
+
+ p_loc_sym_cb_ctx->status = 1;
+
+ *p_sym_cb_ctx = p_loc_sym_cb_ctx;
+
+ return ret;
+}
+
+static int32_t
+xran_reg_sym_cb_tx_win_begin(struct xran_device_ctx * p_dev_ctx, xran_callback_sym_fn symCb, void * symCbParam, struct xran_sense_of_time* symCbTime,
+ uint8_t symb, struct cb_user_per_sym_ctx **p_sym_cb_ctx)
+{
+ int32_t ret = XRAN_STATUS_SUCCESS;
+ struct cb_user_per_sym_ctx *p_loc_sym_cb_ctx = &p_dev_ctx->symCbCtx[symb][XRAN_CB_SYM_TX_WIN_BEGIN];
+ uint32_t time_diff_us = 0;
+ uint32_t time_diff_nSymb = 0;
+ uint32_t absolute_ota_sym = 0;
+ uint32_t interval_us_local = p_dev_ctx->interval_us_local;
+
+ if(p_loc_sym_cb_ctx->status) {
+ ret = XRAN_STATUS_RESOURCE;
+ print_err("timer sym %d type id %d was already created",symb, XRAN_CB_SYM_TX_WIN_BEGIN);
+ return ret;
+ }
+
+ time_diff_us = p_dev_ctx->fh_cfg.T1a_max_up;
+ printf("TX WIN begin -T1a_max_up is %d [us] where TTI is %d [us] \n", time_diff_us, interval_us_local);
+ time_diff_nSymb = (time_diff_us*1000/(interval_us_local*1000/N_SYM_PER_SLOT));
+ if ((time_diff_nSymb/1000/(interval_us_local*1000/N_SYM_PER_SLOT)) < time_diff_us) {
+ time_diff_nSymb +=1;
+ printf("time duration %d rounded up to duration of %d symbols\n", time_diff_us, time_diff_nSymb);
+ }
+ printf("U-plane DL advance is %d [us] measured against OTA time [offset in symbols is %d]\n", time_diff_us, -time_diff_nSymb);
+ printf("requested symb %d pkt tx time [deadline] corresponds to symb %d OTA time\n", symb, absolute_ota_sym);
+ absolute_ota_sym = ((symb + XRAN_NUM_OF_SYMBOL_PER_SLOT) - time_diff_nSymb) % XRAN_NUM_OF_SYMBOL_PER_SLOT;
+
+ p_loc_sym_cb_ctx->symb_num_req = symb;
+ p_loc_sym_cb_ctx->sym_diff = time_diff_nSymb;
+ p_loc_sym_cb_ctx->symb_num_ota = absolute_ota_sym;
+ p_loc_sym_cb_ctx->cb_type_id = XRAN_CB_SYM_TX_WIN_BEGIN;
+ p_loc_sym_cb_ctx->p_dev = p_dev_ctx;
+
+ p_loc_sym_cb_ctx->symCb = symCb;
+ p_loc_sym_cb_ctx->symCbParam = symCbParam;
+ p_loc_sym_cb_ctx->symCbTimeInfo = symCbTime;
+
+ p_loc_sym_cb_ctx->status = 1;
+
+ *p_sym_cb_ctx =p_loc_sym_cb_ctx;
+
+ return ret;
+}
+
+int32_t
+xran_reg_sym_cb(void *pHandle, xran_callback_sym_fn symCb, void * symCbParam, struct xran_sense_of_time* symCbTime, uint8_t symb, enum cb_per_sym_type_id cb_sym_t_id)
+{
+ int32_t ret = XRAN_STATUS_SUCCESS;
+ struct xran_device_ctx * p_dev_ctx = NULL;
+ struct cb_elem_entry * cb_elm = NULL;
+ struct cb_user_per_sym_ctx *p_sym_cb_ctx = NULL;
+ rx_dpdk_sym_cb_fn dpdk_cb_to_arm = NULL;
+
+ if(xran_get_if_state() == XRAN_RUNNING) {
+ print_err("Cannot register callback while running!!");
+ return (-1);
+ }
+
+ if(pHandle) {
+ p_dev_ctx = (struct xran_device_ctx *)pHandle;
+ } else {
+ print_err("pHandle==NULL");
+ ret = XRAN_STATUS_INVALID_PARAM;
+ return ret;
+ }
+
+ switch (cb_sym_t_id) {
+ case XRAN_CB_SYM_OTA_TIME:
+ ret = xran_reg_sym_cb_ota(p_dev_ctx, symCb, symCbParam, symCbTime, symb, &p_sym_cb_ctx);
+ if(ret != XRAN_STATUS_SUCCESS)
+ return ret;
+ dpdk_cb_to_arm = rx_ul_user_sym_cb;
+ break;
+ case XRAN_CB_SYM_RX_WIN_BEGIN:
+ ret = xran_reg_sym_cb_rx_win_begin(p_dev_ctx, symCb, symCbParam, symCbTime, symb, &p_sym_cb_ctx);
+ if(ret != XRAN_STATUS_SUCCESS)
+ return ret;
+ dpdk_cb_to_arm = rx_ul_user_sym_cb;
+ break;
+ case XRAN_CB_SYM_RX_WIN_END:
+ ret = xran_reg_sym_cb_rx_win_end(p_dev_ctx, symCb, symCbParam, symCbTime, symb, &p_sym_cb_ctx);
+ if(ret != XRAN_STATUS_SUCCESS)
+ return ret;
+ dpdk_cb_to_arm = rx_ul_user_sym_cb;
+ break;
+ case XRAN_CB_SYM_TX_WIN_BEGIN:
+ ret = xran_reg_sym_cb_tx_win_begin(p_dev_ctx, symCb, symCbParam, symCbTime, symb, &p_sym_cb_ctx);
+ if(ret != XRAN_STATUS_SUCCESS)
+ return ret;
+ dpdk_cb_to_arm = rx_ul_user_sym_cb;
+ break;
+ case XRAN_CB_SYM_TX_WIN_END:
+ ret = xran_reg_sym_cb_tx_win_end(p_dev_ctx, symCb, symCbParam, symCbTime, symb, &p_sym_cb_ctx);
+ if(ret != XRAN_STATUS_SUCCESS)
+ return ret;
+ dpdk_cb_to_arm = rx_ul_user_sym_cb;
+ break;
+ default:
+ /* functionality is not yet implemented */
+ print_err("Functionality is not yet implemented !");
+ ret = XRAN_STATUS_INVALID_PARAM;
+ return ret;
+ }
+
+ cb_elm = xran_create_cb(xran_timer_arm_user_cb, dpdk_cb_to_arm, (void*)p_sym_cb_ctx);
+ if(cb_elm){
+ LIST_INSERT_HEAD(&p_dev_ctx->sym_cb_list_head[p_sym_cb_ctx->symb_num_ota],
+ cb_elm,
+ pointers);
+ } else {
+ print_err("cb_elm is NULL\n");
+ ret = XRAN_STATUS_FAIL;
+ return ret;
+ }
+
+ return ret;
+}
+
+int32_t
+xran_reg_physide_cb(void *pHandle, xran_fh_tti_callback_fn Cb, void *cbParam, int skipTtiNum, enum callback_to_phy_id id)
+{
+ struct xran_device_ctx * p_xran_dev_ctx = xran_dev_get_ctx();
+
+ if(xran_get_if_state() == XRAN_RUNNING) {
+ print_err("Cannot register callback while running!!\n");
+ return (-1);
+ }
+
+ p_xran_dev_ctx->ttiCb[id] = Cb;
+ p_xran_dev_ctx->TtiCbParam[id] = cbParam;
+ p_xran_dev_ctx->SkipTti[id] = skipTtiNum;
+
+ return 0;
+}
+
+
+
+