/*******************************************************************************
Eurecom OpenAirInterface
Copyright(c) 1999 - 2010 Eurecom
This program is free software; you can redistribute it and/or modify it
under the terms and conditions of the GNU General Public License,
version 2, as published by the Free Software Foundation.
This program is distributed in the hope it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
more details.
You should have received a copy of the GNU General Public License along with
this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin St - Fifth Floor, Boston, MA 02110-1301 USA.
The full GNU General Public License is included in this distribution in
the file called "COPYING".
Contact Information
Openair Admin: openair_admin@eurecom.fr
Openair Tech : openair_tech@eurecom.fr
Forums : http://forums.eurecom.fsr/openairinterface
Address : Eurecom, 2229, route des crĂȘtes, 06560 Valbonne Sophia Antipolis, France
*******************************************************************************/
/*! \file def.h
* \brief MAC data structures, constant, and function prototype
* \author Raymond Knopp, Navid Nikaein
* \date 2011
* \version 0.5
* \email navid.nikaein@eurecom.fr
* @ingroup _mac
*/
#ifndef __LAYER2_MAC_DEFS_H__
#define __LAYER2_MAC_DEFS_H__
#ifdef USER_MODE
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#endif
//#include "COMMON/openair_defs.h"
#include "COMMON/platform_constants.h"
#include "COMMON/mac_rrc_primitives.h"
#include "PHY/defs.h"
#include "RadioResourceConfigCommon.h"
#include "RadioResourceConfigDedicated.h"
#include "MeasGapConfig.h"
#include "TDD-Config.h"
#include "RACH-ConfigCommon.h"
#include "MeasObjectToAddModList.h"
#ifdef Rel10
#include "MBSFN-AreaInfoList-r9.h"
#include "MBSFN-SubframeConfigList.h"
#include "PMCH-InfoList-r9.h"
#endif
//#ifdef PHY_EMUL
//#include "SIMULATION/PHY_EMULATION/impl_defs.h"
//#endif
/** @defgroup _mac_impl_ MAC Layer Reference Implementation
* @ingroup _ref_implementation_
* @{
*/
#define BCCH_PAYLOAD_SIZE_MAX 128
#define CCCH_PAYLOAD_SIZE_MAX 128
#define SCH_PAYLOAD_SIZE_MAX 4096
/// Logical channel ids from 36-311 (Note BCCH is not specified in 36-311, uses the same as first DRB)
#define BCCH 3 // SI
#define CCCH 0 // srb0
#define DCCH 1 // srb1
#define DCCH1 2 // srb2
#define DTCH 3 // DTCH + lcid < 11
#define MCCH 4 // MCCH
#define MTCH 1 // MTCH
#ifdef Rel10
// Mask for identifying subframe for MBMS
#define MBSFN_TDD_SF3 0x80// for TDD
#define MBSFN_TDD_SF4 0x40
#define MBSFN_TDD_SF7 0x20
#define MBSFN_TDD_SF8 0x10
#define MBSFN_TDD_SF9 0x08
#define MBSFN_FDD_SF1 0x80// for FDD
#define MBSFN_FDD_SF2 0x40
#define MBSFN_FDD_SF3 0x20
#define MBSFN_FDD_SF6 0x10
#define MBSFN_FDD_SF7 0x08
#define MBSFN_FDD_SF8 0x04
#define MAX_MBSFN_AREA 8
#define MAX_PMCH_perMBSFN 15
#define MCCH_PAYLOAD_SIZE_MAX 128
//#define MCH_PAYLOAD_SIZE_MAX 16384// this value is using in case mcs and TBS index are high
#endif
#ifdef USER_MODE
#define printk printf
#endif //USER_MODE
#define MAX_NUM_LCGID 4
#define MAX_NUM_LCID 11
//#define MAX_NUM_RB 8
#define MAX_NUM_CE 5
#define NB_RA_PROC_MAX 4
#define BSR_TABLE_SIZE 64
// The power headroom reporting range is from -23 ...+40 dB and beyond, with step 1
#define PHR_MAPPING_OFFSET 23 // if ( x>= -23 ) val = floor (x + 23)
#define N_RBGS_MAX 25
#define LCGID0 0
#define LCGID1 1
#define LCGID2 2
#define LCGID3 3
#define LCID_EMPTY 0
#define LCID_NOT_EMPTY 1
typedef enum {
CONNECTION_OK=0,
CONNECTION_LOST,
PHY_RESYNCH
} UE_L2_STATE_t;
typedef struct {
u8 RAPID:6;
u8 T:1;
u8 E:1;
} __attribute__((__packed__))RA_HEADER_RAPID;
typedef struct {
u8 BI:4;
u8 R:2;
u8 T:1;
u8 E:1;
} __attribute__((__packed__))RA_HEADER_BI;
/*
typedef struct {
uint64_t padding:16;
uint64_t t_crnti:16;
uint64_t hopping_flag:1;
uint64_t rb_alloc:10;
uint64_t mcs:4;
uint64_t TPC:3;
uint64_t UL_delay:1;
uint64_t cqi_req:1;
uint64_t Timing_Advance_Command:11; // first/2nd octet LSB
uint64_t R:1; // octet MSB
} __attribute__((__packed__))RAR_PDU;
typedef struct {
uint64_t padding:16;
uint64_t R:1; // octet MSB
uint64_t Timing_Advance_Command:11; // first/2nd octet LSB
uint64_t cqi_req:1;
uint64_t UL_delay:1;
uint64_t TPC:3;
uint64_t mcs:4;
uint64_t rb_alloc:10;
uint64_t hopping_flag:1;
uint64_t t_crnti:16;
} __attribute__((__packed__))RAR_PDU;
#define sizeof_RAR_PDU 6
*/
typedef struct {
u8 LCID:5; // octet 1 LSB
u8 E:1;
u8 R:2; // octet 1 MSB
u8 L:7; // octet 2 LSB
u8 F:1; // octet 2 MSB
} __attribute__((__packed__))SCH_SUBHEADER_SHORT;
typedef struct {
u8 LCID:5; // octet 1 LSB
u8 E:1;
u8 R:2; // octet 1 MSB
u8 L_MSB:7;
u8 F:1; // octet 2 MSB
u8 L_LSB:8;
u8 padding;
} __attribute__((__packed__))SCH_SUBHEADER_LONG;
typedef struct {
u8 LCID:5;
u8 E:1;
u8 R:2;
} __attribute__((__packed__))SCH_SUBHEADER_FIXED;
typedef struct {
u8 Buffer_size:6; // octet 1 LSB
u8 LCGID:2; // octet 1 MSB
} __attribute__((__packed__))BSR_SHORT;
typedef BSR_SHORT BSR_TRUNCATED;
typedef struct {
u32 Buffer_size3:6;
u32 Buffer_size2:6;
u32 Buffer_size1:6;
u32 Buffer_size0:6;
u32 padding:8;
} __attribute__((__packed__))BSR_LONG;
#define BSR_LONG_SIZE (sizeof(BSR_LONG))
typedef struct {
u8 TA:6;
u8 R:2;
} __attribute__((__packed__))TIMING_ADVANCE_CMD;
typedef struct {
u8 PH:6;
u8 R:2;
} __attribute__((__packed__))POWER_HEADROOM_CMD;
typedef struct {
u8 Num_ue_spec_dci ;
u8 Num_common_dci ;
unsigned int nCCE;
DCI_ALLOC_t dci_alloc[NUM_DCI_MAX] ;
} DCI_PDU;
typedef struct {
u8 payload[CCCH_PAYLOAD_SIZE_MAX] ;/*!< \brief CCCH payload */
} __attribute__((__packed__))CCCH_PDU;
typedef struct {
u8 payload[BCCH_PAYLOAD_SIZE_MAX] ;/*!< \brief CCCH payload */
} __attribute__((__packed__))BCCH_PDU;
#ifdef Rel10
typedef struct {
u8 payload[MCCH_PAYLOAD_SIZE_MAX] ;/*!< \brief MCCH payload */
} __attribute__((__packed__))MCCH_PDU;
#endif
typedef struct{
u8 stop_sf_MSB:3; // octet 1 LSB
u8 lcid:5; // octet 2 MSB
u8 stop_sf_LSB:8;
} __attribute__((__packed__))MSI_ELEMENT;
// DLSCH LCHAN IDs
#define CCCH_LCHANID 0
#define UE_CONT_RES 28
#define TIMING_ADV_CMD 29
#define DRX_CMD 30
#define SHORT_PADDING 31
#ifdef Rel10
// MCH LCHAN IDs (table6.2.1-4 TS36.321)
#define MCCH_LCHANID 0
#define MCH_SCHDL_INFO 30
#endif
// ULSCH LCHAN IDs
#define EXTENDED_POWER_HEADROOM 25
#define POWER_HEADROOM 26
#define CRNTI 27
#define TRUNCATED_BSR 28
#define SHORT_BSR 29
#define LONG_BSR 30
/*! \brief Downlink SCH PDU Structure
*/
typedef struct {
s8 payload[8][SCH_PAYLOAD_SIZE_MAX];
u16 Pdu_size[8];
} __attribute__ ((__packed__)) DLSCH_PDU;
/*! \brief MCH PDU Structure
*/
typedef struct {
s8 payload[SCH_PAYLOAD_SIZE_MAX];
u16 Pdu_size;
uint8_t mcs;
uint8_t sync_area;
uint8_t msi_active;
uint8_t mcch_active;
uint8_t mtch_active;
} __attribute__ ((__packed__)) MCH_PDU;
/*! \brief Uplink SCH PDU Structure
*/
typedef struct {
s8 payload[SCH_PAYLOAD_SIZE_MAX]; /*!< \brief SACH payload */
u16 Pdu_size;
} __attribute__ ((__packed__)) ULSCH_PDU;
#include "PHY/impl_defs_top.h"
typedef enum {
S_UL_NONE =0,
S_UL_WAITING,
S_UL_SCHEDULED,
S_UL_BUFFERED,
S_UL_NUM_STATUS
} UE_ULSCH_STATUS;
typedef enum {
S_DL_NONE =0,
S_DL_WAITING,
S_DL_SCHEDULED,
S_DL_BUFFERED,
S_DL_NUM_STATUS
} UE_DLSCH_STATUS;
// temp struct for sched
typedef struct {
u16 rnti;
u16 subframe;
u16 serving_num;
UE_ULSCH_STATUS status;
} eNB_ULSCH_INFO;
// temp struct for sched
typedef struct {
u16 rnti;
u16 weight;
u16 subframe;
u16 serving_num;
UE_DLSCH_STATUS status;
} eNB_DLSCH_INFO;
typedef struct{
/// BW
uint16_t num_dlactive_UEs;
/// available number of PRBs for a give SF
uint16_t available_prbs;
/// total number of PRB available for the user plane
uint32_t total_available_prbs;
/// aggregation
/// total avilable nccc : num control channel element
uint16_t available_ncces;
// only for a new transmission, should be extended for retransmission
// current dlsch bit rate for all transport channels
uint32_t dlsch_bitrate;
//
uint32_t dlsch_bytes_tx;
//
uint32_t dlsch_pdus_tx;
//
uint32_t total_dlsch_bitrate;
//
uint32_t total_dlsch_bytes_tx;
//
uint32_t total_dlsch_pdus_tx;
//
uint32_t ulsch_bitrate;
//
uint32_t ulsch_bytes_rx;
//
uint64_t ulsch_pdus_rx;
// here for RX
}eNB_STATS;
typedef struct{
/// CRNTI of UE
uint16_t crnti; ///user id (rnti) of connected UEs
// rrc status
uint8_t rrc_status;
/// harq pid
uint8_t harq_pid;
/// harq rounf
uint8_t harq_round;
/// DL Wideband CQI index (2 TBs)
uint8_t dl_cqi;
/// total available number of PRBs for a new transmission
uint16_t rbs_used;
/// total available number of PRBs for a retransmission
uint16_t rbs_used_retx;
/// total nccc used for a new transmission: num control channel element
uint16_t ncce_used;
/// total avilable nccc for a retransmission: num control channel element
uint16_t ncce_used_retx;
// mcs1 before the rate adaptaion
uint8_t dlsch_mcs1;
/// Target mcs2 after rate-adaptation
uint8_t dlsch_mcs2;
// current TBS with mcs2
uint32_t TBS;
// total TBS with mcs2
// uint32_t total_TBS;
// total rb used for a new transmission
uint32_t total_rbs_used;
// total rb used for retransmission
uint32_t total_rbs_used_retx;
/// TX
/// Num pkt
uint32_t num_pdu_tx[NB_RB_MAX];
/// num bytes
uint32_t num_bytes_tx[NB_RB_MAX];
/// num retransmission / harq
uint32_t num_retransmission;
/// instantaneous tx throughput for each TTI
// uint32_t tti_throughput[NB_RB_MAX];
/// overall
//
uint32_t dlsch_bitrate;
//total
uint32_t total_dlsch_bitrate;
/// headers+ CE + padding bytes for a MAC PDU
uint64_t overhead_bytes;
/// headers+ CE + padding bytes for a MAC PDU
uint64_t total_overhead_bytes;
/// headers+ CE + padding bytes for a MAC PDU
uint64_t avg_overhead_bytes;
// MAC multiplexed payload
uint64_t total_sdu_bytes;
// total MAC pdu bytes
uint64_t total_pdu_bytes;
// total num pdu
uint32_t total_num_pdus;
//
// uint32_t avg_pdu_size;
/// RX
/// num rx pdu
uint32_t num_pdu_rx[NB_RB_MAX];
/// num bytes rx
uint32_t num_bytes_rx[NB_RB_MAX];
/// instantaneous rx throughput for each TTI
// uint32_t tti_goodput[NB_RB_MAX];
/// errors
uint32_t num_errors_rx;
/// overall
// total MAC pdu bytes
uint64_t total_pdu_bytes_rx;
// total num pdu
uint32_t total_num_pdus_rx;
}eNB_UE_STATS;
typedef struct{
/// C-RNTI of UE
u16 rnti;
/// Flag to indicate UL has been scheduled at least once
int ul_active;
// PHY interface info
/// DCI format for DLSCH
u16 DLSCH_dci_fmt;
/// Current Aggregation Level for DCI
u8 DCI_aggregation_min;
///
u8 DLSCH_dci_size_bits;
/// DCI buffer for DLSCH
u8 DLSCH_DCI[8][(MAX_DCI_SIZE_BITS>>3)+1];
/// Number of Allocated RBs for DL after scheduling (prior to frequency allocation)
u16 nb_rb[8];
/// Number of Allocated RBs for UL after scheduling (prior to frequency allocation)
u16 nb_rb_ul[8];
/// DCI buffer for ULSCH
u8 ULSCH_DCI[8][(MAX_DCI_SIZE_BITS>>3)+1];
/// DL DAI
u8 DAI;
/// UL DAI
u8 DAI_ul[10];
/// UL Scheduling Request Received
u8 ul_SR;
//Resource Block indication for each sub-band in MU-MIMO
u8 rballoc_subband[8][50];
// Logical channel info for link with RLC
/// UE BSR info for each logical channel group id
u8 bsr_info[MAX_NUM_LCGID];
/// phr information
u8 phr_info;
//dl buffer info
u32_t dl_buffer_info[MAX_NUM_LCID];
u32_t dl_buffer_total;
u32_t dl_pdus_total;
u32_t dl_pdus_in_buffer[MAX_NUM_LCID];
u32_t dl_buffer_head_sdu_creation_time[MAX_NUM_LCID];
u8 dl_buffer_head_sdu_is_segmented[MAX_NUM_LCID];
u32_t dl_buffer_head_sdu_remaining_size_to_send[MAX_NUM_LCID];
} UE_TEMPLATE;
typedef struct {
/// Flag to indicate this process is active
u8 RA_active;
/// Size of DCI for RA-Response (bytes)
u8 RA_dci_size_bytes1;
/// Size of DCI for RA-Response (bits)
u8 RA_dci_size_bits1;
/// Actual DCI to transmit for RA-Response
u8 RA_alloc_pdu1[(MAX_DCI_SIZE_BITS>>3)+1];
/// DCI format for RA-Response (should be 1A)
u8 RA_dci_fmt1;
/// Size of DCI for Msg4/ContRes (bytes)
u8 RA_dci_size_bytes2;
/// Size of DCI for Msg4/ContRes (bits)
u8 RA_dci_size_bits2;
/// Actual DCI to transmit for Msg4/ContRes
u8 RA_alloc_pdu2[(MAX_DCI_SIZE_BITS>>3)+1];
/// DCI format for Msg4/ContRes (should be 1A)
u8 RA_dci_fmt2;
/// Flag to indicate the eNB should generate RAR. This is triggered by detection of PRACH
u8 generate_rar;
/// Subframe where Msg3 is to be sent
u8 Msg3_subframe;
/// Flag to indicate the eNB should generate Msg4 upon reception of SDU from RRC. This is triggered by first ULSCH reception at eNB for new user.
u8 generate_Msg4;
/// Flag to indicate the eNB should generate the DCI for Msg4, after getting the SDU from RRC.
u8 generate_Msg4_dci;
/// Flag to indicate that eNB is waiting for ACK that UE has received Msg3.
u8 wait_ack_Msg4;
/// UE RNTI allocated during RAR
u16 rnti;
/// RA RNTI allocated from received PRACH
u16 RA_rnti;
/// Received preamble_index
u8 preamble_index;
/// Received UE Contention Resolution Identifier
u8 cont_res_id[6];
/// Timing offset indicated by PHY
s16 timing_offset;
/// Timeout for RRC connection
s16 RRC_timer;
} RA_TEMPLATE;
///subband bitmap coniguration (for ALU icic algo purpose), in test phase
typedef struct{
u8 sbmap[NUMBER_OF_SUBBANDS]; //13 = number of SB MAX for 100 PRB
u8 periodicity;
u8 first_subframe;
u8 sb_size;
u8 nb_active_sb;
}SBMAP_CONF;
//end ALU's algo
typedef struct{
///
u16 Node_id;
/// frame counter
u32 frame;
/// subframe counter
u32 subframe;
/// Outgoing DCI for PHY generated by eNB scheduler
DCI_PDU DCI_pdu;
/// Outgoing BCCH pdu for PHY
BCCH_PDU BCCH_pdu;
/// Outgoing BCCH DCI allocation
uint32_t BCCH_alloc_pdu;
/// Outgoing CCCH pdu for PHY
CCCH_PDU CCCH_pdu;
/// Outgoing DLSCH pdu for PHY
DLSCH_PDU DLSCH_pdu[NUMBER_OF_UE_MAX+1][2];
/// DCI template and MAC connection parameters for UEs
UE_TEMPLATE UE_template[NUMBER_OF_UE_MAX];
/// DCI template and MAC connection for RA processes
RA_TEMPLATE RA_template[NB_RA_PROC_MAX];
/// BCCH active flag
u8 bcch_active;
/// MBSFN SubframeConfig
struct MBSFN_SubframeConfig *mbsfn_SubframeConfig[8];
/// number of subframe allocation pattern available for MBSFN sync area
u8 num_sf_allocation_pattern;
#ifdef Rel10
/// MBMS Flag
u8 MBMS_flag;
/// Outgoing MCCH pdu for PHY
MCCH_PDU MCCH_pdu;
/// MCCH active flag
u8 msi_active;
/// MCCH active flag
u8 mcch_active;
/// MTCH active flag
u8 mtch_active;
/// number of active MBSFN area
u8 num_active_mbsfn_area;
/// MBSFN Area Info
struct MBSFN_AreaInfo_r9 *mbsfn_AreaInfo[MAX_MBSFN_AREA];
/// PMCH Config
struct PMCH_Config_r9 *pmch_Config[MAX_PMCH_perMBSFN];
/// MBMS session info list
struct MBMS_SessionInfoList_r9 *mbms_SessionList[MAX_PMCH_perMBSFN];
/// Outgoing MCH pdu for PHY
MCH_PDU MCH_pdu;
#endif
#ifdef CBA
uint8_t num_active_cba_groups;
uint16_t cba_rnti[NUM_MAX_CBA_GROUP];
#endif
///subband bitmap configuration
SBMAP_CONF sbmap_conf;
/// active flag for Other lcid
u8 lcid_active[NB_RB_MAX];
// eNB stats
eNB_STATS eNB_stats;
/// eNB to UE statistics
eNB_UE_STATS eNB_UE_stats[NUMBER_OF_UE_MAX];
}eNB_MAC_INST;
typedef struct {
/// buffer status for each lcgid
u8 BSR[MAX_NUM_LCGID]; // should be more for mesh topology
/// keep the number of bytes in rlc buffer for each lcid
u16 BSR_bytes[MAX_NUM_LCGID];
/// buffer status for each lcid
u8 LCID_status[MAX_NUM_LCID];
/// SR pending as defined in 36.321
u8 SR_pending;
/// SR_COUNTER as defined in 36.321
u16 SR_COUNTER;
/// logical channel group ide for each LCID
u8 LCGID[MAX_NUM_LCID];
/// retxBSR-Timer, default value is sf2560
u16 retxBSR_Timer;
/// retxBSR_SF, number of subframe before triggering a regular BSR
s16 retxBSR_SF;
/// periodicBSR-Timer, default to infinity
u16 periodicBSR_Timer;
/// periodicBSR_SF, number of subframe before triggering a periodic BSR
s16 periodicBSR_SF;
/// default value is 0: not configured
u16 sr_ProhibitTimer;
/// sr ProhibitTime running
u8 sr_ProhibitTimer_Running;
/// default value to n5
u16 maxHARQ_Tx;
/// default value is false
u16 ttiBundling;
/// default value is release
struct DRX_Config *drx_config;
/// default value is release
struct MAC_MainConfig__phr_Config *phr_config;
///timer before triggering a periodic PHR
u16 periodicPHR_Timer;
///timer before triggering a prohibit PHR
u16 prohibitPHR_Timer;
///DL Pathloss change value
u16 PathlossChange;
///number of subframe before triggering a periodic PHR
s16 periodicPHR_SF;
///number of subframe before triggering a prohibit PHR
s16 prohibitPHR_SF;
///DL Pathloss Change in db
u16 PathlossChange_db;
//Bj bucket usage per lcid
s16 Bj[MAX_NUM_LCID];
// Bucket size per lcid
s16 bucket_size[MAX_NUM_LCID];
} UE_SCHEDULING_INFO;
typedef struct{
u16 Node_id;
/// frame counter
u32 frame;
/// subframe counter
u32 subframe;
/// C-RNTI of UE
u16 crnti;
/// uplink active flag
uint8_t ul_active;
/// pointer to RRC PHY configuration
RadioResourceConfigCommonSIB_t *radioResourceConfigCommon;
/// pointer to RRC PHY configuration
struct PhysicalConfigDedicated *physicalConfigDedicated;
/// pointer to TDD Configuration (NULL for FDD)
TDD_Config_t *tdd_Config;
/// Number of adjacent cells to measure
u8 n_adj_cells;
/// Array of adjacent physical cell ids
u32 adj_cell_id[6];
/// Pointer to RRC MAC configuration
MAC_MainConfig_t *macConfig;
/// Pointer to RRC Measurement gap configuration
MeasGapConfig_t *measGapConfig;
/// Pointers to LogicalChannelConfig indexed by LogicalChannelIdentity. Note NULL means LCHAN is inactive.
LogicalChannelConfig_t *logicalChannelConfig[MAX_NUM_LCID];
/// Scheduling Information
UE_SCHEDULING_INFO scheduling_info;
/// Outgoing CCCH pdu for PHY
CCCH_PDU CCCH_pdu;
/// Incoming DLSCH pdu for PHY
//DLSCH_PDU DLSCH_pdu[NUMBER_OF_UE_MAX][2];
/// number of attempt for rach
u8 RA_attempt_number;
/// Random-access procedure flag
u8 RA_active;
/// Random-access window counter
s8 RA_window_cnt;
/// Random-access Msg3 size in bytes
u8 RA_Msg3_size;
/// Random-access prachMaskIndex
u8 RA_prachMaskIndex;
/// Flag indicating Preamble set (A,B) used for first Msg3 transmission
u8 RA_usedGroupA;
/// Random-access Resources
PRACH_RESOURCES_t RA_prach_resources;
/// Random-access PREAMBLE_TRANSMISSION_COUNTER
u8 RA_PREAMBLE_TRANSMISSION_COUNTER;
/// Random-access backoff counter
s16 RA_backoff_cnt;
/// Random-access variable for window calculation (frame of last change in window counter)
u32 RA_tx_frame;
/// Random-access variable for window calculation (subframe of last change in window counter)
u8 RA_tx_subframe;
/// Random-access Group B maximum path-loss
/// Random-access variable for backoff (frame of last change in backoff counter)
u32 RA_backoff_frame;
/// Random-access variable for backoff (subframe of last change in backoff counter)
u8 RA_backoff_subframe;
/// Random-access Group B maximum path-loss
u16 RA_maxPL;
/// Random-access Contention Resolution Timer active flag
u8 RA_contention_resolution_timer_active;
/// Random-access Contention Resolution Timer count value
u8 RA_contention_resolution_cnt;
/// power headroom reporitng reconfigured
u8 PHR_reconfigured;
/// power headroom state as configured by the higher layers
u8 PHR_state;
/// power backoff due to power management (as allowed by P-MPRc) for this cell
u8 PHR_reporting_active;
/// power backoff due to power management (as allowed by P-MPRc) for this cell
u8 power_backoff_db[NUMBER_OF_eNB_MAX];
/// MBSFN_Subframe Configuration
struct MBSFN_SubframeConfig *mbsfn_SubframeConfig[8];
/// number of subframe allocation pattern available for MBSFN sync area
u8 num_sf_allocation_pattern;
#ifdef Rel10
/// number of active MBSFN area
u8 num_active_mbsfn_area;
/// MBSFN Area Info
struct MBSFN_AreaInfo_r9 *mbsfn_AreaInfo[MAX_MBSFN_AREA];
/// PMCH Config
struct PMCH_Config_r9 *pmch_Config[MAX_PMCH_perMBSFN];
/// MCCH status
u8 mcch_status;
/// MSI status
u8 msi_status;// could be an array if there are >1 MCH in one MBSFN area
#endif
//#ifdef CBA
uint16_t cba_rnti[NUM_MAX_CBA_GROUP];
uint8_t cba_last_access[NUM_MAX_CBA_GROUP];
//#endif
}UE_MAC_INST;
typedef struct {
u16 cell_ids[6];
u8 n_adj_cells;
} neigh_cell_id_t;
/* \brief Generate header for DL-SCH. This function parses the desired control elements and sdus and generates the header as described
in 36-321 MAC layer specifications. It returns the number of bytes used for the header to be used as an offset for the payload
in the DLSCH buffer.
@param mac_header Pointer to the first byte of the MAC header (DL-SCH buffer)
@param num_sdus Number of SDUs in the payload
@param sdu_lengths Pointer to array of SDU lengths
@param sdu_lcids Pointer to array of LCIDs (the order must be the same as the SDU length array)
@param drx_cmd dicontinous reception command
@param timing_advancd_cmd timing advanced command
@param ue_cont_res_id Pointer to contention resolution identifier (NULL means not present in payload)
@param short_padding Number of bytes for short padding (0,1,2)
@param post_padding number of bytes for padding at the end of MAC PDU
@returns Number of bytes used for header
*/
unsigned char generate_dlsch_header(unsigned char *mac_header,
unsigned char num_sdus,
unsigned short *sdu_lengths,
unsigned char *sdu_lcids,
unsigned char drx_cmd,
short timing_advance_cmd,
unsigned char *ue_cont_res_id,
unsigned char short_padding,
unsigned short post_padding);
/** \brief RRC Configuration primitive for PHY/MAC. Allows configuration of PHY/MAC resources based on System Information (SI), RRCConnectionSetup and RRCConnectionReconfiguration messages.
@param Mod_id Instance ID of eNB
@param eNB_flag Indicates if this is a eNB or UE configuration
@param UE_id Index of UE if this is an eNB configuration
@param eNB_id Index of eNB if this is a UE configuration
@param radioResourceConfigCommon Structure from SIB2 for common radio parameters (if NULL keep existing configuration)
@param physcialConfigDedicated Structure from RRCConnectionSetup or RRCConnectionReconfiguration for dedicated PHY parameters (if NULL keep existing configuration)
@param measObj Structure from RRCConnectionReconfiguration for UE measurement procedures
@param mac_MainConfig Structure from RRCConnectionSetup or RRCConnectionReconfiguration for dedicated MAC parameters (if NULL keep existing configuration)
@param logicalChannelIdentity Logical channel identity index of corresponding logical channel config
@param logicalChannelConfig Pointer to logical channel configuration
@param measGapConfig Measurement Gap configuration for MAC (if NULL keep existing configuration)
@param tdd_Config TDD Configuration from SIB1 (if NULL keep existing configuration)
@param SIwindowsize SI Windowsize from SIB1 (if NULL keep existing configuration)
@param SIperiod SI Period from SIB1 (if NULL keep existing configuration)
@param MBMS_Flag indicates MBMS transmission
@param mbsfn_SubframeConfigList pointer to mbsfn subframe configuration list from SIB2
@param mbsfn_AreaInfoList pointer to MBSFN Area Info list from SIB13
@param pmch_InfoList pointer to PMCH_InfoList from MBSFNAreaConfiguration Message (MCCH Message)
*/
int rrc_mac_config_req(u8 Mod_id,u8 eNB_flag,u8 UE_id,u8 eNB_index,
RadioResourceConfigCommonSIB_t *radioResourceConfigCommon,
struct PhysicalConfigDedicated *physicalConfigDedicated,
MeasObjectToAddMod_t **measObj,
MAC_MainConfig_t *mac_MainConfig,
long logicalChannelIdentity,
LogicalChannelConfig_t *logicalChannelConfig,
MeasGapConfig_t *measGapConfig,
TDD_Config_t *tdd_Config,
u8 *SIwindowsize,
u16 *SIperiod,
ARFCN_ValueEUTRA_t *ul_CarrierFreq,
long *ul_Bandwidth,
AdditionalSpectrumEmission_t *additionalSpectrumEmission,
struct MBSFN_SubframeConfigList *mbsfn_SubframeConfigList
#ifdef Rel10
,
u8 MBMS_Flag,
MBSFN_AreaInfoList_r9_t *mbsfn_AreaInfoList,
PMCH_InfoList_r9_t *pmch_InfoList
#endif
#ifdef CBA
,
u8 num_active_cba_groups,
u16 cba_rnti
#endif
);
/** \brief First stage of Random-Access Scheduling. Loops over the RA_templates and checks if RAR, Msg3 or its retransmission are to be scheduled in the subframe. It returns the total number of PRB used for RA SDUs. For Msg3 it retrieves the L3msg from RRC and fills the appropriate buffers. For the others it just computes the number of PRBs. Each DCI uses 3 PRBs (format 1A)
for the message.
@param Mod_id Instance ID of eNB
@param frame Frame index
@param subframe Subframe number on which to act
@param nprb Pointer to current PRB count
@param nCCE Pointer to current nCCE count
*/
void schedule_RA(u8 Mod_id,u32 frame,u8 subframe,u8 Msg3_subframe,u8 *nprb,unsigned int *nCCE);
/** \brief First stage of SI Scheduling. Gets a SI SDU from RRC if available and computes the MCS required to transport it as a function of the SDU length. It assumes a length less than or equal to 64 bytes (MCS 6, 3 PRBs).
@param Mod_id Instance ID of eNB
@param frame Frame index
@param subframe Subframe number on which to act
@param Msg3_subframe Subframe where Msg3 will be transmitted
@param nprb Pointer to current PRB count
@param nCCE Pointer to current nCCE count
*/
void schedule_SI(u8 Mod_id,u32 frame,u8 *nprb,unsigned int *nCCE);
/** \brief MBMS scheduling: Checking the position for MBSFN subframes. Create MSI, transfer MCCH from RRC to MAC, transfer MTCHs from RLC to MAC. Multiplexing MSI,MCCH&MTCHs. Return 1 if there are MBSFN data being allocated, otherwise return 0;
@param Mod_id Instance ID of eNB
@param frame Frame index
@param subframe Subframe number on which to act
*/
int schedule_MBMS(unsigned char Mod_id,u32 frame, u8 subframe);
/** \brief check the mapping between sf allocation and sync area, Currently only supports 1:1 mapping
@param Mod_id Instance ID of eNB
@param mbsfn_sync_area index of mbsfn sync area
@param[out] index of sf pattern
*/
s8 get_mbsfn_sf_alloction (unsigned char Mod_id, u8 mbsfn_sync_area);
/** \brief check the mapping between sf allocation and sync area, Currently only supports 1:1 mapping
@param Mod_id Instance ID of eNB
@param mbsfn_sync_area index of mbsfn sync area
@param eNB_index index of eNB
@param[out] index of sf pattern
*/
s8 ue_get_mbsfn_sf_alloction (unsigned char Mod_id, u8 mbsfn_sync_area, unsigned char eNB_index);
/** \brief top ULSCH Scheduling for TDD (config 1-6).
@param Mod_id Instance ID of eNB
@param frame Frame index
@param subframe Subframe number on which to act
@param sched_subframe Subframe number where PUSCH is transmitted (for DAI lookup)
@param nCCE Pointer to current nCCE count
*/
void schedule_ulsch(unsigned char Mod_id,u32 frame,unsigned char cooperation_flag,unsigned char subframe,unsigned char sched_subframe,unsigned int *nCCE);
/** \brief ULSCH Scheduling per RNTI TDD config (config 1-6).
@param Mod_id Instance ID of eNB
@param frame Frame index
@param subframe Subframe number on which to act
@param sched_subframe Subframe number where PUSCH is transmitted (for DAI lookup)
@param nCCE Pointer to current nCCE count
*/
void schedule_ulsch_rnti(u8 Mod_id, unsigned char cooperation_flag, u32 frame, unsigned char subframe, unsigned char sched_subframe, u8 granted_UEs, unsigned int *nCCE, unsigned int *nCCE_available, u16 *first_rb);
/** \brief ULSCH Scheduling for CBA RNTI TDD config (config 1-6).
@param Mod_id Instance ID of eNB
@param frame Frame index
@param subframe Subframe number on which to act
@param sched_subframe Subframe number where PUSCH is transmitted (for DAI lookup)
@param nCCE Pointer to current nCCE count
*/
void schedule_ulsch_cba_rnti(u8 Mod_id, unsigned char cooperation_flag, u32 frame, unsigned char subframe, unsigned char sched_subframe, u8 granted_UEs, unsigned int *nCCE, unsigned int *nCCE_available, u16 *first_rb);
/** \brief Second stage of DLSCH scheduling, after schedule_SI, schedule_RA and schedule_dlsch have been called. This routine first allocates random frequency assignments for SI and RA SDUs using distributed VRB allocations and adds the corresponding DCI SDU to the DCI buffer for PHY. It then loops over the UE specific DCIs previously allocated and fills in the remaining DCI fields related to frequency allocation. It assumes localized allocation of type 0 (DCI.rah=0). The allocation is done for tranmission modes 1,2,4.
@param Mod_id Instance of eNB
@param frame Frame index
@param subframe Index of subframe
@param rballoc Bitmask for allowable subband allocations
@param RA_scheduled RA was scheduled in this subframe
@param mbsfn_flag Indicates that this subframe is for MCH/MCCH
*/
void fill_DLSCH_dci(u8 Mod_id,u32 frame,u8 subframe,u32 rballoc,u8 RA_scheduled,int mbsfn_flag);
/** \brief UE specific DLSCH scheduling. Retrieves next ue to be schduled from round-robin scheduler and gets the appropriate harq_pid for the subframe from PHY. If the process is active and requires a retransmission, it schedules the retransmission with the same PRB count and MCS as the first transmission. Otherwise it consults RLC for DCCH/DTCH SDUs (status with maximum number of available PRBS), builds the MAC header (timing advance sent by default) and copies
@param Mod_id Instance ID of eNB
@param frame Frame index
@param subframe Subframe on which to act
@param nb_rb_used0 Number of PRB used by SI/RA
@param nCCE_used Number of CCE used by SI/RA
@param mbsfn_flag Indicates that MCH/MCCH is in this subframe
*/
void schedule_ue_spec(u8 Mod_id,u32 frame,u8 subframe,u16 nb_rb_used0,unsigned int *nCCE_used,int mbsfn_flag);
/** \brief Function for UE/PHY to compute PUSCH transmit power in power-control procedure.
@param Mod_id Module id of UE
@returns Po_NOMINAL_PUSCH (PREAMBLE_RECEIVED_TARGET_POWER+DELTA_PREAMBLE
*/
s8 get_Po_NOMINAL_PUSCH(u8 Mod_id);
/** \brief Function to compute DELTA_PREAMBLE from 36.321 (for RA power ramping procedure and Msg3 PUSCH power control policy)
@param Mod_id Module id of UE
@returns DELTA_PREAMBLE
*/
s8 get_DELTA_PREAMBLE(u8 Mod_id);
/** \brief Function for compute deltaP_rampup from 36.321 (for RA power ramping procedure and Msg3 PUSCH power control policy)
@param Mod_id Module id of UE
@returns deltaP_rampup
*/
s8 get_deltaP_rampup(u8 Mod_id);
//main.c
void chbch_phy_sync_success(u8 Mod_id,u32 frame,u8 CH_index);
void mrbch_phy_sync_failure(u8 Mod_id, u32 frame,u8 free_eNB_index);
int mac_top_init(int eMBMS_active, u8 cba_group_active);
char layer2_init_UE(u8 Mod_id);
char layer2_init_eNB(u8 Mod_id, u8 Free_ch_index);
void mac_switch_node_function(u8 Mod_id);
int mac_init_global_param(void);
void mac_top_cleanup(void);
void mac_UE_out_of_sync_ind(u8 Mod_id,u32 frame, u16 CH_index);
// eNB functions
/* \brief This function assigns pre-available RBS to each UE in specified sub-bands before scheduling is done
@param Mod_id Instance ID of eNB
@param frame Index of frame
@param subframe Index of current subframe
@param dl_pow_off Pointer to store resulting power offset for DCI
@param pre_nb_available_rbs Pointer to store number of remaining rbs after scheduling
@param N_RBS Number of resource block groups
@param rb_alloc_sub Table of resource block groups allocated to each UE
*/
void dlsch_scheduler_pre_processor (unsigned char Mod_id,
u32 frame,
unsigned char subframe,
u8 *dl_pow_off,
u16 *pre_nb_available_rbs,
int N_RBGS,
unsigned char rballoc_sub_UE[NUMBER_OF_UE_MAX][N_RBGS_MAX]);
/* \brief Function to trigger the eNB scheduling procedure. It is called by PHY at the beginning of each subframe, \f$n$\f
and generates all DLSCH allocations for subframe \f$n\f$ and ULSCH allocations for subframe \f$n+k$\f. The resultant DCI_PDU is
ready after returning from this call.
@param Mod_id Instance ID of eNB
@param cooperation_flag Flag to indicated that this cell has cooperating nodes (i.e. that there are collaborative transport channels that
can be scheduled.
@param subframe Index of current subframe
@param calibration_flag Flag to indicate that eNB scheduler should schedule TDD auto-calibration PUSCH.
*/
void eNB_dlsch_ulsch_scheduler(u8 Mod_id, u8 cooperation_flag, u32 frame, u8 subframe);//, int calibration_flag);
/* \brief Function to retrieve result of scheduling (DCI) in current subframe. Can be called an arbitrary numeber of times after eNB_dlsch_ulsch_scheduler
in a given subframe.
@param Mod_id Instance ID of eNB
@param subframe Index of current subframe
@returns Pointer to generated DCI for subframe
*/
DCI_PDU *get_dci_sdu(u8 Mod_id,u32 frame,u8 subframe);
/* \brief Function to indicate a received preamble on PRACH. It initiates the RA procedure.
@param Mod_id Instance ID of eNB
@param preamble_index index of the received RA request
@param timing_offset Offset in samples of the received PRACH w.r.t. eNB timing. This is used to
*/
void initiate_ra_proc(u8 Mod_id,u32 frame, u16 preamble_index,s16 timing_offset,u8 sect_id,u8 subframe,u8 f_id);
/* \brief Function in eNB to fill RAR pdu when requested by PHY. This provides a single RAR SDU for the moment and returns the t-CRNTI.
@param Mod_id Instance ID of eNB
@param dlsch_buffer Pointer to DLSCH input buffer
@param N_RB_UL Number of UL resource blocks
@returns t_CRNTI
*/
u16 fill_rar(u8 Mod_id,u32 frame,
u8 *dlsch_buffer,
u16 N_RB_UL,
u8 input_buffer_length);
/* \brief This function indicates the end of RA procedure and provides the l3msg received on ULSCH.
@param Mod_id Instance ID of eNB
@param rnti RNTI of UE transmitting l3msg
@param l3msg Pointer to received l3msg
*/
void terminate_ra_proc(u8 Mod_id,u32 frame,u16 rnti, u8 *l3msg, u16 l3msg_len);
/* \brief Function to indicate a failed RA response. It removes all temporary variables related to the initial connection of a UE
@param Mod_id Instance ID of eNB
@param preamble_index index of the received RA request.
*/
void cancel_ra_proc(u8 Mod_id,u32 frame, u16 preamble_index);
/* \brief Function to indicate a received SDU on ULSCH.
@param Mod_id Instance ID of eNB
@param rnti RNTI of UE transmitting the SR
@param sdu Pointer to received SDU
*/
void rx_sdu(u8 Mod_id,u32 frame,u16 rnti, u8 *sdu, u16 sdu_len);
/* \brief Function to indicate a scheduled schduling request (SR) was received by eNB.
@param Mod_id Instance ID of eNB
@param rnti RNTI of UE transmitting the SR
@param subframe Index of subframe where SR was received
*/
void SR_indication(u8 Mod_id,u32 frame,u16 rnti, u8 subframe);
u8 *get_dlsch_sdu(u8 Mod_id,u32 frame,u16 rnti,u8 TBindex);
/* \brief Function to retrieve MCH transport block and MCS used for MCH in this MBSFN subframe. Returns null if no MCH is to be transmitted
@param Mod_id Instance ID of eNB
@param frame Index of frame
@param subframe Index of current subframe
@param mcs Pointer to mcs used by PHY (to be filled by MAC)
@returns Pointer to MCH transport block and mcs for subframe
*/
MCH_PDU *get_mch_sdu(uint8_t Mod_id,uint32_t frame,uint32_t subframe);
//added for ALU icic purpose
u32 Get_Cell_SBMap(u8 Mod_id);
void UpdateSBnumber(unsigned char Mod_id);
//end ALU's algo
void init_ue_sched_info(void);
void add_ue_ulsch_info(u8 Mod_id, u8 UE_id, u8 subframe,UE_ULSCH_STATUS status);
void add_ue_dlsch_info(u8 Mod_id, u8 UE_id, u8 subframe,UE_DLSCH_STATUS status);
s8 find_UE_id(u8 Mod_id,u16 rnti) ;
s16 find_UE_RNTI(u8 Mod_id, u8 UE_id);
s8 find_active_UEs(u8 Mod_id);
u8 is_UE_active(unsigned char Mod_id, unsigned char UE_id );
u16 find_ulgranted_UEs(u8 Mod_id);
u16 find_dlgranted_UEs(u8 Mod_id);
u8 process_ue_cqi (u8 Mod_id, u8 UE_id);
s8 find_active_UEs_with_traffic(unsigned char Mod_id);
u8 find_num_active_UEs_in_cbagroup(unsigned char Mod_id, unsigned char group_id);
u8 UE_is_to_be_scheduled(u8 Mod_id,u8 UE_id);
/** \brief Round-robin scheduler for ULSCH traffic.
@param Mod_id Instance ID for eNB
@param subframe Subframe number on which to act
@returns UE index that is to be scheduled if needed/room
*/
u8 schedule_next_ulue(u8 Mod_id, u8 UE_id,u8 subframe);
/** \brief Round-robin scheduler for DLSCH traffic.
@param Mod_id Instance ID for eNB
@param subframe Subframe number on which to act
@returns UE index that is to be scheduled if needed/room
*/
u8 schedule_next_dlue(u8 Mod_id, u8 subframe);
/* \brief Allocates a set of PRBS for a particular UE. This is a simple function for the moment, later it should process frequency-domain CQI information and/or PMI information. Currently it just returns the first PRBS that are available in the subframe based on the number requested.
@param UE_id Index of UE on which to act
@param nb_rb Number of PRBs allocated to UE by scheduler
@param rballoc Pointer to bit-map of current PRB allocation given to previous users/control channels. This is updated for subsequent calls to the routine.
@returns an rballoc bitmap for resource type 0 allocation (DCI).
*/
u32 allocate_prbs(u8 UE_id,u8 nb_rb, u32 *rballoc);
/* \fn u32 req_new_ulsch(u8 Mod_id)
\brief check for a new transmission in any drb
@param Mod_id Instance id of UE in machine
@returns 1 for new transmission, 0 for none
*/
u32 req_new_ulsch(u8 Mod_id);
/* \brief Get SR payload (0,1) from UE MAC
@param Mod_id Instance id of UE in machine
@param eNB_id Index of eNB that UE is attached to
@param rnti C_RNTI of UE
@param subframe subframe number
@returns 0 for no SR, 1 for SR
*/
u32 ue_get_SR(u8 Mod_id, u32 frame, u8 eNB_id,u16 rnti,u8 subframe);
u8 get_ue_weight(u8 Mod_id, u8 UE_id);
// UE functions
void mac_out_of_sync_ind(u8 Mod_id, u32 frame, u16 eNB_index);
void ue_decode_si(u8 Mod_id, u32 frame, u8 CH_index, void *pdu, u16 len);
void ue_send_sdu(u8 Mod_id, u32 frame, u8 *sdu,u16 sdu_len,u8 CH_index);
#ifdef Rel10
/* \brief Called by PHY to transfer MCH transport block to ue MAC.
@param Mod_id Index of module instance
@param frame Frame index
@param sdu Pointer to transport block
@param sdu_len Length of transport block
@param eNB_index Index of attached eNB
@param sync_area the index of MBSFN sync area
*/
void ue_send_mch_sdu(u8 Mod_id,u32 frame,u8 *sdu,u16 sdu_len,u8 eNB_index,u8 sync_area) ;
/*\brief Function to check if UE PHY needs to decode MCH for MAC.
@param Mod_id Index of protocol instance
@param frame Index of frame
@param subframe Index of subframe
@param eNB_index index of eNB for this MCH
@param[out] sync_area return the sync area
@param[out] mcch_active flag indicating whether this MCCH is active in this SF
*/
int ue_query_mch(uint8_t Mod_id,uint32_t frame,uint32_t subframe, uint8_t eNB_index, uint8_t *sync_area, uint8_t *mcch_active);
#endif
/* \brief Called by PHY to get sdu for PUSCH transmission. It performs the following operations: Checks BSR for DCCH, DCCH1 and DTCH corresponding to previous values computed either in SR or BSR procedures. It gets rlc status indications on DCCH,DCCH1 and DTCH and forms BSR elements and PHR in MAC header. CRNTI element is not supported yet. It computes transport block for up to 3 SDUs and generates header and forms the complete MAC SDU.
@param Mod_id Instance id of UE in machine
@param eNB_id Index of eNB that UE is attached to
@param rnti C_RNTI of UE
@param subframe subframe number
@returns 0 for no SR, 1 for SR
*/
void ue_get_sdu(u8 Mod_id, u32 frame, u8 subframe, u8 eNB_index,u8 *ulsch_buffer,u16 buflen,u8 *access_mode);
/* \brief Function called by PHY to retrieve information to be transmitted using the RA procedure. If the UE is not in PUSCH mode for a particular eNB index, this is assumed to be an Msg3 and MAC attempts to retrieves the CCCH message from RRC. If the UE is in PUSCH mode for a particular eNB index and PUCCH format 0 (Scheduling Request) is not activated, the MAC may use this resource for random-access to transmit a BSR along with the C-RNTI control element (see 5.1.4 from 36.321)
@param Mod_id Index of UE instance
@param New_Msg3 Flag to indicate this call is for a new Msg3
@param subframe Index of subframe for PRACH transmission (0 ... 9)
@returns A pointer to a PRACH_RESOURCES_t */
PRACH_RESOURCES_t *ue_get_rach(u8 Mod_id,u32 frame,u8 new_Msg3,u8 subframe);
/* \brief Function called by PHY to process the received RAR. It checks that the preamble matches what was sent by the eNB and provides the timing advance and t-CRNTI.
@param Mod_id Index of UE instance
@param dlsch_buffer Pointer to dlsch_buffer containing RAR PDU
@param t_crnti Pointer to PHY variable containing the T_CRNTI
@param preamble_index Preamble Index used by PHY to transmit the PRACH. This should match the received RAR to trigger the rest of
random-access procedure
@returns timing advance or 0xffff if preamble doesn't match
*/
u16 ue_process_rar(u8 Mod_id,u32 frame,u8 *dlsch_buffer,u16 *t_crnti,u8 preamble_index);
/* \brief Generate header for UL-SCH. This function parses the desired control elements and sdus and generates the header as described
in 36-321 MAC layer specifications. It returns the number of bytes used for the header to be used as an offset for the payload
in the ULSCH buffer.
@param mac_header Pointer to the first byte of the MAC header (UL-SCH buffer)
@param num_sdus Number of SDUs in the payload
@param short_padding Number of bytes for short padding (0,1,2)
@param sdu_lengths Pointer to array of SDU lengths
@param sdu_lcids Pointer to array of LCIDs (the order must be the same as the SDU length array)
@param power_headroom Pointer to power headroom command (NULL means not present in payload)
@param crnti Pointer to CRNTI command (NULL means not present in payload)
@param truncated_bsr Pointer to Truncated BSR command (NULL means not present in payload)
@param short_bsr Pointer to Short BSR command (NULL means not present in payload)
@param long_bsr Pointer to Long BSR command (NULL means not present in payload)
@param post_padding Number of bytes for padding at the end of MAC PDU
@returns Number of bytes used for header
*/
unsigned char generate_ulsch_header(u8 *mac_header,
u8 num_sdus,
u8 short_padding,
u16 *sdu_lengths,
u8 *sdu_lcids,
POWER_HEADROOM_CMD *power_headroom,
u16 *crnti,
BSR_SHORT *truncated_bsr,
BSR_SHORT *short_bsr,
BSR_LONG *long_bsr,
unsigned short post_padding);
/* \brief Parse header for UL-SCH. This function parses the received UL-SCH header as described
in 36-321 MAC layer specifications. It returns the number of bytes used for the header to be used as an offset for the payload
in the ULSCH buffer.
@param mac_header Pointer to the first byte of the MAC header (UL-SCH buffer)
@param num_ces Number of SDUs in the payload
@param num_sdu Number of SDUs in the payload
@param rx_ces Pointer to received CEs in the header
@param rx_lcids Pointer to array of LCIDs (the order must be the same as the SDU length array)
@param rx_lengths Pointer to array of SDU lengths
@returns Pointer to payload following header
*/
u8 *parse_ulsch_header(u8 *mac_header,
u8 *num_ce,
u8 *num_sdu,
u8 *rx_ces,
u8 *rx_lcids,
u16 *rx_lengths,
u16 tx_lenght);
int l2_init(LTE_DL_FRAME_PARMS *frame_parms,int eMBMS_active, u8 cba_group_active);
int mac_init(void);
void ue_init_mac(void);
s8 add_new_ue(u8 Mod_id, u16 rnti);
s8 mac_remove_ue(u8 Mod_id, u8 UE_id);
/*! \fn UE_L2_state_t ue_scheduler(u8 Mod_id,u32 frame, u8 subframe, lte_subframe_t direction,u8 eNB_index)
\brief UE scheduler where all the ue background tasks are done. This function performs the following: 1) Trigger PDCP every 5ms 2) Call RRC for link status return to PHY3) Perform SR/BSR procedures for scheduling feedback 4) Perform PHR procedures.
\param[in] Mod_id instance of the UE
\param[in] subframe the subframe number
\param[in] direction subframe direction
\param[in] eNB_index instance of eNB
@returns L2 state (CONNETION_OK or CONNECTION_LOST or PHY_RESYNCH)
*/
UE_L2_STATE_t ue_scheduler(u8 Mod_id,u32 frame, u8 subframe, lte_subframe_t direction,u8 eNB_index);
/*! \fn int use_cba_access(u8 Mod_id,u32 frame,u8 subframe, u8 eNB_index);
\brief determine whether to use cba resource to transmit or not
\param[in] Mod_id instance of the UE
\param[in] frame the frame number
\param[in] subframe the subframe number
\param[in] eNB_index instance of eNB
\param[out] access(1) or postpone (0)
*/
int use_cba_access(u8 Mod_id,u32 frame,u8 subframe, u8 eNB_index);
/*! \fn int get_bsr_lcgid (u8 Mod_id);
\brief determine the lcgid for the bsr
\param[in] Mod_id instance of the UE
\param[out] lcgid
*/
int get_bsr_lcgid (u8 Mod_id);
/*! \fn u8 get_bsr_len (u8 Mod_id, u16 bufflen);
\brief determine whether the bsr is short or long assuming that the MAC pdu is built
\param[in] Mod_id instance of the UE
\param[in] bufflen size of phy transport block
\param[out] bsr_len size of bsr control element
*/
u8 get_bsr_len (u8 Mod_id, u16 buflen);
/*! \fn BSR_SHORT * get_bsr_short(u8 Mod_id, u8 bsr_len)
\brief get short bsr level
\param[in] Mod_id instance of the UE
\param[in] bsr_len indicator for no, short, or long bsr
\param[out] bsr_s pointer to short bsr
*/
BSR_SHORT *get_bsr_short(u8 Mod_id, u8 bsr_len);
/*! \fn BSR_LONG * get_bsr_long(u8 Mod_id, u8 bsr_len)
\brief get long bsr level
\param[in] Mod_id instance of the UE
\param[in] bsr_len indicator for no, short, or long bsr
\param[out] bsr_l pointer to long bsr
*/
BSR_LONG * get_bsr_long(u8 Mod_id, u8 bsr_len);
/*! \fn int update_bsr(u8 Mod_id, u32 frame, u8 lcid)
\brief get the rlc stats and update the bsr level for each lcid
\param[in] Mod_id instance of the UE
\param[in] frame Frame index
\param[in] lcid logical channel identifier
*/
int update_bsr(u8 Mod_id, u32 frame, u8 lcid, u8 lcgid);
/*! \fn locate (int *table, int size, int value)
\brief locate the BSR level in the table as defined in 36.321. This function requires that he values in table to be monotonic, either increasing or decreasing. The returned value is not less than 0, nor greater than n-1, where n is the size of table.
\param[in] *table Pointer to BSR table
\param[in] size Size of the table
\param[in] value Value of the buffer
\return the index in the BSR_LEVEL table
*/
u8 locate (const u32 *table, int size, int value);
/*! \fn int get_sf_periodicBSRTimer(u8 periodicBSR_Timer)
\brief get the number of subframe from the periodic BSR timer configured by the higher layers
\param[in] periodicBSR_Timer timer for periodic BSR
\return the number of subframe
*/
int get_sf_periodicBSRTimer(u8 bucketSize);
/*! \fn int get_ms_bucketsizeduration(u8 bucketSize)
\brief get the time in ms form the bucket size duration configured by the higher layer
\param[in] bucketSize the bucket size duration
\return the time in ms
*/
int get_ms_bucketsizeduration(u8 bucketsizeduration);
/*! \fn int get_sf_retxBSRTimer(u8 retxBSR_Timer)
\brief get the number of subframe form the bucket size duration configured by the higher layer
\param[in] retxBSR_Timer timer for regular BSR
\return the time in sf
*/
int get_sf_retxBSRTimer(u8 retxBSR_Timer);
/*! \fn int get_sf_perioidicPHR_Timer(u8 perioidicPHR_Timer){
\brief get the number of subframe form the periodic PHR timer configured by the higher layer
\param[in] perioidicPHR_Timer timer for reguluar PHR
\return the time in sf
*/
int get_sf_perioidicPHR_Timer(u8 perioidicPHR_Timer);
/*! \fn int get_sf_prohibitPHR_Timer(u8 prohibitPHR_Timer)
\brief get the number of subframe form the prohibit PHR duration configured by the higher layer
\param[in] prohibitPHR_Timer timer for PHR
\return the time in sf
*/
int get_sf_prohibitPHR_Timer(u8 prohibitPHR_Timer);
/*! \fn int get_db_dl_PathlossChange(u8 dl_PathlossChange)
\brief get the db form the path loss change configured by the higher layer
\param[in] dl_PathlossChange path loss for PHR
\return the pathloss in db
*/
int get_db_dl_PathlossChange(u8 dl_PathlossChange);
/*! \fn u8 get_phr_mapping (u8 Mod_id, u8 eNB_index)
\brief get phr mapping as described in 36.313
\param[in] Mod_id index of eNB
\return phr mapping
*/
u8 get_phr_mapping (u8 Mod_id, u8 eNB_index);
/*! \fn void update_phr (u8 Mod_id)
\brief update/reset the phr timers
\param[in] Mod_id index of eNB
\return void
*/
void update_phr (u8 Mod_id);
/*! \brief Function to indicate Msg3 transmission/retransmission which initiates/reset Contention Resolution Timer
\param[in] Mod_id Instance index of UE
\param[in] eNB_id Index of eNB
*/
void Msg3_tx(u8 Mod_id,u32 frame,u8 eNB_id);
/*! \brief Function to indicate the transmission of msg1/rach
\param[in] Mod_id Instance index of UE
\param[in] eNB_id Index of eNB
*/
void Msg1_tx(u8 Mod_id,u32 frame, u8 eNB_id);
void dl_phy_sync_success(unsigned char Mod_id,
u32 frame,
unsigned char eNB_index,
u8 first_sync);
int dump_eNB_l2_stats(char *buffer, int length);
double uniform_rngen(int min, int max);
/*@}*/
#endif /*__LAYER2_MAC_DEFS_H__ */