/* * Copyright (c) 2016 Nordic Semiconductor ASA * Copyright (c) 2016 Vinayak Kariappa Chettimada * * SPDX-License-Identifier: Apache-2.0 */ /* * PDU fields sizes */ #define PDU_PREAMBLE_SIZE(phy) (phy&0x3) #define PDU_ACCESS_ADDR_SIZE 4 #define PDU_HEADER_SIZE 2 #define PDU_MIC_SIZE 4 #define PDU_CRC_SIZE 3 #define PDU_OVERHEAD_SIZE(phy) (PDU_PREAMBLE_SIZE(phy) + \ PDU_ACCESS_ADDR_SIZE + \ PDU_HEADER_SIZE + \ PDU_CRC_SIZE) #define BDADDR_SIZE 6 #define ADVA_SIZE BDADDR_SIZE #define SCANA_SIZE BDADDR_SIZE #define INITA_SIZE BDADDR_SIZE #define TARGETA_SIZE BDADDR_SIZE #define LLDATA_SIZE 22 /* Constant offsets in extended header (TargetA is present in PDUs with AdvA) */ #define ADVA_OFFSET 0 #define TGTA_OFFSET (ADVA_OFFSET + BDADDR_SIZE) #define BYTES2US(bytes, phy) (((bytes)<<3)/BIT((phy&0x3)>>1)) /* Advertisement channel maximum legacy payload size */ #define PDU_AC_LEG_PAYLOAD_SIZE_MAX 37 /* Advertisement channel maximum extended payload size */ #define PDU_AC_EXT_PAYLOAD_SIZE_MAX 255 /* Advertisement channel maximum payload size */ #if defined(CONFIG_BT_CTLR_ADV_EXT) #define PDU_AC_EXT_HEADER_SIZE_MIN offsetof(struct pdu_adv_com_ext_adv, \ ext_hdr_adv_data) #define PDU_AC_EXT_HEADER_SIZE_MAX 63 /* TODO: PDU_AC_EXT_PAYLOAD_OVERHEAD can be reduced based on supported * features, like omitting support for periodic advertising will reduce * 18 octets in the Common Extended Advertising Payload Format. */ #define PDU_AC_EXT_PAYLOAD_OVERHEAD (PDU_AC_EXT_HEADER_SIZE_MIN + \ PDU_AC_EXT_HEADER_SIZE_MAX) #define PDU_AC_PAYLOAD_SIZE_MAX MAX(MIN((PDU_AC_EXT_PAYLOAD_OVERHEAD + \ CONFIG_BT_CTLR_ADV_DATA_LEN_MAX), \ PDU_AC_EXT_PAYLOAD_SIZE_MAX), \ PDU_AC_LEG_PAYLOAD_SIZE_MAX) #else #define PDU_AC_PAYLOAD_SIZE_MAX PDU_AC_LEG_PAYLOAD_SIZE_MAX #endif /* Link Layer header size of Adv PDU. Assumes pdu_adv is packed */ #define PDU_AC_LL_HEADER_SIZE (offsetof(struct pdu_adv, payload)) /* Link Layer Advertisement channel maximum PDU buffer size */ #define PDU_AC_LL_SIZE_MAX (PDU_AC_LL_HEADER_SIZE + PDU_AC_PAYLOAD_SIZE_MAX) /* Advertisement channel maximum legacy advertising/scan data size */ #define PDU_AC_DATA_SIZE_MAX 31 /* Advertisement channel Access Address */ #define PDU_AC_ACCESS_ADDR 0x8e89bed6 /* Data channel minimum payload size and time */ #define PDU_DC_PAYLOAD_SIZE_MIN 27 #define PDU_DC_PAYLOAD_TIME_MIN 328 /* Link Layer header size of Data PDU. Assumes pdu_data is packed */ #define PDU_DC_LL_HEADER_SIZE (offsetof(struct pdu_data, lldata)) /* Link Layer Max size of an empty PDU. TODO: Remove; only used in Nordic LLL */ #define PDU_EM_LL_SIZE_MAX (PDU_DC_LL_HEADER_SIZE) /* Event interframe timings */ #define EVENT_IFS_US 150 /* Standard allows 2 us timing uncertainty inside the event */ #define EVENT_IFS_MAX_US (EVENT_IFS_US + 2) /* Controller will layout extended adv with minimum separation */ #define EVENT_MAFS_US 300 /* Standard allows 2 us timing uncertainty inside the event */ #define EVENT_MAFS_MAX_US (EVENT_MAFS_US + 2) /* Offset Units field encoding */ #define OFFS_UNIT_30_US 30 #define OFFS_UNIT_300_US 300 /* Value specified in BT Spec. Vol 6, Part B, section 2.3.4.6 */ #define OFFS_ADJUST_US 245760 /* transmitWindowDelay times (us) */ #define WIN_DELAY_LEGACY 1250 #define WIN_DELAY_UNCODED 2500 #define WIN_DELAY_CODED 3750 /* * Macros to return correct Data Channel PDU time * Note: formula is valid for 1M, 2M and Coded S8 * see BT spec Version 5.1 Vol 6. Part B, chapters 2.1 and 2.2 * for packet formats and thus lengths */ #define PHY_LEGACY 0 #define PHY_1M BIT(0) #define PHY_2M BIT(1) #define PHY_CODED BIT(2) #if defined(CONFIG_BT_CTLR_PHY_CODED) #define CODED_PHY_PREAMBLE_TIME_US 80 #define CODED_PHY_ACCESS_ADDRESS_TIME_US 256 #define CODED_PHY_CI_TIME_US 16 #define CODED_PHY_TERM1_TIME_US 24 #define CODED_PHY_CRC_SIZE 24 #define CODED_PHY_TERM2_SIZE 3 #define FEC_BLOCK1_TIME_US ((CODED_PHY_ACCESS_ADDRESS_TIME_US) + \ (CODED_PHY_CI_TIME_US) + \ (CODED_PHY_TERM1_TIME_US)) #define FEC_BLOCK2_TIME_US(octets, mic) (((((PDU_HEADER_SIZE) + \ (octets) + \ (mic))<<3) + \ (CODED_PHY_CRC_SIZE) + \ (CODED_PHY_TERM2_SIZE))<<3) #define PKT_DC_US(octets, mic, phy) (((phy) & PHY_CODED) ? \ ((CODED_PHY_PREAMBLE_TIME_US) + \ (FEC_BLOCK1_TIME_US) + \ FEC_BLOCK2_TIME_US((octets), (mic))) : \ (((PDU_PREAMBLE_SIZE(phy) + \ (PDU_ACCESS_ADDR_SIZE) + \ (PDU_HEADER_SIZE) + \ (octets) + \ (mic) + \ (PDU_CRC_SIZE))<<3) / \ BIT(((phy) & 0x03) >> 1))) #else /* !CONFIG_BT_CTLR_PHY_CODED */ #define PKT_DC_US(octets, mic, phy) (((PDU_PREAMBLE_SIZE(phy) + \ (PDU_ACCESS_ADDR_SIZE) + \ (PDU_HEADER_SIZE) + \ (octets) + \ (mic) + \ (PDU_CRC_SIZE))<<3) / \ BIT(((phy) & 0x03) >> 1)) #endif /* !CONFIG_BT_CTLR_PHY_CODED */ #define PKT_US(octets, phy) PKT_DC_US((octets), (PDU_MIC_SIZE), (phy)) #define PKT_AC_US(octets, mic, phy) PKT_DC_US((octets), (mic), (phy)) /* Extra bytes for enqueued node_rx metadata: rssi (always), resolving * index, directed adv report, and mesh channel and instant. */ #define PDU_AC_SIZE_RSSI 1 #if defined(CONFIG_BT_CTLR_PRIVACY) #define PDU_AC_SIZE_PRIV 1 #else #define PDU_AC_SIZE_PRIV 0 #endif /* CONFIG_BT_CTLR_PRIVACY */ #if defined(CONFIG_BT_CTLR_EXT_SCAN_FP) #define PDU_AC_SIZE_SCFP 1 #else #define PDU_AC_SIZE_SCFP 0 #endif /* CONFIG_BT_CTLR_EXT_SCAN_FP */ #if defined(CONFIG_BT_HCI_MESH_EXT) #define PDU_AC_SIZE_MESH 5 #else #define PDU_AC_SIZE_MESH 0 #endif /* CONFIG_BT_HCI_MESH_EXT */ #define PDU_AC_LL_SIZE_EXTRA (PDU_AC_SIZE_RSSI + \ PDU_AC_SIZE_PRIV + \ PDU_AC_SIZE_SCFP + \ PDU_AC_SIZE_MESH) struct pdu_adv_adv_ind { uint8_t addr[BDADDR_SIZE]; uint8_t data[PDU_AC_DATA_SIZE_MAX]; } __packed; struct pdu_adv_direct_ind { uint8_t adv_addr[BDADDR_SIZE]; uint8_t tgt_addr[BDADDR_SIZE]; } __packed; struct pdu_adv_scan_rsp { uint8_t addr[BDADDR_SIZE]; uint8_t data[PDU_AC_DATA_SIZE_MAX]; } __packed; struct pdu_adv_scan_req { uint8_t scan_addr[BDADDR_SIZE]; uint8_t adv_addr[BDADDR_SIZE]; } __packed; struct pdu_adv_connect_ind { uint8_t init_addr[BDADDR_SIZE]; uint8_t adv_addr[BDADDR_SIZE]; struct { uint8_t access_addr[4]; uint8_t crc_init[3]; uint8_t win_size; uint16_t win_offset; uint16_t interval; uint16_t latency; uint16_t timeout; uint8_t chan_map[5]; #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t hop:5; uint8_t sca:3; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t sca:3; uint8_t hop:5; #else #error "Unsupported endianness" #endif } __packed; } __packed; struct pdu_adv_ext_hdr { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t adv_addr:1; uint8_t tgt_addr:1; uint8_t cte_info:1; uint8_t adi:1; uint8_t aux_ptr:1; uint8_t sync_info:1; uint8_t tx_pwr:1; uint8_t rfu1:1; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t rfu1:1; uint8_t tx_pwr:1; uint8_t sync_info:1; uint8_t aux_ptr:1; uint8_t adi:1; uint8_t cte_info:1; uint8_t tgt_addr:1; uint8_t adv_addr:1; #else #error "Unsupported endianness" #endif uint8_t data[0]; } __packed; struct pdu_adv_com_ext_adv { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t ext_hdr_len:6; uint8_t adv_mode:2; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t adv_mode:2; uint8_t ext_hdr_len:6; #else #error "Unsupported endianness" #endif union { struct pdu_adv_ext_hdr ext_hdr; uint8_t ext_hdr_adv_data[254]; }; } __packed; enum pdu_adv_mode { EXT_ADV_MODE_NON_CONN_NON_SCAN = 0x00, EXT_ADV_MODE_CONN_NON_SCAN = 0x01, EXT_ADV_MODE_NON_CONN_SCAN = 0x02, }; struct pdu_adv_adi { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint16_t did:12; uint16_t sid:4; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint16_t sid:4; uint16_t did:12; #else #error "Unsupported endianness" #endif } __packed; struct pdu_adv_aux_ptr { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t chan_idx:6; uint8_t ca:1; uint8_t offs_units:1; uint16_t offs:13; uint16_t phy:3; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t offs_units:1; uint8_t ca:1; uint8_t chan_idx:6; uint16_t phy:3; uint16_t offs:13; #else #error "Unsupported endianness" #endif } __packed; enum pdu_adv_aux_ptr_ca { EXT_ADV_AUX_PTR_CA_500_PPM = 0x00, EXT_ADV_AUX_PTR_CA_50_PPM = 0x01, }; enum pdu_adv_offs_units { EXT_ADV_AUX_PTR_OFFS_UNITS_30 = 0x00, EXT_ADV_AUX_PTR_OFFS_UNITS_300 = 0x01, }; enum pdu_adv_aux_phy { EXT_ADV_AUX_PHY_LE_1M = 0x00, EXT_ADV_AUX_PHY_LE_2M = 0x01, EXT_ADV_AUX_PHY_LE_COD = 0x02, }; struct pdu_cte_info { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t time:5; uint8_t rfu:1; uint8_t type:2; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t type:2; uint8_t rfu:1; uint8_t time:5; #else #error "Unsupported endianness" #endif }; struct pdu_adv_sync_info { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint16_t offs:13; uint16_t offs_units:1; uint16_t offs_adjust:1; uint16_t rfu:1; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint16_t rfu:1; uint16_t offs_adjust:1; uint16_t offs_units:1; uint16_t offs:13; #else #error "Unsupported endianness" #endif uint16_t interval; uint8_t sca_chm[5]; uint32_t aa; uint8_t crc_init[3]; uint16_t evt_cntr; } __packed; enum pdu_adv_type { PDU_ADV_TYPE_ADV_IND = 0x00, PDU_ADV_TYPE_DIRECT_IND = 0x01, PDU_ADV_TYPE_NONCONN_IND = 0x02, PDU_ADV_TYPE_SCAN_REQ = 0x03, PDU_ADV_TYPE_AUX_SCAN_REQ = PDU_ADV_TYPE_SCAN_REQ, PDU_ADV_TYPE_SCAN_RSP = 0x04, PDU_ADV_TYPE_ADV_IND_SCAN_RSP = 0x05, PDU_ADV_TYPE_CONNECT_IND = 0x05, PDU_ADV_TYPE_AUX_CONNECT_REQ = PDU_ADV_TYPE_CONNECT_IND, PDU_ADV_TYPE_SCAN_IND = 0x06, PDU_ADV_TYPE_EXT_IND = 0x07, PDU_ADV_TYPE_AUX_ADV_IND = PDU_ADV_TYPE_EXT_IND, PDU_ADV_TYPE_AUX_SCAN_RSP = PDU_ADV_TYPE_EXT_IND, PDU_ADV_TYPE_AUX_SYNC_IND = PDU_ADV_TYPE_EXT_IND, PDU_ADV_TYPE_AUX_CHAIN_IND = PDU_ADV_TYPE_EXT_IND, PDU_ADV_TYPE_AUX_CONNECT_RSP = 0x08, } __packed; struct pdu_adv { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t type:4; uint8_t rfu:1; uint8_t chan_sel:1; uint8_t tx_addr:1; uint8_t rx_addr:1; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t rx_addr:1; uint8_t tx_addr:1; uint8_t chan_sel:1; uint8_t rfu:1; uint8_t type:4; #else #error "Unsupported endianness" #endif uint8_t len; union { uint8_t payload[0]; struct pdu_adv_adv_ind adv_ind; struct pdu_adv_direct_ind direct_ind; struct pdu_adv_scan_req scan_req; struct pdu_adv_scan_rsp scan_rsp; struct pdu_adv_connect_ind connect_ind; #if defined(CONFIG_BT_CTLR_ADV_EXT) struct pdu_adv_com_ext_adv adv_ext_ind; #endif /* CONFIG_BT_CTLR_ADV_EXT */ } __packed; } __packed; enum pdu_data_llid { PDU_DATA_LLID_RESV = 0x00, PDU_DATA_LLID_DATA_CONTINUE = 0x01, PDU_DATA_LLID_DATA_START = 0x02, PDU_DATA_LLID_CTRL = 0x03, }; enum pdu_data_llctrl_type { PDU_DATA_LLCTRL_TYPE_CONN_UPDATE_IND = 0x00, PDU_DATA_LLCTRL_TYPE_CHAN_MAP_IND = 0x01, PDU_DATA_LLCTRL_TYPE_TERMINATE_IND = 0x02, PDU_DATA_LLCTRL_TYPE_ENC_REQ = 0x03, PDU_DATA_LLCTRL_TYPE_ENC_RSP = 0x04, PDU_DATA_LLCTRL_TYPE_START_ENC_REQ = 0x05, PDU_DATA_LLCTRL_TYPE_START_ENC_RSP = 0x06, PDU_DATA_LLCTRL_TYPE_UNKNOWN_RSP = 0x07, PDU_DATA_LLCTRL_TYPE_FEATURE_REQ = 0x08, PDU_DATA_LLCTRL_TYPE_FEATURE_RSP = 0x09, PDU_DATA_LLCTRL_TYPE_PAUSE_ENC_REQ = 0x0A, PDU_DATA_LLCTRL_TYPE_PAUSE_ENC_RSP = 0x0B, PDU_DATA_LLCTRL_TYPE_VERSION_IND = 0x0C, PDU_DATA_LLCTRL_TYPE_REJECT_IND = 0x0D, PDU_DATA_LLCTRL_TYPE_SLAVE_FEATURE_REQ = 0x0E, PDU_DATA_LLCTRL_TYPE_CONN_PARAM_REQ = 0x0F, PDU_DATA_LLCTRL_TYPE_CONN_PARAM_RSP = 0x10, PDU_DATA_LLCTRL_TYPE_REJECT_EXT_IND = 0x11, PDU_DATA_LLCTRL_TYPE_PING_REQ = 0x12, PDU_DATA_LLCTRL_TYPE_PING_RSP = 0x13, PDU_DATA_LLCTRL_TYPE_LENGTH_REQ = 0x14, PDU_DATA_LLCTRL_TYPE_LENGTH_RSP = 0x15, PDU_DATA_LLCTRL_TYPE_PHY_REQ = 0x16, PDU_DATA_LLCTRL_TYPE_PHY_RSP = 0x17, PDU_DATA_LLCTRL_TYPE_PHY_UPD_IND = 0x18, PDU_DATA_LLCTRL_TYPE_MIN_USED_CHAN_IND = 0x19, PDU_DATA_LLCTRL_TYPE_CIS_REQ = 0x1F, PDU_DATA_LLCTRL_TYPE_CIS_RSP = 0x20, PDU_DATA_LLCTRL_TYPE_CIS_IND = 0x21, PDU_DATA_LLCTRL_TYPE_CIS_TERMINATE_IND = 0x22, }; struct pdu_data_llctrl_conn_update_ind { uint8_t win_size; uint16_t win_offset; uint16_t interval; uint16_t latency; uint16_t timeout; uint16_t instant; } __packed; struct pdu_data_llctrl_chan_map_ind { uint8_t chm[5]; uint16_t instant; } __packed; struct pdu_data_llctrl_terminate_ind { uint8_t error_code; } __packed; struct pdu_data_llctrl_enc_req { uint8_t rand[8]; uint8_t ediv[2]; uint8_t skdm[8]; uint8_t ivm[4]; } __packed; struct pdu_data_llctrl_enc_rsp { uint8_t skds[8]; uint8_t ivs[4]; } __packed; struct pdu_data_llctrl_start_enc_req { /* no members */ } __packed; struct pdu_data_llctrl_start_enc_rsp { /* no members */ } __packed; struct pdu_data_llctrl_unknown_rsp { uint8_t type; } __packed; struct pdu_data_llctrl_feature_req { uint8_t features[8]; } __packed; struct pdu_data_llctrl_feature_rsp { uint8_t features[8]; } __packed; struct pdu_data_llctrl_pause_enc_req { /* no members */ } __packed; struct pdu_data_llctrl_pause_enc_rsp { /* no members */ } __packed; struct pdu_data_llctrl_version_ind { uint8_t version_number; uint16_t company_id; uint16_t sub_version_number; } __packed; struct pdu_data_llctrl_reject_ind { uint8_t error_code; } __packed; struct pdu_data_llctrl_slave_feature_req { uint8_t features[8]; } __packed; struct pdu_data_llctrl_conn_param_req { uint16_t interval_min; uint16_t interval_max; uint16_t latency; uint16_t timeout; uint8_t preferred_periodicity; uint16_t reference_conn_event_count; uint16_t offset0; uint16_t offset1; uint16_t offset2; uint16_t offset3; uint16_t offset4; uint16_t offset5; } __packed; struct pdu_data_llctrl_conn_param_rsp { uint16_t interval_min; uint16_t interval_max; uint16_t latency; uint16_t timeout; uint8_t preferred_periodicity; uint16_t reference_conn_event_count; uint16_t offset0; uint16_t offset1; uint16_t offset2; uint16_t offset3; uint16_t offset4; uint16_t offset5; } __packed; struct pdu_data_llctrl_reject_ext_ind { uint8_t reject_opcode; uint8_t error_code; } __packed; struct pdu_data_llctrl_ping_req { /* no members */ } __packed; struct pdu_data_llctrl_ping_rsp { /* no members */ } __packed; struct pdu_data_llctrl_length_req { uint16_t max_rx_octets; uint16_t max_rx_time; uint16_t max_tx_octets; uint16_t max_tx_time; } __packed; struct pdu_data_llctrl_length_rsp { uint16_t max_rx_octets; uint16_t max_rx_time; uint16_t max_tx_octets; uint16_t max_tx_time; } __packed; struct pdu_data_llctrl_phy_req { uint8_t tx_phys; uint8_t rx_phys; } __packed; struct pdu_data_llctrl_phy_rsp { uint8_t tx_phys; uint8_t rx_phys; } __packed; struct pdu_data_llctrl_phy_upd_ind { uint8_t m_to_s_phy; uint8_t s_to_m_phy; uint16_t instant; } __packed; struct pdu_data_llctrl_min_used_chans_ind { uint8_t phys; uint8_t min_used_chans; } __packed; struct pdu_data_llctrl_cis_req { uint8_t cig_id; uint8_t cis_id; uint8_t c_phy; uint8_t p_phy; #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint16_t c_max_sdu:12; uint16_t rfu0:3; uint16_t framed:1; uint16_t p_max_sdu:12; uint16_t rfu1:4; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint16_t framed:1; uint16_t rfu0:3; uint16_t c_max_sdu:12; uint16_t rfu1:4; uint16_t p_max_sdu:12; #else #error "Unsupported endianness" #endif uint8_t c_sdu_interval[3]; uint8_t p_sdu_interval[3]; uint16_t c_max_pdu; uint16_t p_max_pdu; uint8_t nse; uint8_t sub_interval[3]; #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t c_bn:4; uint8_t p_bn:4; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t p_bn:4; uint8_t c_bn:4; #else #error "Unsupported endianness" #endif uint8_t c_ft; uint8_t p_ft; uint16_t iso_interval; uint8_t cis_offset_min[3]; uint8_t cis_offset_max[3]; uint16_t conn_event_count; } __packed; struct pdu_data_llctrl_cis_rsp { uint8_t cis_offset_min[3]; uint8_t cis_offset_max[3]; uint16_t conn_event_count; } __packed; struct pdu_data_llctrl_cis_ind { uint8_t aa[4]; uint8_t cis_offset[3]; uint8_t cig_sync_delay[3]; uint8_t cis_sync_delay[3]; uint16_t conn_event_count; } __packed; struct pdu_data_llctrl_cis_terminate_ind { uint8_t cig_id; uint8_t cis_id; uint8_t error_code; } __packed; struct pdu_data_llctrl { uint8_t opcode; union { struct pdu_data_llctrl_conn_update_ind conn_update_ind; struct pdu_data_llctrl_chan_map_ind chan_map_ind; struct pdu_data_llctrl_terminate_ind terminate_ind; struct pdu_data_llctrl_enc_req enc_req; struct pdu_data_llctrl_enc_rsp enc_rsp; struct pdu_data_llctrl_start_enc_req start_enc_req; struct pdu_data_llctrl_start_enc_rsp start_enc_rsp; struct pdu_data_llctrl_unknown_rsp unknown_rsp; struct pdu_data_llctrl_feature_req feature_req; struct pdu_data_llctrl_feature_rsp feature_rsp; struct pdu_data_llctrl_pause_enc_req pause_enc_req; struct pdu_data_llctrl_pause_enc_rsp pause_enc_rsp; struct pdu_data_llctrl_version_ind version_ind; struct pdu_data_llctrl_reject_ind reject_ind; struct pdu_data_llctrl_slave_feature_req slave_feature_req; struct pdu_data_llctrl_conn_param_req conn_param_req; struct pdu_data_llctrl_conn_param_rsp conn_param_rsp; struct pdu_data_llctrl_reject_ext_ind reject_ext_ind; struct pdu_data_llctrl_ping_req ping_req; struct pdu_data_llctrl_ping_rsp ping_rsp; struct pdu_data_llctrl_length_req length_req; struct pdu_data_llctrl_length_rsp length_rsp; struct pdu_data_llctrl_phy_req phy_req; struct pdu_data_llctrl_phy_rsp phy_rsp; struct pdu_data_llctrl_phy_upd_ind phy_upd_ind; struct pdu_data_llctrl_min_used_chans_ind min_used_chans_ind; struct pdu_data_llctrl_cis_req cis_req; struct pdu_data_llctrl_cis_rsp cis_rsp; struct pdu_data_llctrl_cis_ind cis_ind; struct pdu_data_llctrl_cis_terminate_ind cis_terminate_ind; } __packed; } __packed; #define PDU_DATA_LLCTRL_LEN(type) (offsetof(struct pdu_data_llctrl, type) + \ sizeof(struct pdu_data_llctrl_ ## type)) #if defined(CONFIG_BT_CTLR_PROFILE_ISR) struct profile { uint8_t lcur; uint8_t lmin; uint8_t lmax; uint8_t cur; uint8_t min; uint8_t max; uint8_t radio; uint8_t lll; uint8_t ull_high; uint8_t ull_low; } __packed; #endif /* CONFIG_BT_CTLR_PROFILE_ISR */ struct pdu_data { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t ll_id:2; uint8_t nesn:1; uint8_t sn:1; uint8_t md:1; uint8_t rfu:3; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t rfu:3; uint8_t md:1; uint8_t sn:1; uint8_t nesn:1; uint8_t ll_id:2; #else #error "Unsupported endianness" #endif uint8_t len; #if !defined(CONFIG_SOC_OPENISA_RV32M1_RISCV32) #if !defined(CONFIG_BT_CTLR_DATA_LENGTH_CLEAR) uint8_t resv:8; /* TODO: remove nRF specific code */ #endif /* !CONFIG_BT_CTLR_DATA_LENGTH_CLEAR */ #endif /* !CONFIG_SOC_OPENISA_RV32M1_RISCV32 */ union { struct pdu_data_llctrl llctrl; uint8_t lldata[0]; #if defined(CONFIG_BT_CTLR_CONN_RSSI) uint8_t rssi; #endif /* CONFIG_BT_CTLR_CONN_RSSI */ #if defined(CONFIG_BT_CTLR_PROFILE_ISR) struct profile profile; #endif /* CONFIG_BT_CTLR_PROFILE_ISR */ } __packed; } __packed; struct pdu_cis { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t ll_id:2; uint8_t nesn:1; uint8_t sn:1; uint8_t cie:1; uint8_t rfu0:1; uint8_t npi:1; uint8_t rfu1:1; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t rfu1:1; uint8_t npi:1; uint8_t rfu0:1; uint8_t cie:1; uint8_t sn:1; uint8_t nesn:1; uint8_t ll_id:2; #else #error "Unsupported endianness" #endif /* __BYTE_ORDER__ */ uint8_t length; uint8_t payload[0]; } __packed; enum pdu_big_ctrl_type { PDU_BIG_CTRL_TYPE_CHAN_MAP_IND = 0x00, PDU_BIG_CTRL_TYPE_TERM_IND = 0x01, }; struct pdu_big_ctrl_chan_map_ind { uint8_t chm[5]; uint16_t instant; } __packed; struct pdu_big_ctrl_term_ind { uint8_t reason; uint16_t instant; } __packed; struct pdu_big_ctrl { uint8_t opcode; union { uint8_t ctrl_data[0]; struct pdu_big_ctrl_chan_map_ind chan_map_ind; struct pdu_big_ctrl_term_ind term_ind; } __packed; } __packed; enum pdu_bis_llid { /** Unframed complete or end fragment */ PDU_BIS_LLID_COMPLETE_END = 0x00, /** Unframed start or continuation fragment */ PDU_BIS_LLID_START_CONTINUE = 0x01, /** Framed; one or more segments of a SDU */ PDU_BIS_LLID_FRAMED = 0x02, /** BIG Control PDU */ PDU_BIS_LLID_CTRL = 0x03, }; struct pdu_bis { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint8_t ll_id:2; uint8_t cssn:3; uint8_t cstf:1; uint8_t rfu:2; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint8_t rfu:2; uint8_t cstf:1; uint8_t cssn:3; uint8_t ll_id:2; #else #error "Unsupported endianness" #endif /* __BYTE_ORDER__ */ uint8_t length; union { uint8_t payload[0]; struct pdu_big_ctrl ctrl; } __packed; } __packed; struct pdu_big_info { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ uint32_t offset:14; uint32_t offset_units:1; uint32_t iso_interval:12; uint32_t num_bis:5; uint32_t nse:5; uint32_t bn:3; uint32_t sub_interval:20; uint32_t pto:4; uint32_t spacing:20; uint32_t irc:4; uint32_t max_pdu:8; uint8_t rfu; uint32_t seed_access_addr; uint32_t sdu_interval:20; uint32_t max_sdu:12; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ uint32_t num_bis:5; uint32_t iso_interval:12; uint32_t offset_units:1; uint32_t offset:14; uint32_t pto:4; uint32_t sub_interval:20; uint32_t bn:3; uint32_t nse:5; uint32_t max_pdu:8; uint32_t irc:4; uint32_t spacing:20; uint8_t rfu; uint32_t seed_access_addr; uint32_t max_sdu:12; uint32_t sdu_interval:20; #else #error "Unsupported endianness" #endif /* __BYTE_ORDER__ */ uint16_t base_crc_init; uint8_t chm_phy[5]; /* 37 bit chm; 3 bit phy */ uint8_t payload_count_framing[5]; /* 39 bit count; 1 bit framing */ uint8_t giv; /* encryption required */ uint16_t gskd; /* encryption required */ } __packed;