/****************************************************************************** * * Copyright 1999-2012 Broadcom Corporation * * 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. * ******************************************************************************/ /***************************************************************************** * * This file contains definitions internal to the RFC unit * *****************************************************************************/ #ifndef RFC_INT_H #define RFC_INT_H #include #include #include #include "stack/include/bt_hdr.h" #include "stack/include/btm_status.h" #include "stack/include/l2c_api.h" #include "stack/rfcomm/port_int.h" #include "stack/rfcomm/rfc_event.h" #include "stack/rfcomm/rfc_state.h" #include "types/raw_address.h" /* * Define RFCOMM result codes */ #define RFCOMM_SUCCESS 0 #define RFCOMM_ERROR 1 #define RFCOMM_SECURITY_ERR 112 /* * Define max and min RFCOMM MTU (N1) */ #define RFCOMM_MIN_MTU 23 #define RFCOMM_MAX_MTU 32767 void RFCOMM_StartReq(tRFC_MCB* p_mcb); void RFCOMM_StartRsp(tRFC_MCB* p_mcb, uint16_t result); void RFCOMM_DlcEstablishReq(tRFC_MCB* p_mcb, uint8_t dlci, uint16_t mtu); void RFCOMM_DlcEstablishRsp(tRFC_MCB* p_mcb, uint8_t dlci, uint16_t mtu, uint16_t result); void RFCOMM_DataReq(tRFC_MCB* p_mcb, uint8_t dlci, BT_HDR* p_buf); void RFCOMM_DlcReleaseReq(tRFC_MCB* p_mcb, uint8_t dlci); void RFCOMM_ParameterNegotiationRequest(tRFC_MCB* p_mcb, uint8_t dlci, uint16_t mtu); void RFCOMM_ParameterNegotiationResponse(tRFC_MCB* p_mcb, uint8_t dlci, uint16_t mtu, uint8_t cl, uint8_t k); void RFCOMM_FlowReq(tRFC_MCB* p_mcb, uint8_t dlci, bool state); void RFCOMM_PortParameterNegotiationRequest(tRFC_MCB* p_mcb, uint8_t dlci, tPORT_STATE* p_pars); void RFCOMM_PortParameterNegotiationResponse(tRFC_MCB* p_mcb, uint8_t dlci, tPORT_STATE* p_pars, uint16_t param_mask); void RFCOMM_ControlReq(tRFC_MCB* p_mcb, uint8_t dlci, tPORT_CTRL* p_pars); void RFCOMM_ControlRsp(tRFC_MCB* p_mcb, uint8_t dlci, tPORT_CTRL* p_pars); void RFCOMM_LineStatusReq(tRFC_MCB* p_mcb, uint8_t dlci, uint8_t line_status); /* * Define logical struct used for sending and decoding MX frames */ typedef struct { uint8_t dlci; uint8_t type; uint8_t cr; uint8_t ea; uint8_t pf; uint8_t credit; union { struct { uint8_t dlci; uint8_t frame_type; uint8_t conv_layer; uint8_t priority; uint8_t t1; uint16_t mtu; uint8_t n2; uint8_t k; } pn; struct { uint8_t* p_data; uint16_t data_len; } test; struct { uint8_t dlci; uint8_t signals; uint8_t break_present; uint8_t break_duration; } msc; struct { uint8_t ea; uint8_t cr; uint8_t type; } nsc; struct { uint8_t dlci; uint8_t is_request; uint8_t baud_rate; uint8_t byte_size; uint8_t stop_bits; uint8_t parity; uint8_t parity_type; uint8_t fc_type; uint8_t xon_char; uint8_t xoff_char; uint16_t param_mask; } rpn; struct { uint8_t dlci; uint8_t line_status; } rls; } u; } MX_FRAME; #define LINE_STATUS_NO_ERROR 0x00 #define LINE_STATUS_OVERRUN 0x02 /* Receive Overrun Error */ #define LINE_STATUS_RXPARITY 0x04 /* Receive Parity Error */ #define LINE_STATUS_FRAME 0x08 /* Receive Framing error */ #define LINE_STATUS_FAILED 0x10 /* Connection Failed */ /* seconds to wait for reply with Poll bit */ #define RFC_T1_TIMEOUT 20 /* seconds to wait for reply with Poll bit other than MX */ #define RFC_PORT_T1_TIMEOUT 60 /* timeout to wait for Mx UIH */ #define RFC_T2_TIMEOUT 20 /* If something goes wrong and we send DISC we should not wait for min */ #define RFC_DISC_TIMEOUT 3 #define RFC_CLOSE_TIMEOUT 10 /* first connection to be established on Mx */ #define RFCOMM_CONN_TIMEOUT 120 /* Define RFComm control block */ typedef struct { MX_FRAME rx_frame; tL2CAP_APPL_INFO reg_info; /* L2CAP Registration info */ bool peer_rx_disabled; /* If true peer sent FCOFF */ uint8_t last_mux; /* Last mux allocated */ uint8_t last_port_index; // Index of last port allocated in rfc_cb.port } tRFCOMM_CB; /* Main Control Block for the RFCOMM Layer (PORT and RFC) */ typedef struct { tRFCOMM_CB rfc; tPORT_CB port; } tRFC_CB; extern tRFC_CB rfc_cb; /* MCB based on the L2CAP's lcid */ extern std::unordered_map rfc_lcid_mcb; /* Timer running on the multiplexor channel while no DLCI connection is open */ #define RFC_MCB_INIT_INACT_TIMER 60 /* in seconds */ /* Timer running on the multiplexor channel after last DLCI is released */ #define RFC_MCB_RELEASE_INACT_TIMER 20 /* in seconds */ #ifdef RFCOMM_PRECALC_FCS #define RFCOMM_SABME_FCS(p_data, cr, dlci) rfc_sabme_fcs[cr][dlci] #define RFCOMM_UA_FCS(p_data, cr, dlci) rfc_ua_fcs[cr][dlci] #define RFCOMM_DM_FCS(p_data, cr, dlci) rfc_dm_fcs[cr][dlci] #define RFCOMM_DISC_FCS(p_data, cr, dlci) rfc_disc_fcs[cr][dlci] #define RFCOMM_UIH_FCS(p_data, dlci) rfc_uih_fcs[dlci] #else uint8_t rfc_calc_fcs(uint16_t len, uint8_t* p); #define RFCOMM_SABME_FCS(p_data, cr, dlci) rfc_calc_fcs(3, p_data) #define RFCOMM_UA_FCS(p_data, cr, dlci) rfc_calc_fcs(3, p_data) #define RFCOMM_DM_FCS(p_data, cr, dlci) rfc_calc_fcs(3, p_data) #define RFCOMM_DISC_FCS(p_data, cr, dlci) rfc_calc_fcs(3, p_data) #define RFCOMM_UIH_FCS(p_data, dlci) rfc_calc_fcs(2, p_data) #endif void rfc_mx_sm_execute(tRFC_MCB* p_mcb, tRFC_MX_EVENT event, void* p_data); /* * Functions provided by the rfc_port_fsm.cc */ void rfc_port_sm_execute(tPORT* p_port, tRFC_PORT_EVENT event, void* p_data); void rfc_process_pn(tRFC_MCB* p_rfc_mcb, bool is_command, MX_FRAME* p_frame); void rfc_process_msc(tRFC_MCB* p_rfc_mcb, bool is_command, MX_FRAME* p_frame); void rfc_process_rpn(tRFC_MCB* p_rfc_mcb, bool is_command, bool is_request, MX_FRAME* p_frame); void rfc_process_rls(tRFC_MCB* p_rfc_mcb, bool is_command, MX_FRAME* p_frame); void rfc_process_nsc(tRFC_MCB* p_rfc_mcb, MX_FRAME* p_frame); void rfc_process_test_rsp(tRFC_MCB* p_rfc_mcb, BT_HDR* p_buf); void rfc_process_fcon(tRFC_MCB* p_rfc_mcb, bool is_command); void rfc_process_fcoff(tRFC_MCB* p_rfc_mcb, bool is_command); void rfc_process_l2cap_congestion(tRFC_MCB* p_mcb, bool is_congested); void rfc_on_l2cap_error(uint16_t lcid, uint16_t result); /* * Functions provided by the rfc_utils.cc */ tRFC_MCB* rfc_alloc_multiplexer_channel(const RawAddress& bd_addr, bool is_initiator); void rfc_release_multiplexer_channel(tRFC_MCB* p_rfc_mcb); void rfc_timer_start(tRFC_MCB* p_rfc_mcb, uint16_t timeout); void rfc_timer_stop(tRFC_MCB* p_rfc_mcb); void rfc_port_timer_start(tPORT* p_port, uint16_t tout); void rfc_port_timer_stop(tPORT* p_port); bool rfc_check_fcs(uint16_t len, uint8_t* p, uint8_t received_fcs); tRFC_MCB* rfc_find_lcid_mcb(uint16_t lcid); void rfc_save_lcid_mcb(tRFC_MCB* p_rfc_mcb, uint16_t lcid); void rfc_check_mcb_active(tRFC_MCB* p_mcb); void rfc_port_closed(tPORT* p_port); void rfc_sec_check_complete(RawAddress bd_addr, tBT_TRANSPORT transport, void* p_ref_data, tBTM_STATUS res); void rfc_inc_credit(tPORT* p_port, uint8_t credit); void rfc_dec_credit(tPORT* p_port); void rfc_check_send_cmd(tRFC_MCB* p_mcb, BT_HDR* p_buf); /* * Functions provided by the rfc_ts_frames.cc */ void rfc_send_sabme(tRFC_MCB* p_rfc_mcb, uint8_t dlci); void rfc_send_ua(tRFC_MCB* p_rfc_mcb, uint8_t dlci); void rfc_send_dm(tRFC_MCB* p_rfc_mcb, uint8_t dlci, bool pf); void rfc_send_disc(tRFC_MCB* p_rfc_mcb, uint8_t dlci); void rfc_send_pn(tRFC_MCB* p_mcb, uint8_t dlci, bool is_command, uint16_t mtu, uint8_t cl, uint8_t k); void rfc_send_test(tRFC_MCB* p_rfc_mcb, bool is_command, BT_HDR* p_buf); void rfc_send_msc(tRFC_MCB* p_mcb, uint8_t dlci, bool is_command, tPORT_CTRL* p_pars); void rfc_send_rls(tRFC_MCB* p_mcb, uint8_t dlci, bool is_command, uint8_t status); void rfc_send_rpn(tRFC_MCB* p_mcb, uint8_t dlci, bool is_command, tPORT_STATE* p_pars, uint16_t mask); void rfc_send_fcon(tRFC_MCB* p_mcb, bool is_command); void rfc_send_fcoff(tRFC_MCB* p_mcb, bool is_command); void rfc_send_buf_uih(tRFC_MCB* p_rfc_mcb, uint8_t dlci, BT_HDR* p_buf); void rfc_send_credit(tRFC_MCB* p_mcb, uint8_t dlci, uint8_t credit); void rfc_process_mx_message(tRFC_MCB* p_rfc_mcb, BT_HDR* p_buf); tRFC_EVENT rfc_parse_data(tRFC_MCB* p_rfc_mcb, MX_FRAME* p_frame, BT_HDR* p_buf); /* Call back functions from RFCOMM */ void rfcomm_l2cap_if_init(void); void PORT_StartInd(tRFC_MCB* p_mcb); void PORT_StartCnf(tRFC_MCB* p_mcb, uint16_t result); void PORT_CloseInd(tRFC_MCB* p_mcb); void PORT_TimeOutCloseMux(tRFC_MCB* p_mcb); void PORT_DlcEstablishInd(tRFC_MCB* p_mcb, uint8_t dlci, uint16_t mtu); void PORT_DlcEstablishCnf(tRFC_MCB* p_mcb, uint8_t dlci, uint16_t mtu, uint16_t result); void PORT_DataInd(tRFC_MCB* p_mcb, uint8_t dlci, BT_HDR* p_buf); void PORT_DlcReleaseInd(tRFC_MCB* p_mcb, uint8_t dlci); void PORT_ParNegInd(tRFC_MCB* p_mcb, uint8_t dlci, uint16_t mtu, uint8_t cl, uint8_t k); void PORT_ParNegCnf(tRFC_MCB* p_mcb, uint8_t dlci, uint16_t mtu, uint8_t cl, uint8_t k); void PORT_FlowInd(tRFC_MCB* p_mcb, uint8_t dlci, bool fc); void PORT_PortNegInd(tRFC_MCB* p_mcb, uint8_t dlci, tPORT_STATE* p_pars, uint16_t param_mask); void PORT_PortNegCnf(tRFC_MCB* p_mcb, uint8_t dlci, tPORT_STATE* p_pars, uint16_t result); void PORT_ControlInd(tRFC_MCB* p_mcb, uint8_t dlci, tPORT_CTRL* p_pars); void PORT_ControlCnf(tRFC_MCB* p_mcb, uint8_t dlci, tPORT_CTRL* p_pars); void PORT_LineStatusInd(tRFC_MCB* p_mcb, uint8_t dlci, uint8_t line_status); #endif