FreeCalypso > hg > freecalypso-sw
view gsm-fw/g23m-aci/uart/uart_kers.c @ 867:c4da570dca83
int_osx_receive_prim() in gsm-fw/gpf/osx/osx.c: there was an error in the
reconstruction of this function from disassembly in the logic that implements
special handling for MPHC_RXLEV_REQ messages.
The code is now fixed to properly match what the binary object version does;
with this fix the firmware now performs the power measurement phase correctly
and the initial network registration succeeds.
author | Space Falcon <falcon@ivan.Harhan.ORG> |
---|---|
date | Sat, 16 May 2015 06:34:09 +0000 |
parents | f54080301c98 |
children |
line wrap: on
line source
/* +----------------------------------------------------------------------------- | Project : | Modul : +----------------------------------------------------------------------------- | Copyright 2002 Texas Instruments Berlin, AG | All rights reserved. | | This file is confidential and a trade secret of Texas | Instruments Berlin, AG | The receipt of or possession of this file does not convey | any rights to reproduce or disclose its contents or to | manufacture, use, or sell anything it may describe, in | whole, or in part, without the specific written consent of | Texas Instruments Berlin, AG. +----------------------------------------------------------------------------- | Purpose : This modul is part of the entity UART and implements all | functions to handles the incoming process internal signals as | described in the SDL-documentation (KER-statemachine) +----------------------------------------------------------------------------- */ #ifndef UART_KERS_C #define UART_KERS_C #endif /* !UART_KERS_C */ #include "config.h" #include "fixedconf.h" #include "condat-features.h" #define ENTITY_UART /* * Turn off spurious LINT warnings */ /*lint -e415 access of out-of-bounds pointer */ /*==== INCLUDES =============================================================*/ #ifdef WIN32 #include "nucleus.h" #endif /* WIN32 */ #include "typedefs.h" /* to get Condat data types */ #include "vsi.h" /* to get a lot of macros */ #include "macdef.h" /* to get a lot of macros */ #include "custom.h" #include "gsm.h" /* to get a lot of macros */ #include "cnf_uart.h" /* to get cnf-definitions */ #include "mon_uart.h" /* to get mon-definitions */ #include "prim.h" /* to get the definitions of used SAP and directions */ #include "dti.h" /* to get dti lib */ #include "pei.h" /* to get PEI interface */ #ifdef FF_MULTI_PORT #include "gsi.h" /* to get definitions of serial driver */ #else /* FF_MULTI_PORT */ #ifdef _TARGET_ #include "../../serial/serialswitch.h" #include "../../serial/traceswitch.h" #else /* _TARGET_ */ #include "serial_dat.h" /* to get definitions of serial driver */ #endif /* _TARGET_ */ #endif /* FF_MULTI_PORT */ #include "uart.h" /* to get the global entity definitions */ #ifdef FF_MULTI_PORT #include "uart_ptxs.h" /* to get signal definitions for service TX */ #include "uart_prxs.h" /* to get rx signals */ #else /* FF_MULTI_PORT */ #include "uart_txs.h" /* to get signal definitions of service TX */ #include "uart_rxs.h" /* to get signal definitions of service RX */ #endif /* FF_MULTI_PORT */ #include "uart_dtxs.h" /* to get signal definitions of service DTX */ #include "uart_drxs.h" /* to get signal definitions of service DRX */ #include "uart_kerf.h" /* to get function definitions of service KER */ #include "uart_rts.h" /* to get signal definitions of service RT */ #ifndef _TARGET_ #include <stdio.h> /* to get sprintf */ #endif /* !_TARGET_ */ #include <string.h> /* JK, delete warnings: to get memcpy */ /*==== CONST ================================================================*/ /*==== LOCAL VARS ===========================================================*/ /*==== PRIVATE FUNCTIONS ====================================================*/ /*==== PUBLIC FUNCTIONS =====================================================*/ /* +------------------------------------------------------------------------------ | Function : sig_drx_ker_line_states_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_DRX_KER_LINE_STATES_IND | | Parameters : dlc_instance - dlc instance wich belongs to calling DRX | st_flow - flow control state (X bit) | st_line_sa - line state SA | st_line_sa - line state SB | st_break_len - break state | +------------------------------------------------------------------------------ */ GLOBAL void sig_drx_ker_line_states_ind(UBYTE dlc_instance, UBYTE st_flow, UBYTE st_line_sa, UBYTE st_line_sb, USHORT st_break_len) { T_DLC* dlc; ULONG old_lines; ULONG new_lines; TRACE_ISIG( "sig_drx_ker_line_states_ind" ); /* * set DLC */ dlc = &uart_data->dlc_table[dlc_instance]; switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_READY: /* * check for changed line states */ old_lines = dlc->lines & (UART_SA_TX_MASK | UART_SB_TX_MASK | UART_X_TX_MASK | UART_BRK_TX_MASK); new_lines = ((ULONG)st_line_sa << UART_SA_TX_POS) | ((ULONG)st_line_sb << UART_SB_TX_POS) | ((ULONG)st_flow << UART_X_TX_POS); if(st_break_len NEQ DTI_BREAK_OFF) { TRACE_EVENT("send Break"); new_lines|= UART_BRK_TX_MASK; } if(old_lines NEQ new_lines) { /* * trace changes */ if(new_lines & UART_X_TX_MASK) { if(!(old_lines & UART_X_TX_MASK)) { TRACE_EVENT("TX Flow Control: stop"); } } else if(old_lines & UART_X_TX_MASK) { TRACE_EVENT("TX Flow Control: start"); } if(new_lines & UART_SA_TX_MASK) { if(!(old_lines & UART_SA_TX_MASK)) { TRACE_EVENT("DSR: off"); } } else if(old_lines & UART_SA_TX_MASK) { TRACE_EVENT("DSR: on"); } if(new_lines & UART_SB_TX_MASK) { if(!(old_lines & UART_SB_TX_MASK)) { TRACE_EVENT("DCD: off"); } } else if(old_lines & UART_SB_TX_MASK) { TRACE_EVENT("DCD: on"); } /* * send new line states * but flush UART before */ dlc->lines&= ~(UART_SA_TX_MASK | UART_SB_TX_MASK | UART_X_TX_MASK | UART_BRK_TX_MASK | UART_BRKLEN_TX_MASK); if(st_break_len NEQ DTI_BREAK_OFF) new_lines|= ((ULONG)st_break_len << UART_BRKLEN_TX_POS); dlc->lines|= new_lines; dlc->received_prim|= UART_DTI_DATA_REQ_MASK; if(uart_data->ker.flush_state EQ UART_KER_NOT_FLUSHING) { uart_data->ker.flush_state = UART_KER_TX_FLUSH; sig_ker_tx_flush_req(); } } break; case KER_MUX: /* * check for changed line states */ old_lines = dlc->lines & (UART_CTS_MASK | UART_DSR_MASK | UART_DCD_MASK | UART_BRK_TX_MASK); new_lines = ((ULONG)st_flow << UART_CTS_POS) | ((ULONG)st_line_sa << UART_DSR_POS) | ((ULONG)st_line_sb << UART_DCD_POS); if(st_break_len NEQ DTI_BREAK_OFF) { TRACE_EVENT_P1("send Break - DLCI=%d", dlc->dlci); new_lines|= UART_BRK_TX_MASK; } if(old_lines NEQ new_lines) { /* * trace changes */ if(new_lines & UART_CTS_MASK) { if(!(old_lines & UART_CTS_MASK)) { TRACE_EVENT_P1("TX Flow Control: stop - DLCI=%d", dlc->dlci); } } else if(old_lines & UART_CTS_MASK) { TRACE_EVENT_P1("TX Flow Control: start - DLCI=%d", dlc->dlci); } if(new_lines & UART_DSR_MASK) { if(!(old_lines & UART_DSR_MASK)) { TRACE_EVENT_P1("DSR: off - DLCI=%d", dlc->dlci); } } else if(old_lines & UART_DSR_MASK) { TRACE_EVENT_P1("DSR: on - DLCI=%d", dlc->dlci); } if(new_lines & UART_DCD_MASK) { if(!(old_lines & UART_DCD_MASK)) { TRACE_EVENT_P1("DCD: off - DLCI=%d", dlc->dlci); } } else if(old_lines & UART_DCD_MASK) { TRACE_EVENT_P1("DCD: on - DLCI=%d", dlc->dlci); } /* * build and send MSC command */ dlc->lines&= ~(UART_CTS_MASK | UART_DSR_MASK | UART_DCD_MASK | UART_BRK_TX_MASK | UART_BRKLEN_TX_MASK); if(st_break_len NEQ DTI_BREAK_OFF) new_lines|= ((ULONG)st_break_len << UART_BRKLEN_TX_POS); dlc->lines|= new_lines; ker_mux_send_line_states(dlc_instance); } break; default: TRACE_ERROR( "SIG_DRX_KER_LINE_STATES_IND unexpected" ); break; } } /* sig_drx_ker_line_states_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_dtx_ker_enable_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_DTX_KER_ENABLE_IND | | Parameters : dlc_instance - dlc instance wich belongs to calling DTX | +------------------------------------------------------------------------------ */ GLOBAL void sig_dtx_ker_enable_ind (UBYTE dlc_instance) { TRACE_ISIG( "sig_dtx_ker_enable_ind" ); switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX: /* * build and send MSC command * enable flow control in line states */ uart_data->dlc_table[dlc_instance].lines&= ~UART_FC_TX_MASK; /* * send new line states */ ker_mux_send_line_states(dlc_instance); break; case KER_READY: break; default: TRACE_ERROR( "SIG_DTX_KER_ENABLE_IND unexpected" ); break; } } /* sig_dtx_ker_enable_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_dtx_ker_disable_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_DTX_KER_DISABLE_IND | | Parameters : dlc_instance - dlc instance wich belongs to calling DTX | +------------------------------------------------------------------------------ */ GLOBAL void sig_dtx_ker_disable_ind (UBYTE dlc_instance) { TRACE_ISIG( "sig_dtx_ker_disable_ind" ); switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX: /* * build and send MSC command * disable flow control in line states */ uart_data->dlc_table[dlc_instance].lines|= UART_FC_TX_MASK; /* * send new line states */ ker_mux_send_line_states(dlc_instance); break; case KER_READY: break; default: TRACE_ERROR( "SIG_DTX_KER_DISABLE_IND unexpected" ); break; } } /* sig_dtx_ker_disable_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_dtx_ker_escape_detected_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_DTX_KER_ESCAPE_DETECTED_IND | | Parameters : dlc_instance - dlc instance wich belongs to calling DTX | +------------------------------------------------------------------------------ */ GLOBAL void sig_dtx_ker_escape_detected_ind (U8 dlc_instance) { T_DLC *dlc; TRACE_FUNCTION( "sig_dtx_ker_escape_detected_ind" ); /* * set DLC */ dlc = &uart_data->dlc_table[dlc_instance]; { PALLOC (uart_detected_ind, UART_DETECTED_IND); uart_detected_ind->device = uart_data->device; uart_detected_ind->dlci = dlc->dlci; uart_detected_ind->cause = UART_DETECT_ESC; PSEND (hCommMMI, uart_detected_ind); } } /* sig_dtx_ker_escape_detected_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_any_ker_flushed_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_ANY_KER_FLUSHED_IND | | Parameters : dlc_instance - dlc instance wich belongs to this signal | +------------------------------------------------------------------------------ */ GLOBAL void sig_any_ker_flushed_ind (UBYTE dlc_instance) { T_DLC* dlc; UBYTE i; TRACE_ISIG( "sig_any_ker_flushed_ind" ); /* * reset flush indicator */ dlc = &uart_data->dlc_table[dlc_instance]; dlc->flushed = TRUE; /* * if the primitive which has triggered the flush belongs to the whole port * we will check each DLC for flush, if it only belongs to this DLC we start * TX flushing immediately */ if(uart_data->ker.received_prim) { /* * check each DLC */ for(i = 0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { dlc = &uart_data->dlc_table[i]; if(dlc->flushed NEQ TRUE) return; } } /* * start TX flushing */ uart_data->ker.flush_state = UART_KER_TX_FLUSH; sig_ker_tx_flush_req(); } /* sig_any_ker_flushed_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_tx_ker_flushed_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_TX_KER_FLUSHED_IND | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void sig_tx_ker_flushed_ind () { T_DLC* dlc; UBYTE i; #ifndef _SIMULATION_ USHORT error_code; #endif TRACE_ISIG( "sig_tx_ker_flushed_ind" ); if(uart_data->ker.flush_state EQ UART_KER_TX_FLUSH) { /* * primitives of the port */ /* * UART_PARAMETERS_REQ */ if(uart_data->ker.received_prim & UART_PARAMETERS_REQ_MASK) { /* * disable UART while set new communication parameters */ #ifdef _SIMULATION_ { /* * send DTI_GETDATA_REQ */ PALLOC (dti_getdata_req, DTI2_GETDATA_REQ); dti_getdata_req->link_id = LINK_DISABLE_PORT_1; /* for disable */ PSEND (hCommMMI, dti_getdata_req); } #else /* _SIMULATION_ */ #ifndef FF_MULTI_PORT if((error_code = UF_Enable (uart_data->device, FALSE)) NEQ UF_OK) { TRACE_ERROR_P2("UF Driver: Can't disable UART, [%d], uart_kerp.c(%d)", error_code,__LINE__); } #endif /* !FF_MULTI_PORT */ #endif /* _SIMULATION */ /* * set new parameters */ ker_setupUart(); #ifdef _SIMULATION_ { /* * send DTI_GETDATA_REQ */ PALLOC (dti_getdata_req, DTI2_GETDATA_REQ); dti_getdata_req->link_id = LINK_ENABLE_PORT_1; /* for enable */ PSEND (hCommMMI, dti_getdata_req); } #else /* _SIMULATION_ */ #ifndef FF_MULTI_PORT if((error_code = UF_Enable (uart_data->device, TRUE)) NEQ UF_OK) { TRACE_ERROR_P2("UF Driver: Can't enable UART, [%d], uart_kerp.c(%d)", error_code,__LINE__); } #endif /* !FF_MULTI_PORT */ #endif /* _SIMULATION */ /* * restart suspended read and write procedures */ sig_ker_tx_restart_write_req(); sig_ker_rx_restart_read_req(); /* * send confirm primitive */ { PALLOC (uart_parameters_cnf, UART_PARAMETERS_CNF); uart_parameters_cnf->device = uart_data->device; PSEND (hCommMMI, uart_parameters_cnf); } } /* * UART_DISABLE_REQ */ if(uart_data->ker.received_prim & UART_DISABLE_REQ_MASK) { switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX: case KER_MUX_ESTABLISH: case KER_MUX_DLC_CLOSING: case KER_MUX_CLOSING: case KER_MUX_CLOSED: /* * stop timers and * remove all DLC instances */ ker_mux_close_down(); break; case KER_READY: /* * close dlc channel */ ker_mux_dlc_release(UART_CONTROL_INSTANCE); break; case KER_DEAD: break; default: TRACE_ERROR( "SIG_TX_KER_FLUSHED_IND unexpected" ); break; } SET_STATE( UART_SERVICE_KER, KER_DEAD ); /* * disable UART */ #ifdef _SIMULATION_ { /* * send DTI_GETDATA_REQ */ PALLOC (dti_getdata_req, DTI2_GETDATA_REQ); dti_getdata_req->link_id = LINK_DISABLE_PORT_1; /* for disable */ PSEND (hCommMMI, dti_getdata_req); } #else /* _SIMULATION_ */ #ifndef FF_MULTI_PORT if((error_code = UF_Enable (uart_data->device, FALSE)) NEQ UF_OK) { TRACE_ERROR_P2("UF Driver: Can't disable UART, [%d], uart_kerp.c(%d)", error_code,__LINE__); } #endif /* !FF_MULTI_PORT */ #endif /* _SIMULATION */ sig_ker_rx_dead_mode_req(); sig_ker_tx_dead_mode_req(); /* * send confirm primitive */ { PALLOC (uart_disable_cnf, UART_DISABLE_CNF); uart_disable_cnf->device = uart_data->device; PSEND (hCommMMI, uart_disable_cnf); } } /* * UART_MUX_START_REQ */ if(uart_data->ker.received_prim & UART_MUX_START_REQ_MASK) { switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_READY: /* * close dlc channel */ ker_mux_dlc_release(UART_CONTROL_INSTANCE); break; default: TRACE_ERROR( "SIG_TX_KER_FLUSHED_IND unexpected" ); break; } SET_STATE( UART_SERVICE_KER, KER_MUX_ESTABLISH ); /* * set RX and TX service in mux mode */ sig_ker_rx_mux_mode_req(); sig_ker_tx_mux_mode_req(); /* * start reception */ MALLOC(uart_data->ker.rx_data_desc, (USHORT)(sizeof(T_desc2) - 1 + uart_data->n1 + 2)); uart_data->ker.rx_data_desc->next = (ULONG)NULL; uart_data->ker.rx_data_desc->len = 0; sig_ker_rx_ready_to_receive_req(uart_data->ker.rx_data_desc, 0, (USHORT)(uart_data->n1 + 2)); /* * start timer */ sig_ker_rt_start_t3_req(); /* * send confirm primitive */ { PALLOC (uart_mux_start_cnf, UART_MUX_START_CNF); uart_mux_start_cnf->device = uart_data->device; PSEND (hCommMMI, uart_mux_start_cnf); } } /* * UART_MUX_CLOSE_REQ */ if(uart_data->ker.received_prim & UART_MUX_CLOSE_REQ_MASK) { switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX_CLOSED: if(uart_data->ker.receiving_state NEQ UART_KER_RECEIVING) { PALLOC(uart_mux_close_ind, UART_MUX_CLOSE_IND); SET_STATE( UART_SERVICE_KER, KER_READY ); /* * stop receiving */ sig_ker_rx_not_ready_to_receive_req(); MFREE_DESC2(uart_data->ker.rx_data_desc); uart_data->ker.rx_data_desc = NULL; /* * set dlc values */ dlc = &uart_data->dlc_table[UART_CONTROL_INSTANCE]; dlc->drx = &uart_data->drx_base[0]; dlc->dtx = &uart_data->dtx_base[0]; dlc->dlci = 0; dlc->priority = 0; /* * set RX and TX in ready mode */ sig_ker_rx_ready_mode_req(); sig_ker_tx_ready_mode_req(); /* * set frame size for ready mode */ uart_data->n1 = UART_N1_READY_MODE; /* * set DRX and DTX in ready mode */ uart_data->dtx = dlc->dtx; uart_data->drx = dlc->drx; sig_ker_drx_ready_mode_req(UART_CONTROL_INSTANCE); sig_ker_dtx_ready_mode_req(UART_CONTROL_INSTANCE); /* * inform ACI about entering ready mode */ uart_mux_close_ind->device = uart_data->device; PSEND(hCommMMI, uart_mux_close_ind); } break; default: TRACE_ERROR( "SIG_TX_KER_FLUSHED_IND unexpected" ); break; } } /* * no more UART port related primitives * so clear all flags */ uart_data->ker.received_prim = 0; /* * primitives of the DLC */ for(i = 0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { dlc = &uart_data->dlc_table[i]; if(dlc->received_prim) { /* * UART_RING_REQ * UART_DCD_REQ * DTI_DATA_REQ (line states) */ if((dlc->received_prim & UART_RING_REQ_MASK) || (dlc->received_prim & UART_DCD_REQ_MASK) || (dlc->received_prim & UART_DTI_DATA_REQ_MASK)) { /* * send new line states */ switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_READY: sig_ker_tx_line_states_req(UART_CONTROL_INSTANCE); break; case KER_MUX: /* * send MSC frame to peer */ ker_mux_send_line_states (uart_data->dlc_instance[dlc->dlci]); break; default: if(dlc->received_prim & UART_RING_REQ_MASK) { TRACE_ERROR( "UART_RING_REQ unexpected" ); } if(dlc->received_prim & UART_DCD_REQ_MASK) { TRACE_ERROR( "UART_DCD_REQ unexpected" ); } break; } /* * send confirm primitives */ if(dlc->received_prim & UART_RING_REQ_MASK) { PALLOC (uart_ring_cnf, UART_RING_CNF); uart_ring_cnf->device = uart_data->device; uart_ring_cnf->dlci = dlc->dlci; PSEND (hCommMMI, uart_ring_cnf); } if(dlc->received_prim & UART_DCD_REQ_MASK) { PALLOC (uart_dcd_cnf, UART_DCD_CNF); uart_dcd_cnf->device = uart_data->device; uart_dcd_cnf->dlci = dlc->dlci; PSEND (hCommMMI, uart_dcd_cnf); } } /* * no more DLC related primitives * so clear all flags */ dlc->received_prim = 0; } } uart_data->ker.flush_state = UART_KER_NOT_FLUSHING; } } /* sig_tx_ker_flushed_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_tx_ker_sending_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_TX_KER_SENDING_IND | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void sig_tx_ker_sending_ind () { TRACE_ISIG( "sig_tx_ker_sending_ind" ); switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX_ESTABLISH: case KER_MUX: case KER_MUX_DLC_CLOSING: case KER_MUX_CLOSING: case KER_MUX_CLOSED: uart_data->ker.sending_state = UART_KER_SENDING; break; default: TRACE_ERROR( "SIG_TX_KER_SENDING_IND unexpected" ); break; } } /* sig_tx_ker_sending_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_tx_ker_data_sent_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_TX_KER_DATA_SENT_IND | | Parameters : rest_data - not yet sent data | write_pos - position where the not yet sent data starts | +------------------------------------------------------------------------------ */ GLOBAL void sig_tx_ker_data_sent_ind (T_desc2* rest_data, USHORT read_pos) { TRACE_ISIG( "sig_tx_ker_data_sent_ind" ); /* * free sent data descriptor */ MFREE_DESC2(uart_data->ker.tx_data_desc); uart_data->ker.tx_data_desc = NULL; uart_data->ker.sending_state = UART_KER_NOT_SENDING; if(uart_data->ker.tx_data_waiting) { /* * send next descriptor in waiting queue */ uart_data->ker.tx_data_desc = uart_data->ker.tx_data_waiting; uart_data->ker.tx_data_waiting = (T_desc2*)uart_data->ker.tx_data_waiting->next; /* * only one descriptor is sent at a time */ uart_data->ker.tx_data_desc->next = (ULONG)NULL; sig_ker_tx_data_available_req( uart_data->ker.tx_data_desc, 0); } else { switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX_ESTABLISH: case KER_MUX: case KER_MUX_DLC_CLOSING: case KER_MUX_CLOSING: break; case KER_MUX_CLOSED: /* * flush UART before enter ready mode */ uart_data->ker.received_prim|= UART_MUX_CLOSE_REQ_MASK; if(uart_data->ker.flush_state EQ UART_KER_NOT_FLUSHING) { uart_data->ker.flush_state = UART_KER_TX_FLUSH; sig_ker_tx_flush_req(); } break; default: TRACE_ERROR( "SIG_TX_KER_DATA_SENT_IND unexpected" ); break; } } } /* sig_tx_ker_data_sent_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_rx_ker_receiving_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_RX_KER_RECEIVING_IND | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void sig_rx_ker_receiving_ind () { TRACE_ISIG( "sig_rx_ker_receiving_ind" ); switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX_ESTABLISH: case KER_MUX: case KER_MUX_DLC_CLOSING: case KER_MUX_CLOSING: case KER_MUX_CLOSED: uart_data->ker.receiving_state = UART_KER_RECEIVING; break; default: TRACE_ERROR( "SIG_RX_KER_RECEIVING_IND unexpected" ); break; } } /* sig_rx_ker_receiving_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_rx_ker_data_received_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_RX_KER_DATA_RECEIVED_IND | which is used to process a received frame. | | Precondition is that the frame has a length >2 without flags. | | Parameters : received_data - received data | write_pos - write position for the next reception | +------------------------------------------------------------------------------ */ GLOBAL void sig_rx_ker_data_received_ind (T_desc2* received_data, USHORT write_pos) { UBYTE i; UBYTE dlci; T_DLC* dlc; ULONG forward; BOOL continuous; TRACE_ISIG( "sig_rx_ker_data_received_ind" ); #ifndef _TARGET_ if(received_data->len) { USHORT pos; char buf[90]; /* * trace output */ TRACE_EVENT("======= IN"); i = 0; pos = 0; while(pos < received_data->len) { i+= sprintf(&buf[i], "0x%02x, ", received_data->buffer[pos]); pos++; if(i > 80) { TRACE_EVENT( buf ); i = 0; } else if(pos >= received_data->len) { TRACE_EVENT( buf ); } } } #endif /* !_TARGET_ */ uart_data->ker.receiving_state = UART_KER_NOT_RECEIVING; switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX_ESTABLISH: if(received_data->len EQ 0) { /* * prepare next reception */ sig_ker_rx_ready_to_receive_req(received_data, write_pos, (USHORT)(uart_data->n1 + 2)); break; } dlci = received_data->buffer[UART_OFFSET_ADDRESS] >> UART_DLCI_POS; if((dlci EQ UART_DLCI_CONTROL) && (received_data->buffer[UART_OFFSET_CONTROL] EQ UART_SABM_FRAME)) { /* * analyze SABM frame */ forward = 0; ker_receive_sabm_frame(&forward, received_data); /* * set dlc value */ dlc = &uart_data->dlc_table[UART_CONTROL_INSTANCE]; if((forward & UART_FORWARD_SABM) && (dlc->connection_state EQ UART_CONNECTION_SABM_RCVD) && (uart_data->dlc_instance[dlci] NEQ UART_CONTROL_INSTANCE)) { SET_STATE( UART_SERVICE_KER, KER_MUX ); /* * stop timer */ sig_ker_rt_stop_t3_req(); /* * setup dlc parameter */ uart_data->dlc_instance[dlci] = UART_CONTROL_INSTANCE; dlc->connection_state = UART_CONNECTION_OPEN; /* * set priority */ dlc->priority = 0; /* * send response frame */ if(forward & UART_FORWARD_RESPONSE) { ker_mux_send_frame(received_data); /* * prepare next reception */ MALLOC(received_data, (USHORT)(sizeof(T_desc2) - 1 + uart_data->n1 + 2)); received_data->next = (ULONG)NULL; } } } /* * prepare next reception */ received_data->len = 0; uart_data->ker.rx_data_desc = received_data; sig_ker_rx_ready_to_receive_req(received_data, 0, (USHORT)(uart_data->n1 + 2)); break; case KER_MUX: if(received_data->len EQ 0) { /* * prepare next reception */ sig_ker_rx_ready_to_receive_req(received_data, write_pos, (USHORT)(uart_data->n1 + 2)); break; } /* * analyze frame and messages */ forward = 0; switch(received_data->buffer[UART_OFFSET_CONTROL]) { case UART_SABM_FRAME: ker_receive_sabm_frame(&forward, received_data); break; case UART_UA_FRAME: ker_receive_ua_frame(&forward, received_data); break; case UART_DM_CONTROL_FRAME: case UART_DM_DATA_FRAME: ker_receive_dm_frame(&forward, received_data); break; case UART_DISC_FRAME: ker_receive_disc_frame(&forward, received_data); break; case UART_UIH_CONTROL_FRAME: ker_receive_uih_control_frame(&forward, received_data); break; case UART_UIH_DATA_FRAME: ker_receive_uih_data_frame(&forward, received_data); break; default: { TRACE_EVENT_P2("Warning: Unexpected HDLC value: %d, uart_kers.c(%d)", received_data->buffer[UART_OFFSET_CONTROL], __LINE__); break; } } /* * remove resonded frames and send next frames in command queue */ for(i=0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { dlc = &uart_data->dlc_table[i]; switch(dlc->connection_state) { case UART_CONNECTION_OPEN: case UART_CONNECTION_DISC_SENT: if((dlc->last_command NEQ NULL) && (dlc->last_command->buffer[UART_OFFSET_CONTROL] EQ UART_UIH_CONTROL_FRAME) && (dlc->last_command->len EQ UART_OFFSET_INFO)) { /* * remove responded UIH frame */ MFREE_DESC2(dlc->last_command); dlc->last_command = NULL; uart_data->ker.nr_t2--; if( uart_data->ker.nr_t2 EQ 0 ) sig_ker_rt_stop_t2_req(); } if((dlc->last_command EQ NULL) && (dlc->next_command NEQ NULL)) { T_desc2* temp_desc; /* * transmit next command frame */ dlc->last_command = dlc->next_command; dlc->next_command = (T_desc2*)dlc->next_command->next; dlc->last_command->next = (ULONG)NULL; MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + dlc->last_command->len)); temp_desc->next = (ULONG)NULL; temp_desc->len = dlc->last_command->len; memcpy(temp_desc->buffer, dlc->last_command->buffer, dlc->last_command->len); dlc->retransmissions = 0; ker_mux_send_frame(temp_desc); if(dlc->last_command->buffer[UART_OFFSET_CONTROL] EQ UART_UIH_CONTROL_FRAME) { uart_data->ker.nr_t2++; sig_ker_rt_start_t2_req(); } else { uart_data->ker.nr_t1++; sig_ker_rt_start_t1_req(); } } break; case UART_CONNECTION_DEAD: break; default: { TRACE_EVENT_P2("Unexpected DLC connection state: %d, uart_kers.c(%d)", dlc->connection_state, __LINE__); break; } } } /* * process results of analysis */ if(forward) { for(i=0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { if(i NEQ UART_CONTROL_INSTANCE) { /* * set dlc values */ dlc = &uart_data->dlc_table[i]; dlci = dlc->dlci; /* * channel to open */ if((forward & UART_FORWARD_SABM) && (dlc->connection_state EQ UART_CONNECTION_SABM_RCVD) && (uart_data->dlc_instance[dlci] NEQ i)) { PALLOC(uart_mux_dlc_establish_ind, UART_MUX_DLC_ESTABLISH_IND); /* * setup dlc parameter */ uart_data->dlc_instance[dlci] = i; dlc->drx = &uart_data->drx_base[i]; dlc->dtx = &uart_data->dtx_base[i]; /* * set priority */ if(dlci < 8) dlc->priority = 7; else if(dlci < 16) dlc->priority = 15; else if(dlci < 24) dlc->priority = 23; else if(dlci < 32) dlc->priority = 31; else if(dlci < 40) dlc->priority = 39; else if(dlci < 48) dlc->priority = 47; else if(dlci < 56) dlc->priority = 55; else dlc->priority = 61; /* * store response frame and * clear appropriate bit in forward mask */ dlc->next_command = received_data; forward &= ~UART_FORWARD_RESPONSE; /* * create new reception frame */ MALLOC(received_data, (USHORT)(sizeof(T_desc2) - 1 + uart_data->n1 + 2)); received_data->next = (ULONG)NULL; /* * inform ACI about new DLC */ uart_mux_dlc_establish_ind->device = uart_data->device; uart_mux_dlc_establish_ind->dlci = dlci; uart_mux_dlc_establish_ind-> convergence = UART_MUX_CONVERGENCE_UOS; uart_mux_dlc_establish_ind->n1 = uart_data->n1; uart_mux_dlc_establish_ind-> service = UART_MUX_SERVICE_AT; PSEND (hCommMMI, uart_mux_dlc_establish_ind); } /* * channel to close */ if((forward & UART_FORWARD_DLC_RELEASE) && (dlc->connection_state EQ UART_CONNECTION_DEAD) && (dlci NEQ UART_DLCI_INVALID)) { PALLOC(uart_mux_dlc_release_ind, UART_MUX_DLC_RELEASE_IND); /* * release channel */ ker_mux_dlc_release(i); /* * inform ACI about DLC release */ uart_mux_dlc_release_ind->device = uart_data->device; uart_mux_dlc_release_ind->dlci = dlci; PSEND(hCommMMI, uart_mux_dlc_release_ind); } /* * set Flow Control ON */ if((forward & UART_FORWARD_FCON) && (dlc->connection_state EQ UART_CONNECTION_OPEN) && (!(dlc->lines & UART_FC_RX_MASK))) { uart_data->drx = dlc->drx; sig_ker_drx_enable_req(); } /* * set Flow Control OFF */ if((forward & UART_FORWARD_FCOFF) && (dlc->connection_state EQ UART_CONNECTION_OPEN) && (!(dlc->lines & UART_FC_RX_MASK))) { uart_data->drx = dlc->drx; sig_ker_drx_disable_req(); } /* * send status lines */ if((forward & UART_FORWARD_MSC) && (dlc->connection_state EQ UART_CONNECTION_OPEN)) { UBYTE st_flow; UBYTE st_line_sa; UBYTE st_break_len; /* * send primitive if DTR drop is detected */ if(dlc->lines & UART_DTR_MASK) { PALLOC (uart_detected_ind, UART_DETECTED_IND); uart_detected_ind->device = uart_data->device; uart_detected_ind->dlci = dlc->dlci; uart_detected_ind->cause = UART_DETECT_DTR; PSEND (hCommMMI, uart_detected_ind); } /* * set line states */ if(dlc->lines & UART_RTS_MASK) st_flow = DTI_FLOW_OFF; else st_flow = DTI_FLOW_ON; if(dlc->lines & UART_DTR_MASK) st_line_sa = DTI_SA_OFF; else st_line_sa = DTI_SA_ON; /* * set break */ if(dlc->lines & UART_BRK_RX_MASK) st_break_len = (UBYTE)((dlc->lines & UART_BRKLEN_RX_MASK) >> UART_BRKLEN_RX_POS); else st_break_len = DTI_BREAK_OFF; /* * send flow control signals */ if(uart_data->ker.data_flow_tx EQ UART_FLOW_ENABLED) { uart_data->drx = dlc->drx; if(dlc->lines & UART_FC_RX_MASK) sig_ker_drx_disable_req(); else sig_ker_drx_enable_req(); } /* * send line states */ uart_data->dtx = dlc->dtx; sig_ker_dtx_line_states_req(st_flow, st_line_sa, DTI_SB_ON, st_break_len); } } } /* * send response frame */ if(forward & UART_FORWARD_RESPONSE) { ker_mux_send_frame(received_data); uart_data->ker.rx_data_desc = NULL; } /* * Close-Down multiplexer */ if(forward & UART_FORWARD_CLD) { SET_STATE( UART_SERVICE_KER, KER_MUX_CLOSED ); /* * stop timers and * remove all DLC instances */ ker_mux_close_down(); /* * flush UART before change the state */ if(uart_data->ker.tx_data_desc EQ NULL) { uart_data->ker.received_prim|= UART_MUX_CLOSE_REQ_MASK; if(uart_data->ker.flush_state EQ UART_KER_NOT_FLUSHING) { uart_data->ker.flush_state = UART_KER_TX_FLUSH; sig_ker_tx_flush_req(); } } } } /* * prepare next reception */ if(forward & UART_FORWARD_RESPONSE) { MALLOC(received_data, (USHORT)(sizeof(T_desc2) - 1 + uart_data->n1 + 2)); received_data->next = (ULONG)NULL; } received_data->len = 0; uart_data->ker.rx_data_desc = received_data; sig_ker_rx_ready_to_receive_req(received_data, 0, (USHORT)(uart_data->n1 + 2)); break; case KER_MUX_DLC_CLOSING: if(received_data->len EQ 0) { /* * prepare next reception */ sig_ker_rx_ready_to_receive_req(received_data, write_pos, (USHORT)(uart_data->n1 + 2)); break; } /* * analyze frame and messages */ forward = 0; switch(received_data->buffer[UART_OFFSET_CONTROL]) { case UART_SABM_FRAME: ker_receive_sabm_frame(&forward, received_data); break; case UART_UA_FRAME: ker_receive_ua_frame(&forward, received_data); break; case UART_DM_CONTROL_FRAME: case UART_DM_DATA_FRAME: ker_receive_dm_frame(&forward, received_data); break; case UART_DISC_FRAME: ker_receive_disc_frame(&forward, received_data); break; case UART_UIH_CONTROL_FRAME: ker_receive_uih_control_frame(&forward, received_data); break; case UART_UIH_DATA_FRAME: ker_receive_uih_data_frame(&forward, received_data); break; default: { TRACE_EVENT_P2("Warning: Unexpected HDLC value: %d, uart_kers.c(%d)", received_data->buffer[UART_OFFSET_CONTROL], __LINE__); break; } } /* * remove resonded frames and send next frames in command queue */ for(i=0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { dlc = &uart_data->dlc_table[i]; switch(dlc->connection_state) { case UART_CONNECTION_OPEN: case UART_CONNECTION_DISC_SENT: if((dlc->last_command NEQ NULL) && (dlc->last_command->buffer[UART_OFFSET_CONTROL] EQ UART_UIH_CONTROL_FRAME) && (dlc->last_command->len EQ UART_OFFSET_INFO)) { /* * remove responded UIH frame */ MFREE_DESC2(dlc->last_command); dlc->last_command = NULL; uart_data->ker.nr_t2--; if( uart_data->ker.nr_t2 EQ 0 ) sig_ker_rt_stop_t2_req(); } if((dlc->last_command EQ NULL) && (dlc->next_command NEQ NULL)) { T_desc2* temp_desc; /* * transmit next command frame */ dlc->last_command = dlc->next_command; dlc->next_command = (T_desc2*)dlc->next_command->next; dlc->last_command->next = (ULONG)NULL; MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + dlc->last_command->len)); temp_desc->next = (ULONG)NULL; temp_desc->len = dlc->last_command->len; memcpy(temp_desc->buffer, dlc->last_command->buffer, dlc->last_command->len); dlc->retransmissions = 0; ker_mux_send_frame(temp_desc); if(dlc->last_command->buffer[UART_OFFSET_CONTROL] EQ UART_UIH_CONTROL_FRAME) { uart_data->ker.nr_t2++; sig_ker_rt_start_t2_req(); } else { uart_data->ker.nr_t1++; sig_ker_rt_start_t1_req(); } } break; case UART_CONNECTION_DEAD: break; default: { TRACE_EVENT_P2("Unexpected DLC connection state: %d, uart_kers.c(%d)", dlc->connection_state, __LINE__); break; } } } /* * process results of analysis */ if(forward) { continuous = FALSE; for(i=0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { if(i NEQ UART_CONTROL_INSTANCE) { /* * set dlc values */ dlc = &uart_data->dlc_table[i]; dlci = dlc->dlci; /* * channel to open */ if((forward & UART_FORWARD_SABM) && (dlc->connection_state EQ UART_CONNECTION_SABM_RCVD)) { /* * reject all attempts to open a channel */ received_data->buffer[UART_OFFSET_CONTROL] = UART_DM_CONTROL_FRAME; /* * release channel */ ker_mux_dlc_release(i); } /* * channel to close */ if((forward & UART_FORWARD_DLC_RELEASE) && (dlc->connection_state EQ UART_CONNECTION_DEAD) && (dlci NEQ UART_DLCI_INVALID)) { /* * release channel */ ker_mux_dlc_release(i); } if(dlc->connection_state NEQ UART_CONNECTION_DEAD) continuous = TRUE; } } /* * send response frame */ if(forward & UART_FORWARD_RESPONSE) { ker_mux_send_frame(received_data); uart_data->ker.rx_data_desc = NULL; } /* * Close-Down multiplexer */ if(forward & UART_FORWARD_CLD) { SET_STATE( UART_SERVICE_KER, KER_MUX_CLOSED ); /* * stop timers and * remove all DLC instances */ ker_mux_close_down(); /* * flush UART before change the state */ if(uart_data->ker.tx_data_desc EQ NULL) { uart_data->ker.received_prim|= UART_MUX_CLOSE_REQ_MASK; if(uart_data->ker.flush_state EQ UART_KER_NOT_FLUSHING) { uart_data->ker.flush_state = UART_KER_TX_FLUSH; sig_ker_tx_flush_req(); } } } /* * change state if all channels are closed */ else if(continuous EQ FALSE) { SET_STATE( UART_SERVICE_KER, KER_MUX_CLOSING ); /* * build and send CLD command frame: */ ker_mux_send_close_down(); /* * start timer */ sig_ker_rt_start_t3_req(); } } /* * prepare next reception */ if(forward & UART_FORWARD_RESPONSE) { MALLOC(received_data, (USHORT)(sizeof(T_desc2) - 1 + uart_data->n1 + 2)); received_data->next = (ULONG)NULL; } received_data->len = 0; uart_data->ker.rx_data_desc = received_data; sig_ker_rx_ready_to_receive_req(received_data, 0, (USHORT)(uart_data->n1 + 2)); break; case KER_MUX_CLOSING: if(received_data->len EQ 0) { /* * prepare next reception */ sig_ker_rx_ready_to_receive_req(received_data, write_pos, (USHORT)(uart_data->n1 + 2)); break; } /* * analyze frame and messages */ forward = 0; switch(received_data->buffer[UART_OFFSET_CONTROL]) { case UART_SABM_FRAME: ker_receive_sabm_frame(&forward, received_data); break; case UART_UA_FRAME: ker_receive_ua_frame(&forward, received_data); break; case UART_DM_CONTROL_FRAME: case UART_DM_DATA_FRAME: ker_receive_dm_frame(&forward, received_data); break; case UART_DISC_FRAME: ker_receive_disc_frame(&forward, received_data); break; case UART_UIH_CONTROL_FRAME: ker_receive_uih_control_frame(&forward, received_data); break; case UART_UIH_DATA_FRAME: ker_receive_uih_data_frame(&forward, received_data); break; default: { TRACE_EVENT_P2("Warning: Unexpected HDLC value: %d, uart_kers.c(%d)", received_data->buffer[UART_OFFSET_CONTROL], __LINE__); break; } } /* * remove resonded frames and send next frames in command queue */ for(i=0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { dlc = &uart_data->dlc_table[i]; switch(dlc->connection_state) { case UART_CONNECTION_OPEN: case UART_CONNECTION_DISC_SENT: if((dlc->last_command NEQ NULL) && (dlc->last_command->buffer[UART_OFFSET_CONTROL] EQ UART_UIH_CONTROL_FRAME) && (dlc->last_command->len EQ UART_OFFSET_INFO)) { /* * remove responded UIH frame */ MFREE_DESC2(dlc->last_command); dlc->last_command = NULL; uart_data->ker.nr_t2--; if( uart_data->ker.nr_t2 EQ 0 ) sig_ker_rt_stop_t2_req(); } if((dlc->last_command EQ NULL) && (dlc->next_command NEQ NULL)) { T_desc2* temp_desc; /* * transmit next command frame */ dlc->last_command = dlc->next_command; dlc->next_command = (T_desc2*)dlc->next_command->next; dlc->last_command->next = (ULONG)NULL; MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + dlc->last_command->len)); temp_desc->next = (ULONG)NULL; temp_desc->len = dlc->last_command->len; memcpy(temp_desc->buffer, dlc->last_command->buffer, dlc->last_command->len); dlc->retransmissions = 0; ker_mux_send_frame(temp_desc); if(dlc->last_command->buffer[UART_OFFSET_CONTROL] EQ UART_UIH_CONTROL_FRAME) { uart_data->ker.nr_t2++; sig_ker_rt_start_t2_req(); } else { uart_data->ker.nr_t1++; sig_ker_rt_start_t1_req(); } } break; case UART_CONNECTION_DEAD: break; default: { TRACE_EVENT_P2("Unexpected DLC connection state: %d, uart_kers.c(%d)", dlc->connection_state,__LINE__); break; } } } /* * process results of analysis */ if(forward) { for(i=0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { if(i NEQ UART_CONTROL_INSTANCE) { /* * set dlc values */ dlc = &uart_data->dlc_table[i]; dlci = dlc->dlci; /* * channel to open */ if((forward & UART_FORWARD_SABM) && (dlc->connection_state EQ UART_CONNECTION_SABM_RCVD)) { /* * reject all attempts to open a channel */ received_data->buffer[UART_OFFSET_CONTROL] = UART_DM_CONTROL_FRAME; /* * release channel */ ker_mux_dlc_release(i); } /* * channel to close */ if((forward & UART_FORWARD_DLC_RELEASE) && (dlc->connection_state EQ UART_CONNECTION_DEAD) && (dlci NEQ UART_DLCI_INVALID)) { /* * release channel */ ker_mux_dlc_release(i); } } } /* * send response frame */ if(forward & UART_FORWARD_RESPONSE) { ker_mux_send_frame(received_data); uart_data->ker.rx_data_desc = NULL; } /* * Close-Down multiplexer */ if(forward & UART_FORWARD_CLD) { SET_STATE( UART_SERVICE_KER, KER_MUX_CLOSED ); /* * stop timers and * remove all DLC instances */ ker_mux_close_down(); /* * flush UART before change the state */ if(uart_data->ker.tx_data_desc EQ NULL) { uart_data->ker.received_prim|= UART_MUX_CLOSE_REQ_MASK; if(uart_data->ker.flush_state EQ UART_KER_NOT_FLUSHING) { uart_data->ker.flush_state = UART_KER_TX_FLUSH; sig_ker_tx_flush_req(); } } } } /* * prepare next reception */ if(forward & UART_FORWARD_RESPONSE) { MALLOC(received_data, (USHORT)(sizeof(T_desc2) - 1 + uart_data->n1 + 2)); received_data->next = (ULONG)NULL; } received_data->len = 0; uart_data->ker.rx_data_desc = received_data; sig_ker_rx_ready_to_receive_req(received_data, 0, (USHORT)(uart_data->n1 + 2)); break; case KER_MUX_CLOSED: if((uart_data->ker.tx_data_desc EQ NULL) && (uart_data->ker.flush_state EQ UART_KER_NOT_FLUSHING)) { PALLOC(uart_mux_close_ind, UART_MUX_CLOSE_IND); SET_STATE( UART_SERVICE_KER, KER_READY ); /* * free receiving buffer */ MFREE_DESC2(uart_data->ker.rx_data_desc); uart_data->ker.rx_data_desc = NULL; /* * set dlc values */ dlc = &uart_data->dlc_table[UART_CONTROL_INSTANCE]; dlc->drx = &uart_data->drx_base[0]; dlc->dtx = &uart_data->dtx_base[0]; dlc->dlci = 0; dlc->priority = 0; /* * set RX and TX in ready mode */ sig_ker_rx_ready_mode_req(); sig_ker_tx_ready_mode_req(); /* * set frame size for ready mode */ uart_data->n1 = UART_N1_READY_MODE; /* * set DRX and DTX in ready mode */ uart_data->dtx = dlc->dtx; uart_data->drx = dlc->drx; sig_ker_drx_ready_mode_req(UART_CONTROL_INSTANCE); sig_ker_dtx_ready_mode_req(UART_CONTROL_INSTANCE); /* * inform ACI about entering ready mode */ uart_mux_close_ind->device = uart_data->device; PSEND(hCommMMI, uart_mux_close_ind); } else if(received_data->len EQ 0) { /* * prepare next reception */ sig_ker_rx_ready_to_receive_req(received_data, write_pos, (USHORT)(uart_data->n1 + 2)); } else { /* * prepare next reception */ received_data->len = 0; sig_ker_rx_ready_to_receive_req(received_data, 0, (USHORT)(uart_data->n1 + 2)); } break; default: TRACE_ERROR( "SIG_RX_KER_DATA_RECEIVED_IND unexpected" ); break; } } /* sig_rx_ker_data_received_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_rx_ker_line_states_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_RX_KER_LINE_STATES_IND | | Parameters : line_states - new line states | +------------------------------------------------------------------------------ */ GLOBAL void sig_rx_ker_line_states_ind (ULONG line_states) { T_DLC* dlc; UBYTE st_flow; UBYTE st_line_sa; UBYTE st_line_sb; UBYTE st_break_len; TRACE_ISIG( "sig_rx_ker_line_states_ind" ); /* * set DLC */ dlc = &uart_data->dlc_table[UART_CONTROL_INSTANCE]; /* * send primitive if escape sequence or DTR drop is detected */ if(line_states & UART_ESC_RX_MASK) { PALLOC (uart_detected_ind, UART_DETECTED_IND); uart_detected_ind->device = uart_data->device; uart_detected_ind->dlci = dlc->dlci; uart_detected_ind->cause = UART_DETECT_ESC; PSEND (hCommMMI, uart_detected_ind); } if((line_states & UART_DTR_MASK) AND (!(dlc->lines & UART_DTR_MASK))) { PALLOC (uart_detected_ind, UART_DETECTED_IND); uart_detected_ind->device = uart_data->device; uart_detected_ind->dlci = dlc->dlci; uart_detected_ind->cause = UART_DETECT_DTR; PSEND (hCommMMI, uart_detected_ind); } switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_READY: /* * set line states */ if(line_states & UART_X_RX_MASK) st_flow = DTI_FLOW_OFF; else st_flow = DTI_FLOW_ON; if(line_states & UART_SA_RX_MASK) st_line_sa = DTI_SA_OFF; else st_line_sa = DTI_SA_ON; if(line_states & UART_SB_RX_MASK) st_line_sb = DTI_SB_OFF; else st_line_sb = DTI_SB_ON; if(line_states & UART_BRK_RX_MASK) st_break_len = (UBYTE)((line_states & UART_BRKLEN_RX_MASK) >> UART_BRKLEN_RX_POS); else st_break_len = DTI_BREAK_OFF; uart_data->dtx = dlc->dtx; sig_ker_dtx_line_states_req(st_flow, st_line_sa, st_line_sb, st_break_len); break; case KER_MUX_ESTABLISH: case KER_MUX: case KER_MUX_DLC_CLOSING: case KER_MUX_CLOSING: case KER_MUX_CLOSED: break; default: TRACE_ERROR( "SIG_RX_KER_LINE_STATES_IND unexpected" ); break; } /* * store new line states */ dlc->lines &= ~(UART_X_RX_MASK | UART_SA_RX_MASK | UART_SB_RX_MASK | UART_ESC_RX_MASK | UART_BRK_RX_MASK | UART_BRKLEN_RX_MASK); line_states&= ~(UART_ESC_RX_MASK | UART_BRK_RX_MASK | UART_BRKLEN_RX_MASK); dlc->lines |= line_states; } /* sig_rx_ker_line_states_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_rt_ker_timeout_t1_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_RT_KER_TIMEOUT_T1_IND | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void sig_rt_ker_timeout_t1_ind () { UBYTE i; T_desc2* temp_desc; T_DLC* dlc; UBYTE j; UBYTE dlci; ULONG forward; BOOL continuous; TRACE_ISIG( "sig_rt_ker_timeout_t1_ind" ); for( i = 0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++ ) { /* * set dlc value */ dlc = &uart_data->dlc_table[i]; switch(dlc->connection_state) { case UART_CONNECTION_OPEN: case UART_CONNECTION_DISC_SENT: /* * T1 is used for non UIH Control frames */ if((dlc->last_command NEQ NULL) && (dlc->last_command->buffer[UART_OFFSET_CONTROL] NEQ UART_UIH_CONTROL_FRAME)) { if(dlc->retransmissions < uart_data->ker.n2) { /* * retransmission of Control frame */ dlc->retransmissions++; MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + dlc->last_command->len)); temp_desc->next = (ULONG)NULL; temp_desc->len = dlc->last_command->len; memcpy(temp_desc->buffer, dlc->last_command->buffer, dlc->last_command->len); ker_mux_send_frame( temp_desc ); } else { /* * maximum number of retransmissions reached */ switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX: /* * act as on reception of a DM frame */ /* * create DM frame */ MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + 2)); temp_desc->next = (ULONG)NULL; temp_desc->len = 2; memcpy(temp_desc->buffer, dlc->last_command->buffer, 2) ;/*lint !e419 !e420 apparent data overrun and access beyond array*/ temp_desc->buffer[UART_OFFSET_CONTROL] = UART_DM_CONTROL_FRAME; /* * act as on reception of a DM frame */ forward = 0; ker_receive_dm_frame(&forward, temp_desc); /* * process results of analysis */ if(forward) { for(j=0; j <= UART_MAX_NUMBER_OF_CHANNELS; j++) { if(j NEQ UART_CONTROL_INSTANCE) { /* * set dlc values */ dlc = &uart_data->dlc_table[j]; dlci = dlc->dlci; /* * channel to close */ if((forward & UART_FORWARD_DLC_RELEASE) && (dlc->connection_state EQ UART_CONNECTION_DEAD) && (dlci NEQ UART_DLCI_INVALID)) { PALLOC(uart_mux_dlc_release_ind, UART_MUX_DLC_RELEASE_IND); /* * release channel */ ker_mux_dlc_release(j); /* * inform ACI about DLC release */ uart_mux_dlc_release_ind->device = uart_data->device; uart_mux_dlc_release_ind->dlci = dlci; PSEND(hCommMMI, uart_mux_dlc_release_ind); } } } } break; case KER_MUX_DLC_CLOSING: /* * act as on reception of a DM frame */ /* * create DM frame */ MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + 2)); temp_desc->next = (ULONG)NULL; temp_desc->len = 2; memcpy(temp_desc->buffer, dlc->last_command->buffer, 2) ;/*lint !e419 !e420 apparent data overrun and access beyond array*/ temp_desc->buffer[UART_OFFSET_CONTROL] = UART_DM_CONTROL_FRAME; /* * act as on reception of a DM frame */ forward = 0; ker_receive_dm_frame(&forward, temp_desc); /* * process results of analysis */ if(forward) { continuous = FALSE; for(j=0; j <= UART_MAX_NUMBER_OF_CHANNELS; j++) { if(j NEQ UART_CONTROL_INSTANCE) { /* * set dlc values */ dlc = &uart_data->dlc_table[j]; dlci = dlc->dlci; /* * channel to close */ if((forward & UART_FORWARD_DLC_RELEASE) && (dlc->connection_state EQ UART_CONNECTION_DEAD) && (dlci NEQ UART_DLCI_INVALID)) { /* * release channel */ ker_mux_dlc_release(j); } if(dlc->connection_state NEQ UART_CONNECTION_DEAD) continuous = TRUE; } } /* * change state if all channels are closed */ if(continuous EQ FALSE) { SET_STATE( UART_SERVICE_KER, KER_MUX_CLOSING ); /* * build and send CLD command frame: */ ker_mux_send_close_down(); /* * start timer */ sig_ker_rt_start_t3_req(); } } break; case KER_MUX_CLOSING: /* * do not care about retransmission couter * retransmission stops if T3 expires */ dlc->retransmissions++; MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + dlc->last_command->len)); temp_desc->next = (ULONG)NULL; temp_desc->len = dlc->last_command->len; memcpy(temp_desc->buffer, dlc->last_command->buffer, dlc->last_command->len); ker_mux_send_frame( temp_desc ); break; default: TRACE_ERROR( "SIG_RT_KER_TIMEOUT_T1_IND unexpected" ); break; } } } break; case UART_CONNECTION_DEAD: break; default: { TRACE_EVENT_P2("Unexpected DLC connection state: %d, uart_kers.c(%d)", dlc->connection_state, __LINE__); break; } } } if(uart_data->ker.nr_t1) { /* * restart timer t1 */ sig_ker_rt_start_t1_req(); } } /* sig_rt_ker_timeout_t1_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_rt_ker_timeout_t2_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_RT_KER_TIMEOUT_T2_IND | | This signal means that no response to a sent command frame | was received within the allowed time. It is assumed that | the frame has been lost and a retransmission is done if the | maximum number of retransmissions is not reached yet. | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void sig_rt_ker_timeout_t2_ind () { UBYTE i; T_desc2* temp_desc; T_DLC* dlc; TRACE_ISIG( "sig_rt_ker_timeout_t2_ind" ); for( i = 0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++ ) { /* * set dlc value */ dlc = &uart_data->dlc_table[i]; switch(dlc->connection_state) { case UART_CONNECTION_OPEN: case UART_CONNECTION_DISC_SENT: /* * T2 is only used for UIH Control frames */ if((dlc->last_command NEQ NULL) && (dlc->last_command->buffer[UART_OFFSET_CONTROL] EQ UART_UIH_CONTROL_FRAME)) { if(dlc->retransmissions < uart_data->ker.n2) { /* * retransmission of Control frame */ dlc->retransmissions++; MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + dlc->last_command->len)); temp_desc->next = (ULONG)NULL; temp_desc->len = dlc->last_command->len; memcpy(temp_desc->buffer, dlc->last_command->buffer, dlc->last_command->len); ker_mux_send_frame( temp_desc ); } else { /* * maximum number of retransmissions reached */ switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX: case KER_MUX_DLC_CLOSING: /* * skip this frame and send next frame */ /* * remove current UIH frame */ MFREE_DESC2(dlc->last_command); dlc->last_command = NULL; uart_data->ker.nr_t2--; if(dlc->next_command) { /* * transmit next command frame */ dlc->last_command = dlc->next_command; dlc->next_command = (T_desc2*)dlc->next_command->next; dlc->last_command->next = (ULONG)NULL; MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + dlc->last_command->len)); temp_desc->next = (ULONG)NULL; temp_desc->len = dlc->last_command->len; memcpy(temp_desc->buffer, dlc->last_command->buffer, dlc->last_command->len); dlc->retransmissions = 0; ker_mux_send_frame(temp_desc); uart_data->ker.nr_t2++; } break; case KER_MUX_CLOSING: /* * do not care about retransmission couter * retransmission stops if T3 expires */ dlc->retransmissions++; MALLOC(temp_desc, (USHORT)(sizeof( T_desc2 ) - 1 + dlc->last_command->len)); temp_desc->next = (ULONG)NULL; temp_desc->len = dlc->last_command->len; memcpy(temp_desc->buffer, dlc->last_command->buffer, dlc->last_command->len); ker_mux_send_frame( temp_desc ); break; default: TRACE_ERROR( "SIG_RT_KER_TIMEOUT_T2_IND unexpected" ); break; } } } break; case UART_CONNECTION_DEAD: break; default: { TRACE_EVENT_P2("Unexpected DLC connection state: %d, uart_kers.c(%d)", dlc->connection_state, __LINE__); break; } } } if(uart_data->ker.nr_t2) { /* * restart timer t2 */ sig_ker_rt_start_t2_req(); } } /* sig_rt_ker_timeout_t2_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_rt_ker_timeout_t3_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_RT_KER_TIMEOUT_T3_IND | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void sig_rt_ker_timeout_t3_ind () { TRACE_ISIG( "sig_rt_ker_timeout_t3_ind" ); switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_MUX_ESTABLISH: case KER_MUX_CLOSING: SET_STATE( UART_SERVICE_KER, KER_MUX_CLOSED ); /* * stop timers and * remove all DLC instances */ ker_mux_close_down(); if(uart_data->ker.tx_data_desc EQ NULL) { uart_data->ker.received_prim|= UART_MUX_CLOSE_REQ_MASK; if(uart_data->ker.flush_state EQ UART_KER_NOT_FLUSHING) { uart_data->ker.flush_state = UART_KER_TX_FLUSH; sig_ker_tx_flush_req(); } } break; default: TRACE_ERROR( "SIG_RT_KER_TIMEOUT_T3_IND unexpected" ); break; } } /* sig_rt_ker_timeout_t3_ind() */ /* +------------------------------------------------------------------------------ | Function : sig_rt_ker_timeout_tesd_ind +------------------------------------------------------------------------------ | Description : Handles the internal signal SIG_RT_KER_TIMEOUT_TESD_IND | | This signal means that the trailing guard period has completed. | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void sig_rt_ker_timeout_tesd_ind () { UBYTE i; TRACE_ISIG( "sig_rt_ker_timeout_tesd_ind" ); switch( GET_STATE( UART_SERVICE_KER ) ) { case KER_READY: case KER_MUX: for( i = 0; i < UART_MAX_NUMBER_OF_CHANNELS; i++ ) { /* * set current dtx */ uart_data->dtx = &uart_data->dtx_base[i]; sig_ker_dtx_timeout_tesd_req(); } break; default: TRACE_ERROR( "SIG_RT_KER_TIMEOUT_TESD_IND unexpected" ); break; } } /* sig_rt_ker_timeout_tesd_ind() */