FreeCalypso > hg > fc-magnetite
view src/g23m-aci/uart/uart_rxp.c @ 640:16eb1b9640dc
target gtm900 renamed to gtm900mgc2
This change reflects the fact that the build target in question supports
MGC2GSMT hardware only, and will NOT work on other hw that confusing bears
the same end user name of GTM900, neither the LoCosto-based GTM900-C
nor the Calypso-based MG01GSMT that has a different and incompatible RFFE.
If we ever get our hands on a piece of MG01GSMT hw and add support for it,
that other target will be named gtm900mg01.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Fri, 31 Jan 2020 00:46:07 +0000 |
| parents | 53929b40109c |
| children |
line wrap: on
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/* +----------------------------------------------------------------------------- | 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 primitives as described in | the SDL-documentation (RX-statemachine) +----------------------------------------------------------------------------- */ #ifndef UART_RXP_C #define UART_RXP_C #endif /* !UART_RXP_C */ #define ENTITY_UART #ifndef FF_MULTI_PORT /*==== 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 interfac */ #ifdef _TARGET_ #include "uart/serialswitch.h" #include "uart/traceswitch.h" #else /* _TARGET_ */ #include "serial_dat.h" /* to get definitions of serial driver */ #endif /* _TARGET_ */ #include "uart.h" /* to get the global entity definitions */ #include "uart_rxf.h" /* to get rx functions */ #include "uart_kers.h" /* to get ker signals */ #include "uart_dtxs.h" /* to get dtx signals */ #ifdef _SIMULATION_ #include <stdio.h> /* to get sprintf */ #include "uart_rxp.h" /* to get rx_readdata */ #endif /* _SIMULATION_ */ /*==== CONST ================================================================*/ /*==== LOCAL VARS ===========================================================*/ /*==== PRIVATE FUNCTIONS ====================================================*/ /*==== PUBLIC FUNCTIONS =====================================================*/ /* +------------------------------------------------------------------------------ | Function : rx_uart_driver_received_ind +------------------------------------------------------------------------------ | Description : Handles the primitive UART_DRIVER_RECEIVED_IND | | Parameters : *uart_device - affected device database | +------------------------------------------------------------------------------ */ GLOBAL void rx_uart_driver_received_ind ( T_UART_DATA* uart_device ) { USHORT i; BOOL continuous; T_DLC* dlc; T_desc2* temp_desc = NULL; ULONG line_states; TRACE_EVENT( "rx_uart_driver_received_ind()" ); /* * set affected instance */ uart_data = uart_device; /* * inform about new line states */ if(uart_data->rx.lines NEQ uart_data->rx.prev_lines) { /* * convert line states and send it */ line_states = 0; if(uart_data->rx.lines & X_MASK) { line_states|= UART_X_RX_MASK; if(!(uart_data->rx.prev_lines & X_MASK)) { TRACE_EVENT("RX Flow Control: stop"); } } else if(uart_data->rx.prev_lines & X_MASK) { TRACE_EVENT("RX Flow Control: start"); } if(uart_data->rx.lines & SA_MASK) { line_states|= UART_SA_RX_MASK; if(!(uart_data->rx.prev_lines & SA_MASK)) { TRACE_EVENT("DTR: drop"); } } else if(uart_data->rx.prev_lines & SA_MASK) { TRACE_EVENT("DTR: on"); } if(uart_data->rx.lines & SB_MASK) { line_states|= UART_SB_RX_MASK; if(!(uart_data->rx.prev_lines & SB_MASK)) { TRACE_EVENT("RTS: off"); } } else if(uart_data->rx.prev_lines & SB_MASK) { TRACE_EVENT("RTS: on"); } if(uart_data->rx.lines & ESC_MASK) { line_states|= UART_ESC_RX_MASK; TRACE_EVENT("Escape Sequence detected"); } if(uart_data->rx.lines & BRK_MASK) { line_states|= UART_BRK_RX_MASK; line_states|= (((uart_data->rx.lines & BRK_LEN_MASK) >> BRKLEN) << UART_BRKLEN_RX_POS); TRACE_EVENT("Break detected"); } /* * store new line states */ uart_data->rx.lines&= ~(ESC_MASK | BRK_MASK | BRK_LEN_MASK); uart_data->rx.prev_lines = uart_data->rx.lines; /* * inform MMI */ sig_rx_ker_line_states_ind(line_states); } switch( GET_STATE( UART_SERVICE_RX ) ) { case RX_READY: dlc = &uart_data->dlc_table[UART_CONTROL_INSTANCE]; if(uart_data->rx.dlc_instance NEQ UART_EMPTY_INSTANCE) { uart_data->rx.dlc_instance = UART_EMPTY_INSTANCE; uart_data->rx.analyze_state = UART_RX_ERROR; /* * if ISR has read out some data * inform all channels about data reception */ if(uart_data->rx.read_permission) { for(i = 0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { switch(uart_data->dlc_table[i].receive_process) { case UART_RX_PROCESS_READY: case UART_RX_PROCESS_COMPLETE: /* * inform all channels about data reception */ uart_data->dlc_table[i].receive_process = UART_RX_PROCESS_STOP; temp_desc = uart_data->dlc_table[i].receive_data; uart_data->dlc_table[i].receive_data = NULL; if(i EQ UART_CONTROL_INSTANCE) { /* * Control channel */ sig_rx_ker_data_received_ind( temp_desc, uart_data->dlc_table[i].receive_pos); } else { /* * Data channel */ uart_data->dtx = uart_data->dlc_table[i].dtx; sig_rx_dtx_data_received_ind( temp_desc, uart_data->dlc_table[i].receive_pos); } /* fall through */ case UART_RX_PROCESS_STOP: /* * add new channels which want to receive */ if(uart_data->dlc_table[i].receive_data) uart_data->dlc_table[i].receive_process = UART_RX_PROCESS_READY; break; default: TRACE_EVENT_P2("Unexpected DLC process state: %d | uart_rxp.c(%d)", dlc->receive_process, __LINE__); break; } } } } else { switch(dlc->receive_process) { case UART_RX_PROCESS_READY: case UART_RX_PROCESS_COMPLETE: /* * if ISR has read out some data * inform channel about data reception */ if(uart_data->rx.read_permission) { /* * inform channel about data reception */ dlc->receive_process = UART_RX_PROCESS_STOP; temp_desc = dlc->receive_data; dlc->receive_data = NULL; uart_data->dtx = dlc->dtx; sig_rx_dtx_data_received_ind(temp_desc, dlc->receive_pos); } /* fall through */ case UART_RX_PROCESS_STOP: /* * add new channel which want to receive */ if(dlc->receive_data) dlc->receive_process = UART_RX_PROCESS_READY; break; default: TRACE_EVENT_P2("Unexpected DLC process state: %d | uart_rxp.c(%d)", dlc->receive_process, __LINE__); break; } } if(dlc->receive_process EQ UART_RX_PROCESS_STOP) { uart_data->rx.receive_state = UART_RX_NOT_RECEIVING; break; } #ifdef _SIMULATION_ if(rx_inpavail(uart_data->device) > 0) #else /* _SIMULATION_ */ if(UF_InpAvail (uart_data->device) > 0) #endif /* _SIMULATION_ */ { /* * inform channel about reading */ uart_data->rx.read_permission = TRUE; uart_data->dtx = dlc->dtx; sig_rx_dtx_receiving_ind(); } else uart_data->rx.read_permission = FALSE; if(uart_data EQ (&(uart_data_base[0]))) { TRACE_EVENT("UF_ReadData()"); #ifdef _SIMULATION_ rx_readdata(0); #else /* _SIMULATION_ */ UF_ReadData (uart_data->device, sm_suspend, rx_readOutFunc_0); #endif /* else _SIMULATION_ */ } #ifdef FF_TWO_UART_PORTS else if(uart_data EQ (&(uart_data_base[1]))) { TRACE_EVENT("UF_ReadData()"); #ifdef _SIMULATION_ rx_readdata(1); #else /* _SIMULATION_ */ UF_ReadData (uart_data->device, sm_suspend, rx_readOutFunc_1); #endif /* else _SIMULATION_ */ } #endif /* FF_TWO_UART_PORTS */ else { TRACE_ERROR("wrong value of uart_data"); } break; case RX_MUX: if(uart_data->rx.dlc_instance EQ UART_EMPTY_INSTANCE) { uart_data->rx.dlc_instance = UART_CONTROL_INSTANCE; uart_data->rx.analyze_state = UART_RX_ERROR; } continuous = FALSE; for(i = 0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { dlc = &uart_data->dlc_table[i]; switch(dlc->receive_process) { case UART_RX_PROCESS_READY: case UART_RX_PROCESS_COMPLETE: /* * if ISR has read out some data * inform all channels about data reception */ if(uart_data->rx.read_permission) { dlc->receive_process = UART_RX_PROCESS_STOP; temp_desc = dlc->receive_data; dlc->receive_data = NULL; if(i EQ UART_CONTROL_INSTANCE) { /* * Control channel */ sig_rx_ker_data_received_ind(temp_desc, dlc->receive_pos); } else { /* * Data channel */ uart_data->dtx = dlc->dtx; sig_rx_dtx_data_received_ind(temp_desc, dlc->receive_pos); } } /* fall through */ case UART_RX_PROCESS_STOP: /* * add new channels which want to receive */ if(dlc->receive_data) dlc->receive_process = UART_RX_PROCESS_READY; break; default: TRACE_EVENT_P2("Unexpected DLC process state: %d, uart_rxp.c(%d)", dlc->receive_process, __LINE__); break; } if(dlc->receive_process NEQ UART_RX_PROCESS_STOP) continuous = TRUE; } /* * check whether there is a channel to receive */ if(continuous NEQ TRUE) { uart_data->rx.receive_state = UART_RX_NOT_RECEIVING; break; } #ifdef _SIMULATION_ if(rx_inpavail(uart_data->device) > 0) #else /* _SIMULATION_ */ if(UF_InpAvail (uart_data->device) > 0) #endif /* _SIMULATION_ */ { /* * inform each channel about reading */ uart_data->rx.read_permission = TRUE; for(i = 0; i <= UART_MAX_NUMBER_OF_CHANNELS; i++) { if(uart_data->dlc_table[i].receive_process EQ UART_RX_PROCESS_READY) { if(i EQ UART_CONTROL_INSTANCE) { /* * Control channel */ sig_rx_ker_receiving_ind(); } else { /* * Data channel */ uart_data->dtx = uart_data->dlc_table[i].dtx; sig_rx_dtx_receiving_ind(); } } } } else uart_data->rx.read_permission = FALSE; if(uart_data EQ (&(uart_data_base[0]))) { TRACE_EVENT("UF_ReadData()"); #ifdef _SIMULATION_ rx_readdata(0); #else /* _SIMULATION_ */ UF_ReadData (uart_data->device, sm_suspend, rx_readOutFunc_0); #endif /* else _SIMULATION_ */ } #ifdef FF_TWO_UART_PORTS else if(uart_data EQ (&(uart_data_base[1]))) { TRACE_EVENT("UF_ReadData()"); #ifdef _SIMULATION_ rx_readdata(1); #else /* _SIMULATION_ */ UF_ReadData (uart_data->device, sm_suspend, rx_readOutFunc_1); #endif /* else _SIMULATION_ */ } #endif /* FF_TWO_UART_PORTS */ else { TRACE_ERROR("wrong value of uart_data"); } break; default: TRACE_ERROR( "UART_DRIVER_RECEIVED_IND unexpected" ); break; } } /* rx_uart_driver_received_ind() */ #ifdef _SIMULATION_ /* +------------------------------------------------------------------------------ | Function : rx_dti_data_test_ind +------------------------------------------------------------------------------ | Description : Handles the primitive DTI_DATA_TEST_IND | | Parameters : *dti_data_test_ind - Ptr to primitive payload | +------------------------------------------------------------------------------ */ GLOBAL void rx_dti_data_test_ind ( T_DTI2_DATA_TEST_IND *dti_data_test_ind ) { char buf[100]; T_reInstMode reInstall; USHORT size[2]; USHORT pos; USHORT i; T_UART_DATA* uart_device; TRACE_FUNCTION( "rx_dti_data_test_ind" ); /* * set UART instance */ uart_device = &(uart_data_base[UART_TEST_C_ID_1]); /* * copy data to simulation buffer */ MFREE_DESC2(uart_device->rx.sim_buffer); MALLOC(uart_device->rx.sim_buffer, (USHORT)(sizeof(T_desc2) - 1 + (dti_data_test_ind->sdu.l_buf >> 3))); memcpy(uart_device->rx.sim_buffer->buffer, &dti_data_test_ind->sdu.buf[dti_data_test_ind->sdu.o_buf >> 3], dti_data_test_ind->sdu.l_buf >> 3); uart_device->rx.sim_buffer->len = dti_data_test_ind->sdu.l_buf >> 3; uart_device->rx.sim_buffer->next = (ULONG)NULL; uart_device->rx.sim_pos = 0; /* * trace output */ sprintf(buf, "UART device %d:", dti_data_test_ind->link_id); TRACE_FUNCTION( buf ); i = 0; pos = uart_device->rx.sim_pos; while(pos < uart_device->rx.sim_buffer->len) { i+= sprintf(&buf[i], "0x%02x, ", uart_device->rx.sim_buffer->buffer[pos]); pos++; if(i > 80) { TRACE_FUNCTION( buf ); i = 0; } else if(pos >= uart_device->rx.sim_buffer->len) { TRACE_FUNCTION( buf ); } } /* * set values for ISR */ uart_device->rx.source[0] = &uart_device->rx.sim_buffer->buffer[ uart_device->rx.sim_pos]; uart_device->rx.source[1] = NULL; size[0] = uart_device->rx.sim_buffer->len - uart_device->rx.sim_pos; size[1] = 0; /* * call actual function */ rx_readOutFunc_0 (FALSE, &reInstall, 1, uart_device->rx.source, size, 0); /* * store return values */ if(size[0] EQ 0) { MFREE_DESC2(uart_device->rx.sim_buffer); uart_device->rx.sim_buffer = NULL; } else uart_device->rx.sim_pos = uart_device->rx.sim_buffer->len - size[0]; /* * free the primitive */ PFREE(dti_data_test_ind); } /* rx_dti_data_test_ind() */ /* +------------------------------------------------------------------------------ | Function : rx_readdata +------------------------------------------------------------------------------ | Description : Simulates a UF_ReadData() call. | | Parameters : caller - calling UART instance | +------------------------------------------------------------------------------ */ GLOBAL void rx_readdata (UBYTE caller) { T_reInstMode reInstall; USHORT size[2]; T_UART_DATA* uart_device; TRACE_FUNCTION( "rx_readdata" ); /* * set UART instance */ uart_device = &(uart_data_base[caller]); if(uart_device->rx.sim_buffer EQ NULL) { /* * send DTI_GETDATA_REQ */ PALLOC (dti_getdata_req, DTI2_GETDATA_REQ); dti_getdata_req->link_id = LINK_READDATA_PORT_1; /* for usual read_data */ PSEND (hCommMMI, dti_getdata_req); } else { /* * set values for ISR */ uart_device->rx.source[0] = NULL; uart_device->rx.source[1] = &uart_device->rx.sim_buffer->buffer[ uart_device->rx.sim_pos]; size[0] = 0; size[1] = uart_device->rx.sim_buffer->len - uart_device->rx.sim_pos; /* * call actual function */ if(caller EQ 0) { rx_readOutFunc_0 (FALSE, &reInstall, 2, uart_device->rx.source, size, 0); } #ifdef FF_TWO_UART_PORTS else if(caller EQ 1) { rx_readOutFunc_1 (FALSE, &reInstall, 2, uart_device->rx.source, size, 0); } #endif /* FF_TWO_UART_PORTS */ else { TRACE_ERROR("wrong caller value"); } /* * store return values */ if(size[1] EQ 0) { MFREE_DESC2(uart_device->rx.sim_buffer); uart_device->rx.sim_buffer = NULL; } else uart_device->rx.sim_pos = uart_device->rx.sim_buffer->len - size[1]; } } /* rx_readdata() */ /* +------------------------------------------------------------------------------ | Function : rx_inpavail +------------------------------------------------------------------------------ | Description : Simulates a UF_InpAvail() call. | | Parameters : caller - calling UART instance | | Return : number of octets in Input Queue | +------------------------------------------------------------------------------ */ GLOBAL USHORT rx_inpavail (UBYTE caller) { T_UART_DATA* uart_device; TRACE_FUNCTION( "rx_inpavail" ); /* * set UART instance */ uart_device = &(uart_data_base[caller]); if(uart_device->rx.sim_buffer) return uart_device->rx.sim_buffer->len - uart_device->rx.sim_pos; else return 0; } /* rx_inpavail() */ #endif /* _SIMULATION_ */ #endif /* !FF_MULTI_PORT */