FreeCalypso > hg > fc-magnetite
view src/cs/drivers/drv_app/uart/serialswitch_dp.c @ 702:9394305d4ff5 default tip
etm_audio.c: fix off-by-one error in auw of FIR coefficients
This fix was already made in FC Tourmaline a while back, but it is also
the kind of bugfix that deserves to be backported to Magnetite and
Selenite as well.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Mon, 31 Oct 2022 00:14:44 +0000 |
parents | 945cf7f506b2 |
children |
line wrap: on
line source
/******************************************************************************* * * SERIALSWITCH.C * * Board-specific switch for Perseus * * (C) Texas Instruments 2000 * ******************************************************************************/ #ifndef __SERIALSWITCH_C__ #define __SERIALSWITCH_C__ #include "main/sys_types.h" #include "memif/mem.h" #include "nucleus.h" #include "csmi/csmi.h" #include "uart/serialswitch.h" #include "uart/uart.h" #include "uart/uartfax.h" #include "csmi/csmi_uart.h" #include "csmi/csmi_uartfax.h" #include "inth/iq.h" static int serial_config; #define NUMBER_OF_UART 2 // Constant used to avoid calling uart interrupt handler when using CSMI #define DISABLE_UART_INTERRUPT_HANDLER 0x0 // Internal UART constants & macros - used by interrupt handler #define IIR (0x02) /* UART interrupt ident. register - Read only */ #define SCR (0x10) /* UART suppl. control register - Read/Write */ #define SSR (0x11) /* UART suppl. status register - Read only */ #define IIR_BITS_USED (0x07) #define IT_NOT_PENDING (0x01) /* * Supplementary Control Register */ #define RX_CTS_WAKE_UP_ENABLE_BIT (4) /* * Supplementary Status Register */ #define RX_CTS_WAKE_UP_STS (0x02) /* Wake-up interrupt occurred */ /* * This macro allows to read an UART register. */ #define READ_UART_REGISTER(UART,REG) \ *((volatile SYS_UWORD8 *) ((UART)->base_address + (REG))) /* * This macro allows to disable the UART's wake-up interrupt. */ #define DISABLE_WAKE_UP_INTERRUPT(UART) \ *((volatile SYS_UWORD8 *) ((UART)->base_address + SCR)) &= \ ~(1 << (RX_CTS_WAKE_UP_ENABLE_BIT)); /* * Wake-up time duration in seconds and in number of TDMAs. * 1 TDMA = (6 / 1300) s = 0.004615 s (= 4.615 ms). */ #define WAKE_UP_TIME_DURATION (10) /* 7200 seconds = 120 min. = 2 hours*/ #define WAKE_UP_TIME_IN_TDMA (WAKE_UP_TIME_DURATION * 1300 / 6) char ser_cfg_info[NUMBER_OF_TR_UART] = {0, 0}; /* * Types of flows supported. */ typedef enum { TRACE_FLOW, FAX_DATA_FLOW } t_flow_type; static const unsigned long uart_base_address[NUMBER_OF_UART] = { MEM_UART_IRDA, MEM_UART_MODEM }; static NU_TIMER uart_wake_up_duration_timer; static unsigned char uart_waked_up_by_interrupt; #if ((CHIPSET == 2) || (CHIPSET == 3)) static unsigned long uart_spurious_interrupts; #elif ((CHIPSET == 4) || (CHIPSET == 5) || (CHIPSET == 6) || (CHIPSET == 7)) static unsigned long uart_modem_spurious_interrupts; static unsigned long uart_irda_spurious_interrupts; #endif // Structures representing the arrays typedef struct { void (*tr_Init) (T_tr_UartId device, int baudrate, void (callback_function (void))); unsigned long (*tr_ReadNChars) (T_tr_UartId device, char *buffer, unsigned long chars_to_read); unsigned long (*tr_ReadNBytes) (T_tr_UartId device, char *buffer, unsigned long chars_to_read, unsigned char *eof_detected); unsigned long (*tr_WriteNChars) (T_tr_UartId device, char *buffer, unsigned long chars_to_write); unsigned long (*tr_EncapsulateNChars) (T_tr_UartId device, char *buffer, unsigned long chars_to_write); unsigned long (*tr_WriteNBytes) (T_tr_UartId device, unsigned char *buffer, unsigned long chars_to_write); void (*tr_WriteChar) (T_tr_UartId device, char character); void (*tr_WriteString) (T_tr_UartId device, char *buffer); unsigned char (*tr_EnterSleep) (T_tr_UartId device); void (*tr_WakeUp) (T_tr_UartId device); } TR_DRV; /* * Set of function pointers for fax & data functions. */ typedef struct { T_FDRET (*fd_Init) (T_fd_UartId uartNo); T_FDRET (*fd_Enable) (T_fd_UartId uartNo, unsigned char enable); T_FDRET (*fd_SetComPar) (T_fd_UartId uartNo, T_baudrate baudrate, T_bitsPerCharacter bpc, T_stopBits sb, T_parity parity); T_FDRET (*fd_SetBuffer) (T_fd_UartId uartNo, unsigned short bufSize, unsigned short rxThreshold, unsigned short txThreshold); T_FDRET (*fd_SetFlowCtrl) (T_fd_UartId uartNo, T_flowCtrlMode fcMode, unsigned char XON, unsigned char XOFF); T_FDRET (*fd_SetEscape) (T_fd_UartId uartNo, unsigned char escChar, unsigned short guardPeriod); T_FDRET (*fd_InpAvail) (T_fd_UartId uartNo); T_FDRET (*fd_OutpAvail) (T_fd_UartId uartNo); T_FDRET (*fd_EnterSleep) (T_fd_UartId uartNo); T_FDRET (*fd_WakeUp) (T_fd_UartId uartNo); T_FDRET (*fd_ReadData) (T_fd_UartId uartNo, T_suspendMode suspend, void (readOutFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char nsource, unsigned char *source[], unsigned short size[], unsigned long state))); T_FDRET (*fd_WriteData) (T_fd_UartId uartNo, T_suspendMode suspend, void (writeInFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char ndest, unsigned char *dest[], unsigned short size[]))); T_FDRET (*fd_StopRec) (T_fd_UartId uartNo); T_FDRET (*fd_StartRec) (T_fd_UartId uartNo); T_FDRET (*fd_GetLineState) (T_fd_UartId uartNo, unsigned long *state); T_FDRET (*fd_SetLineState) (T_fd_UartId uartNo, unsigned long state, unsigned long mask); T_FDRET (*fd_CheckXEmpty) (T_fd_UartId uartNo); } FD_DRV; /* * UART structure used for UARTs. */ typedef struct { SYS_UWORD32 base_address; SYS_BOOL device_used; SYS_BOOL deep_sleep_set_up; t_flow_type flow_type; SYS_WORD16 flow_id; void (*interrupt_handler) (int uart_id, SYS_UWORD8 interrupt_status); } T_UART; /* * Internal variables and prototypes of stubs */ static unsigned short fd_bufSize; static unsigned char fd_buffer[FD_MAX_BUFFER_SIZE]; static unsigned char fd_driver_enabled; static void dummy_tr_Init (int device, int baudrate, void (callback_function (void))); static unsigned long dummy_tr_ReadNChars (int device, char *buffer, unsigned long chars_to_read); static unsigned long dummy_tr_ReadNBytes (T_tr_UartId device, char *buffer, unsigned long chars_to_read, unsigned char *eof_detected); static unsigned long dummy_tr_WriteNChars (int device, char *buffer, unsigned long chars_to_write); static unsigned long dummy_tr_EncapsulateNChars (T_tr_UartId device, char *buffer, unsigned long chars_to_write); static unsigned long dummy_tr_WriteNBytes (T_tr_UartId device, unsigned char *buffer, unsigned long chars_to_write); static void dummy_tr_WriteChar (int device, char character); static void dummy_tr_WriteString (int device, char *buffer); static unsigned char dummy_tr_EnterSleep (T_tr_UartId device); static void dummy_tr_WakeUp (T_tr_UartId device); static T_FDRET dummy_fd_Init (T_fd_UartId uartNo); static T_FDRET dummy_fd_Enable (T_fd_UartId uartNo, unsigned char enable); static T_FDRET dummy_fd_SetComPar (T_fd_UartId uartNo, T_baudrate baudrate, T_bitsPerCharacter bpc, T_stopBits sb, T_parity parity); static T_FDRET dummy_fd_SetBuffer (T_fd_UartId uartNo, unsigned short bufSize, unsigned short rxThreshold, unsigned short txThreshold); static T_FDRET dummy_fd_SetFlowCtrl (T_fd_UartId uartNo, T_flowCtrlMode fcMode, unsigned char XON, unsigned char XOFF); static T_FDRET dummy_fd_SetEscape (T_fd_UartId uartNo, unsigned char escChar, unsigned short guardPeriod); static T_FDRET dummy_fd_InpAvail (T_fd_UartId uartNo); static T_FDRET dummy_fd_OutpAvail (T_fd_UartId uartNo); static T_FDRET dummy_fd_EnterSleep (T_fd_UartId uartNo); static T_FDRET dummy_fd_WakeUp (T_fd_UartId uartNo); static T_FDRET dummy_fd_ReadData (T_fd_UartId uartNo, T_suspendMode suspend, void (readOutFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char nsource, unsigned char *source[], unsigned short size[], unsigned long state))); static T_FDRET dummy_fd_WriteData (T_fd_UartId uartNo, T_suspendMode suspend, void (writeInFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char ndest, unsigned char *dest[], unsigned short size[]))); static T_FDRET dummy_fd_StopRec (T_fd_UartId uartNo); static T_FDRET dummy_fd_StartRec (T_fd_UartId uartNo); static T_FDRET dummy_fd_GetLineState (T_fd_UartId uartNo, unsigned long *state); static T_FDRET dummy_fd_SetLineState (T_fd_UartId uartNo, unsigned long state, unsigned long mask); static T_FDRET dummy_fd_CheckXEmpty (T_fd_UartId uartNo); // Arrays of pointers to functions const TR_DRV TR_Uart = { UA_Init, UA_ReadNChars, UA_ReadNBytes, UA_WriteNChars, UA_EncapsulateNChars, UA_WriteNBytes, UA_WriteChar, UA_WriteString, UA_EnterSleep, UA_WakeUp }; const TR_DRV TR_Dummy = { dummy_tr_Init, dummy_tr_ReadNChars, dummy_tr_ReadNBytes, dummy_tr_WriteNChars, dummy_tr_EncapsulateNChars, dummy_tr_WriteNBytes, dummy_tr_WriteChar, dummy_tr_WriteString, dummy_tr_EnterSleep, dummy_tr_WakeUp }; const TR_DRV TR_Csmi = { CU_Init, CU_ReadNChars, CU_ReadNBytes, CU_WriteNChars, CU_EncapsulateNChars, CU_WriteNBytes, CU_WriteChar, CU_WriteString, CU_EnterSleep, CU_WakeUp }; const FD_DRV FD_Uart = { UAF_Init, UAF_Enable, UAF_SetComPar, UAF_SetBuffer, UAF_SetFlowCtrl, UAF_SetEscape, UAF_InpAvail, UAF_OutpAvail, UAF_EnterSleep, UAF_WakeUp, UAF_ReadData, UAF_WriteData, UAF_StopRec, UAF_StartRec, UAF_GetLineState, UAF_SetLineState, UAF_CheckXEmpty }; const FD_DRV FD_Csmi = { CF_Init, CF_Enable, CF_SetComPar, CF_SetBuffer, CF_SetFlowCtrl, CF_SetEscape, CF_InpAvail, CF_OutpAvail, dummy_fd_EnterSleep, dummy_fd_WakeUp, CF_ReadData, CF_WriteData, CF_StopRec, CF_StartRec, CF_GetLineState, CF_SetLineState, dummy_fd_CheckXEmpty }; const FD_DRV FD_Dummy = { dummy_fd_Init, dummy_fd_Enable, dummy_fd_SetComPar, dummy_fd_SetBuffer, dummy_fd_SetFlowCtrl, dummy_fd_SetEscape, dummy_fd_InpAvail, dummy_fd_OutpAvail, dummy_fd_EnterSleep, dummy_fd_WakeUp, dummy_fd_ReadData, dummy_fd_WriteData, dummy_fd_StopRec, dummy_fd_StartRec, dummy_fd_GetLineState, dummy_fd_SetLineState, dummy_fd_CheckXEmpty }; #define MAX_TRACE_STREAMS 4 #define MAX_FD_STREAMS 2 /* * The board's serial configuration includes : * an array of trace drivers, each with its associated UART identifier * a data driver, also with its UART identifier * */ typedef struct { const TR_DRV *trDrv; int trId; } T_TRACE_CONFIG; typedef struct { const FD_DRV *fdDrv; int fdId; } T_DATA_CONFIG; typedef struct { T_TRACE_CONFIG trCfg[MAX_TRACE_STREAMS]; T_DATA_CONFIG fdCfg[MAX_FD_STREAMS]; } T_SERIAL_CONFIG; /* * All possible serial configurations are described in this table */ const T_SERIAL_CONFIG serialConfigs[] = { // serial config 0 : TEST & DEBUG configuration // - Riviera trace (1) on serial port 1 (gsm uart modem) // - fax & data Dummy { { { &TR_Dummy, -1 }, { &TR_Uart, 1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, }, { { &FD_Dummy, -1 }, { &FD_Dummy, -1 } }, }, // serial config 1 : TEST & DEBUG configuration // - trace (0) Dummy // - fax & data on serial port 1 (gsm uart modem) { { { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, }, { { &FD_Uart, 1 }, { &FD_Dummy, -1 } }, }, // serial config 2 : PRODUCTION configuration // - Riviera trace (Dummy for debug) // - fax & data on CSMI port 5 (Fax Data #0) { { { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, }, { { &FD_Csmi, 0 }, { &FD_Dummy, -1 } }, }, // serial config 3 : PRODUCTION configuration (FaxData with dual port) // - Riviera trace (Dummy for debug) // - fax & data on CSMI port 5 and 6 (Fax Data #0 and #1) { { { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, }, { { &FD_Csmi, 0 }, { &FD_Csmi, 1 } }, }, // serial config 4 : TEST & DEBUG configuration (for ANITE dial up networking) // - trace (0) dummy // - fax & data on serial port 1 (gsm uart modem) { { { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, }, { { &FD_Uart, 1 }, { &FD_Dummy, -1 } }, }, // serial config 5 : TEST & DEBUG configuration // - trace (1) dummy // - fax & data on serial port 1 (gsm uart modem) { { { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, }, { { &FD_Uart, 1 }, { &FD_Dummy, -1 } }, }, // serial config 6 : TEST & DEBUG configuration (CSMI debug) // - Riviera trace (1) on serial port 1 (gsm uart modem) // - fax & data on CSMI { { { &TR_Dummy, -1 }, { &TR_Uart, 1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, }, { { &FD_Csmi, 0 }, { &FD_Csmi, 1 } }, }, // serial config 7 : TEST & DEBUG configuration (stand-alone) // - Riviera trace (1) on csmi trace port // - fax & data on CSMI { { { &TR_Dummy, -1 }, { &TR_Csmi, 0 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, }, { { &FD_Csmi, 0 }, { &FD_Csmi, 1 } }, }, // serial config 8 : TEST & DEBUG configuration for PGT // - trace (0) on serial port 1 (gsm uart modem) // - fax & data Dummy { { { &TR_Uart, 1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, { &TR_Dummy, -1 }, }, { { &FD_Dummy, -1 }, { &FD_Dummy, -1 } }, } }; const T_SERIAL_CONFIG *serialConfigP; // Physical UART data structures static T_UART int_uart[2]; static SYS_UWORD32 uart_spurious_interrupts; /******************************************************************************* * * analyze_uart_wake_up_timer_expiration * * Purpose : The wake-up time duration has just expired. If requested, UARTs * can again be set up to enter Deep Sleep. * * Arguments: In : id: parameter not used. * Out: none * * Returns : none * ******************************************************************************/ void analyze_uart_wake_up_timer_expiration (UNSIGNED id) { /* * Wake-up time duration has expired. * UARTs can again be set up for Deep Sleep. */ (void) NU_Control_Timer (&uart_wake_up_duration_timer, NU_DISABLE_TIMER); uart_waked_up_by_interrupt = 0; } /******************************************************************************* * * start_uart_wake_up_timer * * Purpose : Starts the wake-up duration timer once UARTs have been waked-up * by an interrupt. * * Arguments: In : none * Out: none * * Returns : none * ******************************************************************************/ void start_uart_wake_up_timer (void) { /* * Wake-up duration timer is started. * UARTs can't no more be set up for Deep Sleep until the timer expires. */ (void) NU_Reset_Timer (&uart_wake_up_duration_timer, &analyze_uart_wake_up_timer_expiration, WAKE_UP_TIME_IN_TDMA, 0, /* The timer expires once. */ NU_DISABLE_TIMER); (void) NU_Control_Timer (&uart_wake_up_duration_timer, NU_ENABLE_TIMER); } /******************************************************************************* * * SER_WriteConfig * * Purpose: TBD * * Parameters: In : new_config: TBD * write_to_flash: TBD * Out: none * * Return: 0 (FALSE) : In case of error while trying to write file in FFS * >= 1 (TRUE) : Successful operation. * ******************************************************************************/ SYS_BOOL SER_WriteConfig (char *new_config, SYS_BOOL write_to_flash) { // Dummy function to make the linker happy. (SER_WriteConfig is called by cst) SYS_BOOL status = 0; return (status); } /******************************************************************************* * * SER_ImmediateSwitch * * Purpose: TBD * * Parameters: In : none * Out: none * * Return: 0 (FALSE) : In case of error. * >= 1 (TRUE) : Successful operation. * ******************************************************************************/ SYS_BOOL SER_ImmediateSwitch (void) { // Dummy function to make the linker happy. (SER_ImmediateSwitch is called by cst) SYS_BOOL status = 0; return (status); } /* * SER_InitSerialConfig * * */ void SER_InitSerialConfig (int cfg) { int uart_id; SYS_BOOL uart_used; /* * Basic UARTs initializations. */ for (uart_id = 0; uart_id < NUMBER_OF_UART; uart_id++) { int_uart[uart_id].base_address = uart_base_address[uart_id]; int_uart[uart_id].device_used = 0; int_uart[uart_id].deep_sleep_set_up = 0; } uart_spurious_interrupts = 0; uart_waked_up_by_interrupt = 0; // Install the 2 interrupt handlers for each serial config switch (cfg) { case 0: int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].interrupt_handler = UA_InterruptHandler; break; case 1: int_uart[0].device_used = 0; int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].device_used = 1; int_uart[1].flow_id = 1; int_uart[1].flow_type = FAX_DATA_FLOW; int_uart[1].interrupt_handler = UAF_InterruptHandler; break; case 2: int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; break; case 3: int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; break; case 4: int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].interrupt_handler = UAF_InterruptHandler; break; case 5: int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].interrupt_handler = UAF_InterruptHandler; break; case 6: int_uart[0].device_used = 0; int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].device_used = 1; int_uart[1].flow_id = 1; int_uart[1].flow_type = TRACE_FLOW; int_uart[1].interrupt_handler = UA_InterruptHandler; break; case 7: int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; break; case 8: int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].interrupt_handler = UA_InterruptHandler; break; default : cfg=0; int_uart[0].interrupt_handler = DISABLE_UART_INTERRUPT_HANDLER; int_uart[1].interrupt_handler = UA_InterruptHandler; break; } serialConfigP = &serialConfigs[cfg]; /* * Checks if both UARTs are used. * If not, performs minimum initialization including Sleep Mode. */ uart_used = 0; for (uart_id = 0; uart_id < NUMBER_OF_UART; uart_id++) { if (!(int_uart[uart_id].device_used)) initialize_uart_sleep (uart_id); else /* if (int_uart[uart_id].device_used) */ uart_used = 1; /* At least one UART is used */ } /* * If at least one uart is used, create a timer to control the wake-up * time duration. */ if (uart_used) (void) NU_Create_Timer ( &uart_wake_up_duration_timer, "Wake Up", &analyze_uart_wake_up_timer_expiration, 0, /* Parameter supplied to the routine: not used. */ WAKE_UP_TIME_IN_TDMA, 0, /* The timer expires once. */ NU_DISABLE_TIMER); } void SER_tr_Init (int id, int baudrate, void (callback_function (void))) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; (trDrv->tr_Init)(trId, baudrate, callback_function); } unsigned long SER_tr_ReadNChars (int id, char *buffer, unsigned long chars_to_read) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; return ((trDrv->tr_ReadNChars)(trId, buffer, chars_to_read)); } unsigned long SER_tr_ReadNBytes (int id, char *buffer, unsigned long chars_to_read, unsigned char *eof_detected) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; return ((trDrv->tr_ReadNBytes) (trId, buffer, chars_to_read, eof_detected)); } unsigned long SER_tr_WriteNChars (int id, char *buffer, unsigned long chars_to_write) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; return ((trDrv->tr_WriteNChars)(trId, buffer, chars_to_write)); } unsigned long SER_tr_EncapsulateNChars (int id, char *buffer, unsigned long chars_to_write) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; return ((trDrv->tr_EncapsulateNChars) (trId, buffer, chars_to_write)); } unsigned long SER_tr_WriteNBytes (int id, unsigned char *buffer, unsigned long chars_to_write) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; return ((trDrv->tr_WriteNBytes) (trId, buffer, chars_to_write)); } void SER_tr_WriteChar (int id, char character) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; (trDrv->tr_WriteChar)(trId, character); } void SER_tr_WriteString (int id, char *buffer) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; (trDrv->tr_WriteString)(trId, buffer); } unsigned char SER_tr_EnterSleep (int id) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; return ((trDrv->tr_EnterSleep) (trId)); } void SER_tr_WakeUp (int id) { const TR_DRV *trDrv; int trId; trDrv = serialConfigP->trCfg[id].trDrv; trId = serialConfigP->trCfg[id].trId; (trDrv->tr_WakeUp) (trId); } /* * SER_fd_xx : Fax/data functions * */ T_FDRET SER_fd_Init(void) { return UF_Init (0); } T_FDRET SER_fd_Enable (unsigned char enable) { return UF_Enable (0, enable); } T_FDRET SER_fd_SetComPar (T_baudrate baudrate, T_bitsPerCharacter bpc, T_stopBits sb, T_parity parity) { return UF_SetComPar (0, baudrate, bpc, sb, parity); } T_FDRET SER_fd_SetBuffer (unsigned short bufSize, unsigned short rxThreshold, unsigned short txThreshold) { return UF_SetBuffer (0, bufSize, rxThreshold, txThreshold); } T_FDRET SER_fd_SetFlowCtrl (T_flowCtrlMode fcMode, unsigned char XON, unsigned char XOFF) { return UF_SetFlowCtrl (0, fcMode, XON, XOFF); } T_FDRET SER_fd_SetEscape (char escChar, unsigned short guardPeriod) { return UF_SetEscape (0, escChar, guardPeriod); } T_FDRET SER_fd_InpAvail (void) { return UF_InpAvail (0); } T_FDRET SER_fd_OutpAvail (void) { return UF_OutpAvail (0); } T_FDRET SER_fd_EnterSleep (void) { return UF_EnterSleep (0); } T_FDRET SER_fd_WakeUp (void) { UF_WakeUp (0); } T_FDRET SER_fd_ReadData (T_suspendMode suspend, void (readOutFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char nsource, unsigned char *source[], unsigned short size[], unsigned long state))) { return UF_ReadData (0, suspend, readOutFunc); } T_FDRET SER_fd_WriteData (T_suspendMode suspend, void (writeInFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char ndest, unsigned char *dest[], unsigned short size[]))) { return UF_WriteData (0, suspend, writeInFunc); } T_FDRET SER_fd_StopRec (void) { return UF_StopRec(0); } T_FDRET SER_fd_StartRec (void) { return UF_StartRec(0); } T_FDRET SER_fd_GetLineState (unsigned long *state) { return UF_GetLineState(0, state); } T_FDRET SER_fd_SetLineState (unsigned long state, unsigned long mask) { return UF_SetLineState(0, state, mask); } T_FDRET SER_fd_CheckXEmpty (void) { return UF_CheckXEmpty(0); } /* * * SER_int_uart_handlerx * * Internal UART interrupt handler. * * Perseus has 2 internal UARTs, each with its own interrupt vector * */ void SER_uart_irda_handler (void) { SYS_UWORD8 interrupt_status; T_UART *uart; int uart_id; uart_id = 0; uart = &(int_uart[0]); // clear UART interrupt interrupt_status = READ_UART_REGISTER (uart, IIR) & IIR_BITS_USED; // call interrupt handler if necessary if(uart->interrupt_handler != DISABLE_UART_INTERRUPT_HANDLER) (*(uart->interrupt_handler)) (uart_id, interrupt_status); } void SER_uart_modem_handler (void) { SYS_UWORD8 interrupt_status; T_UART *uart; SYS_BOOL it_wakeup_identified; int uart_id; uart_id = 1; it_wakeup_identified = 0; uart = &(int_uart[1]); /* * Check first for a wake-up interrupt. */ interrupt_status = READ_UART_REGISTER (uart, SSR); if (interrupt_status & RX_CTS_WAKE_UP_STS) { /* Wake-up IT has occurred */ it_wakeup_identified = 1; uart_waked_up_by_interrupt = 1; DISABLE_WAKE_UP_INTERRUPT (uart); } /* * If no wake-up interrupt has been detected, check UART for other * interrupt causes. */ if (!it_wakeup_identified) { // clear UART interrupt interrupt_status = READ_UART_REGISTER (uart, IIR) & IIR_BITS_USED; if (!(interrupt_status & IT_NOT_PENDING)) (*(uart->interrupt_handler)) (uart_id, interrupt_status); else uart_modem_spurious_interrupts++; } } T_FDRET UF_Init (int uartNo) { const FD_DRV *fdDrv; int fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; fdId = serialConfigP->fdCfg[uartNo].fdId; return ((fdDrv->fd_Init)(fdId)); } T_FDRET UF_Enable (int uartNo, SYS_BOOL enable) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return((fdDrv->fd_Enable)(fdId, enable)); } short UF_SetComPar (int uartNo, T_baudrate baudrate, T_bitsPerCharacter bpc, T_stopBits sb, T_parity parity) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return((fdDrv->fd_SetComPar)(fdId, baudrate, bpc, sb, parity)); } short UF_SetBuffer (int uartNo, unsigned short bufSize, unsigned short rxThreshold, unsigned short txThreshold) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return((fdDrv->fd_SetBuffer)(fdId, bufSize, rxThreshold, txThreshold)); } short UF_SetFlowCtrl (int uartNo, T_flowCtrlMode fcMode, unsigned char XON, unsigned char XOFF) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return((fdDrv->fd_SetFlowCtrl)(fdId, fcMode, XON, XOFF)); } short UF_SetEscape (int uartNo, char escChar, unsigned short guardPeriod) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_SetEscape) (fdId, escChar, guardPeriod)); } T_FDRET UF_InpAvail (int uartNo) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_InpAvail) (fdId)); } T_FDRET UF_OutpAvail (int uartNo) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_OutpAvail) (fdId)); } short UF_EnterSleep (int uartNo) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_EnterSleep) (fdId)); } short UF_WakeUp (int uartNo) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_WakeUp) (fdId)); } short UF_ReadData (int uartNo, T_suspendMode suspend, void (readOutFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char nsource, unsigned char *source[], unsigned short size[], unsigned long state))) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_ReadData) (fdId, suspend, readOutFunc)); } short UF_WriteData (int uartNo, T_suspendMode suspend, void (writeInFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char ndest, unsigned char *dest[], unsigned short size[]))) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_WriteData) (fdId, suspend, writeInFunc)); } short UF_StopRec (int uartNo) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_StopRec) (fdId)); } short UF_StartRec (int uartNo) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_StartRec) (fdId)); } short UF_GetLineState (int uartNo, unsigned long *state) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_GetLineState) (fdId, state)); } short UF_SetLineState (int uartNo, unsigned long state, unsigned long mask) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_SetLineState) (fdId, state, mask)); } short UF_CheckXEmpty (int uartNo) { const FD_DRV *fdDrv; int fdId; fdId = serialConfigP->fdCfg[uartNo].fdId; fdDrv = serialConfigP->fdCfg[uartNo].fdDrv; return ((fdDrv->fd_CheckXEmpty) (fdId)); } /******************************************************************************* * * dummy_tr_Init * * Purpose: No action. * * Parameters: See SER_tr_Init. * * Return: none * ******************************************************************************/ static void dummy_tr_Init (int device, int baudrate, void (callback_function (void))) { /* * No action. */ } /******************************************************************************* * * dummy_tr_ReadNChars * * Purpose: No action. * * Parameters: See SER_tr_ReadNChars. * * Return: 0 * ******************************************************************************/ static unsigned long dummy_tr_ReadNChars (int device, char *buffer, unsigned long chars_to_read) { return (0); } /******************************************************************************* * * dummy_tr_ReadNBytes * * Purpose: No action. * * Parameters: See SER_tr_ReadNBytes. * * Return: 0 * ******************************************************************************/ static unsigned long dummy_tr_ReadNBytes (T_tr_UartId device, char *buffer, unsigned long chars_to_read, unsigned char *eof_detected) { return (0); } /******************************************************************************* * * dummy_tr_WriteNChars * * Purpose: No action. * * Parameters: See SER_tr_WriteNChars. * * Return: The number of character to write. * ******************************************************************************/ static unsigned long dummy_tr_WriteNChars (int device, char *buffer, unsigned long chars_to_write) { return (chars_to_write); } /******************************************************************************* * * dummy_tr_EncapsulateNChars * * Purpose: No action. * * Parameters: See SER_tr_EncapsulateNChars. * * Return: The number of character to write. * ******************************************************************************/ static unsigned long dummy_tr_EncapsulateNChars (T_tr_UartId device, char *buffer, unsigned long chars_to_write) { return (chars_to_write); } /******************************************************************************* * * dummy_tr_WriteNBytes * * Purpose: No action. * * Parameters: See SER_tr_WriteNBytes. * * Return: The number of byte to write. * ******************************************************************************/ static unsigned long dummy_tr_WriteNBytes (T_tr_UartId device, unsigned char *buffer, unsigned long chars_to_write) { return (chars_to_write); } /******************************************************************************* * * dummy_tr_WriteChar * * Purpose: No action. * * Parameters: See SER_tr_WriteChar. * * Return: none * ******************************************************************************/ static void dummy_tr_WriteChar (int device, char character) { /* * No action. */ } /******************************************************************************* * * dummy_tr_WriteString * * Purpose: No action. * * Parameters: See SER_tr_WriteString. * * Return: none * ******************************************************************************/ static void dummy_tr_WriteString (int device, char *buffer) { /* * No action. */ } /******************************************************************************* * * dummy_tr_EnterSleep * * Purpose: No action. * * Parameters: See SER_tr_EnterSleep. * * Return: 1 * ******************************************************************************/ static unsigned char dummy_tr_EnterSleep (T_tr_UartId device) { return (1); } /******************************************************************************* * * dummy_tr_WakeUp * * Purpose: No action. * * Parameters: See SER_tr_WakeUp. * * Return: none * ******************************************************************************/ static void dummy_tr_WakeUp (T_tr_UartId device) { /* * No action. */ } /******************************************************************************* * * dummy_fd_Init * * Purpose: Sets the size of the circular buffer to the maximum value and the * state of the driver to 'disabled'. * * Parameters: See SER_fd_Init. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_Init (T_fd_UartId uartNo) { fd_bufSize = FD_MAX_BUFFER_SIZE; fd_driver_enabled = 0; return (FD_OK); } /******************************************************************************* * * dummy_fd_Enable * * Purpose: Stores the state of the driver. * * Parameters: See SER_fd_Enable. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_Enable (T_fd_UartId uartNo, unsigned char enable) { fd_driver_enabled = enable; return (FD_OK); } /******************************************************************************* * * dummy_fd_SetComPar * * Purpose: No action. * * Parameters: See SER_fd_SetComPar. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_SetComPar (T_fd_UartId uartNo, T_baudrate baudrate, T_bitsPerCharacter bpc, T_stopBits sb, T_parity parity) { return (FD_OK); } /******************************************************************************* * * dummy_fd_SetBuffer * * Purpose: Stores the size of the circular buffer. * * Parameters: See SER_fd_SetBuffer. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_SetBuffer (T_fd_UartId uartNo, unsigned short bufSize, unsigned short rxThreshold, unsigned short txThreshold) { fd_bufSize = bufSize; return (FD_OK); } /******************************************************************************* * * dummy_fd_SetFlowCtrl * * Purpose: No action. * * Parameters: See SER_fd_SetFlowCtrl. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_SetFlowCtrl (T_fd_UartId uartNo, T_flowCtrlMode fcMode, unsigned char XON, unsigned char XOFF) { return (FD_OK); } /******************************************************************************* * * dummy_fd_SetEscape * * Purpose: No action. * * Parameters: See SER_fd_SetEscape. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_SetEscape (T_fd_UartId uartNo, unsigned char escChar, unsigned short guardPeriod) { return (FD_OK); } /******************************************************************************* * * dummy_fd_InpAvail * * Purpose: No action. * * Parameters: See SER_fd_InpAvail. * * Return: The size of the circular buffer. * ******************************************************************************/ static T_FDRET dummy_fd_InpAvail (T_fd_UartId uartNo) { return (fd_bufSize); } /******************************************************************************* * * dummy_fd_OutpAvail * * Purpose: No action. * * Parameters: See SER_fd_OutpAvail. * * Return: The size of the circular buffer. * ******************************************************************************/ static T_FDRET dummy_fd_OutpAvail (T_fd_UartId uartNo) { return (fd_bufSize); } /******************************************************************************* * * dummy_fd_EnterSleep * * Purpose: No action. * * Parameters: See SER_tr_EnterSleep. * * Return: 1 * ******************************************************************************/ static T_FDRET dummy_fd_EnterSleep (T_fd_UartId uartNo) { return (1); } /******************************************************************************* * * dummy_fd_WakeUp * * Purpose: No action. * * Parameters: See SER_tr_WakeUp. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_WakeUp (T_fd_UartId uartNo) { return (FD_OK); } /******************************************************************************* * * dummy_fd_ReadData * * Purpose: No action. * * Parameters: See SER_fd_ReadData. * * Return: 0 if the suspend parameter is set to 'sm_noSuspend'. * FD_SUSPENDED if the suspend parameter is set to 'sm_suspend'. * ******************************************************************************/ static T_FDRET dummy_fd_ReadData (T_fd_UartId uartNo, T_suspendMode suspend, void (readOutFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char nsource, unsigned char *source[], unsigned short size[], unsigned long state))) { T_FDRET result; if (suspend == sm_noSuspend) result = 0; else result = FD_SUSPENDED; return (result); } /******************************************************************************* * * dummy_fd_WriteData * * Purpose: The user's function is called with: * - cldFromIrq = 0 * - ndest = 1 * - dest[0] is a unsigned char pointer on the beginning address of a local * buffer * - size[0] is set to fd_bufSize. * * Parameters: See SER_fd_WriteData. * * Return: The number of bytes written in the local buffer. * ******************************************************************************/ static T_FDRET dummy_fd_WriteData (T_fd_UartId uartNo, T_suspendMode suspend, void (writeInFunc (unsigned char cldFromIrq, T_reInstMode *reInstall, unsigned char ndest, unsigned char *dest[], unsigned short size[]))) { T_reInstMode dummyInstall; unsigned char *destination[2]; unsigned short buffer_size[2]; destination[0] = &(fd_buffer[0]); buffer_size[0] = fd_bufSize; (*writeInFunc) (0, &dummyInstall, 1, &(destination[0]), &(buffer_size[0])); return ((T_FDRET) (fd_bufSize - buffer_size[0])); } /******************************************************************************* * * dummy_fd_StopRec * * Purpose: No action. * * Parameters: See SER_fd_StopRec. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_StopRec (T_fd_UartId uartNo) { return (FD_OK); } /******************************************************************************* * * dummy_fd_StartRec * * Purpose: No action. * * Parameters: See SER_fd_StartRec. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_StartRec (T_fd_UartId uartNo) { return (FD_OK); } /******************************************************************************* * * dummy_fd_GetLineState * * Purpose: Sets the RXBLEV field to the bufSize value. * * Parameters: See SER_fd_GetLineState. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_GetLineState (T_fd_UartId uartNo, unsigned long *state) { *state = fd_bufSize << RXBLEV; return (FD_OK); } /******************************************************************************* * * dummy_fd_SetLineState * * Purpose: No action. * * Parameters: See SER_fd_SetLineState. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_SetLineState (T_fd_UartId uartNo, unsigned long state, unsigned long mask) { return (FD_OK); } /******************************************************************************* * * dummy_fd_CheckXEmpty * * Purpose: No action. * * Parameters: See SER_fd_CheckXEmpty. * * Return: FD_OK: Successful operation. * ******************************************************************************/ static T_FDRET dummy_fd_CheckXEmpty (T_fd_UartId uartNo) { return (FD_OK); } /******************************************************************************* * * SER_UartSleepStatus * * Purpose: This function checks if both UARTs are ready to enter Deep Sleep. * * Parameters: In : none * Out: none * * Return: 0 : Deep Sleep is not possible. * >= 1 : Deep Sleep is possible. * ******************************************************************************/ unsigned char SER_UartSleepStatus (void) { T_UART *uart; int uart_id; SYS_BOOL status; /* * Check first if wake-up time duration is active. * A return is used to simplify the code. */ /* Wake-up duration timer has not yet expired. */ if (uart_waked_up_by_interrupt) return (0); /* * Check if both UARTs are ready to enter Deep Sleep. */ status = 1; uart_id = 0; while ((uart_id < NUMBER_OF_UART) && (status)) { uart = &(int_uart[uart_id]); /* * Check if the specified UART is actually used. */ if (uart->device_used) { /* * Check if the specified UART is used by a Trace or * by a Fax & Data flow. */ if (uart->flow_type == TRACE_FLOW) status = SER_tr_EnterSleep (uart->flow_id); else if (uart->flow_type == FAX_DATA_FLOW) status = (SYS_BOOL) SER_fd_EnterSleep (); else status = 0; if (status) { /* * The specified UART is now set up for Deep Sleep. */ uart->deep_sleep_set_up = 1; } } uart_id++; } /* * Check if Deep Sleep is finally possible. * If not revert eventual Deep Sleep settings. */ if (!status) { for (uart_id = 0; uart_id < NUMBER_OF_UART; uart_id++) { uart = &(int_uart[uart_id]); /* * If the specified used UART has already been set up for * Deep Sleep, revert these settings. */ if ((uart->device_used) && (uart->deep_sleep_set_up)) { /* * Check if the specified UART is used by a Trace or * by a Fax & Data flow. */ if (uart->flow_type == TRACE_FLOW) SER_tr_WakeUp (uart->flow_id); else /* if (uart->flow_type == FAX_DATA_FLOW) */ SER_fd_WakeUp (); uart->deep_sleep_set_up = 0; } } } return (status); } /******************************************************************************* * * SER_WakeUpUarts * * Purpose: This function wakes up used UARTs after Deep Sleep. * * Parameters: In : none * Out: none * * Return: none * ******************************************************************************/ void SER_WakeUpUarts (void) { T_UART *uart; int uart_id; if (uart_waked_up_by_interrupt) start_uart_wake_up_timer (); for (uart_id = 0; uart_id < NUMBER_OF_UART; uart_id++) { uart = &(int_uart[uart_id]); /* * Check if the specified UART is actually used, and has not yet * been waked up. */ if ((uart->device_used) && (uart->deep_sleep_set_up)) { /* * Check if the specified UART is used by a Trace or * by a Fax & Data flow. * Bluetooth HCI can not yet handled Deep Sleep Mode. */ if (uart->flow_type == TRACE_FLOW) SER_tr_WakeUp (uart->flow_id); else SER_fd_WakeUp (); /* * The specified UART is no more set up for Deep Sleep. */ uart->deep_sleep_set_up = 0; } } } #endif // end __SERIALSWITCH_C__