FreeCalypso > hg > fc-tourmaline
view src/g23m-aci/uart/uart_txf.c @ 75:8697f358f505
backlight rework: Condat light driver accepts levels
The present change is another intermediate step on the path toward
new FreeCalypso backlight handling. At this intermediate step the
Condat light driver accepts 0-255 backlight levels driven by MFW,
and puts them out on PWL on Luna development boards. At the same
time on C139 it is now possible to turn on the display backlight
with or without the keypad bl - the lsb of the 0-255 backlight level
controls the keypad bl.
MFW presently drives only 0 and 255 backlight levels, thus there is
no visible behavioral change yet - but the plan for subsequent stages
of this backlight rework is to add a dimmed backlight state
(no keypad bl on C139) during active calls.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Sat, 24 Oct 2020 20:44:04 +0000 |
parents | fa8dc04885d8 |
children |
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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 | procedures and functions as described in the | SDL-documentation (TX-statemachine) +----------------------------------------------------------------------------- */ #ifndef UART_TXF_C #define UART_TXF_C #endif /* !UART_TXF_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 */ #ifdef DTILIB #include "dti.h" /* to get dti lib */ #endif /* DTILIB */ #include "pei.h" /* to get PEI interface */ #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 */ #ifdef _SIMULATION_ #include <stdio.h> /* to get sprintf */ #endif /* _SIMULATION_ */ #include <string.h> /* JK, delete warnings: to get memcpy */ /*==== CONST ================================================================*/ /*==== LOCAL VARS ===========================================================*/ /*==== PRIVATE FUNCTIONS ====================================================*/ /*==== PUBLIC FUNCTIONS =====================================================*/ /* +------------------------------------------------------------------------------ | Function : tx_proc_output +------------------------------------------------------------------------------ | Description : The function tx_proc_output() is the actual callback function | to write data into the send buffer. | | Parameters : uart_device - database for the affected UART device | +------------------------------------------------------------------------------ */ LOCAL void tx_proc_output(T_UART_DATA* uart_device) { USHORT i, len, pos; T_DLC *dlc; /* used Data Link Connection */ UBYTE transmit_state; /* state of transmission */ T_desc2* cur_desc; /* currently used descriptor */ UBYTE temp_field; /* multi purpose value */ UBYTE frame_size; /* numbr of octets in Information field */ UBYTE fcs; /* Frame Check Sequence */ SHORT error_code; /* Error code returned from a function */ TRACE_FUNCTION( "tx_proc_output" ); if(uart_device->tx.dlc_instance EQ UART_EMPTY_INSTANCE) { /* * Raw Data */ /* * use entry 0 for raw data */ dlc = &uart_device->dlc_table[UART_CONTROL_INSTANCE]; cur_desc = dlc->transmit_data; /* * search next descriptor that includes data */ while((cur_desc) && (dlc->transmit_pos >= cur_desc->len)) { cur_desc = (T_desc2*)cur_desc->next; dlc->transmit_pos = 0; } /* * for each ring buffer segment */ for (i=0; i < uart_device->tx.ndest; i++) { pos = 0; /* * while ring buffer segment is not yet full and * there are still data to send */ while((uart_device->tx.size[i] > 0) && (cur_desc)) { /* * determine length to copy */ len = cur_desc->len - dlc->transmit_pos; if(len > uart_device->tx.size[i]) len = uart_device->tx.size[i]; /* * copy data */ memcpy((char*) &uart_device->tx.dest[i][pos], (char*) &cur_desc->buffer[dlc->transmit_pos], len); /* * updata values */ uart_device->tx.size[i]-= len; dlc->transmit_pos += len; pos += len; /* * if current descriptor completly send * then move to next descriptor */ while((cur_desc) && (dlc->transmit_pos >= cur_desc->len)) { cur_desc = (T_desc2*)cur_desc->next; dlc->transmit_pos = 0; } } } } else { /* * Multiplexer Data */ dlc = &uart_device->dlc_table[uart_device->tx.dlc_instance]; cur_desc = dlc->transmit_data; temp_field = 0; /* * search next descriptor that includes data */ while((cur_desc) && (dlc->transmit_pos >= cur_desc->len)) { cur_desc = (T_desc2*)cur_desc->next; dlc->transmit_pos = 0; } if(cur_desc) { /* * initiailze destination values */ i = 0; while((i < uart_device->tx.ndest) && (uart_device->tx.size[i] EQ 0)) { i++; } pos = 0; /* * send start HDLC Flag */ uart_device->tx.dest[i][pos] = UART_HDLC_FLAG; fcs = UART_INITFCS; transmit_state = UART_TX_ADDRESS; frame_size = 0; /* * increase destination position */ pos++; uart_device->tx.size[i]--; while((i < uart_device->tx.ndest) && (uart_device->tx.size[i] EQ 0)) { pos = 0; i++; } while(transmit_state NEQ UART_TX_END) { switch(transmit_state) { case UART_TX_ADDRESS: /* * send Address field */ if(uart_device->tx.dlc_instance EQ UART_CONTROL_INSTANCE) { /* * at Control Channel the address field * is included in source data */ temp_field = cur_desc->buffer[dlc->transmit_pos]; /* * if current descriptor completly send * then move to next descriptor */ dlc->transmit_pos++; while((cur_desc) && (dlc->transmit_pos >= cur_desc->len)) { cur_desc = (T_desc2*)cur_desc->next; dlc->transmit_pos = 0; } } else { /* * at Data Channel the address field * is calculated with the DLCI */ temp_field = (dlc->dlci << UART_DLCI_POS) | UART_EA; } /* * calculate FCS */ fcs = uart_device->fcstab[fcs ^ temp_field]; /* * next field is Control field */ transmit_state = UART_TX_CONTROL; break; case UART_TX_CONTROL: /* * send Control field */ if(uart_device->tx.dlc_instance EQ UART_CONTROL_INSTANCE) { /* * at Control Channel the control field * is included in source data */ temp_field = cur_desc->buffer[dlc->transmit_pos]; /* * if current descriptor completly send * then move to next descriptor */ dlc->transmit_pos++; while((cur_desc) && (dlc->transmit_pos >= cur_desc->len)) { cur_desc = (T_desc2*)cur_desc->next; dlc->transmit_pos = 0; } } else { /* * at Data Channel the control field * is always an UIH frame with P/F bit set to 0 */ temp_field = UART_UIH_DATA_FRAME; } /* * calculate FCS */ fcs = uart_device->fcstab[fcs ^ temp_field]; /* * if there are still data to send the * next field is Information field * otherwise next field is FCS field */ if(cur_desc) transmit_state = UART_TX_INFORMATION; else transmit_state = UART_TX_FCS; break; case UART_TX_INFORMATION: /* * send Information field */ temp_field = cur_desc->buffer[dlc->transmit_pos]; /* * check if there is still data in the current descriptor and * the maximum frame size is not yet reached */ dlc->transmit_pos++; frame_size++; if((frame_size >= uart_device->n1) || (dlc->transmit_pos >= cur_desc->len)) { /* * if current descriptor completly send * then move to next descriptor */ while((cur_desc) && (dlc->transmit_pos >= cur_desc->len)) { cur_desc = (T_desc2*)cur_desc->next; dlc->transmit_pos = 0; } /* * if no more data to send available or * maximum frame size is reached then * the next field is FCS field */ if((frame_size >= uart_device->n1) || (cur_desc EQ NULL)) transmit_state = UART_TX_FCS; } break; case UART_TX_FCS: /* * send FCS field */ #ifdef _SIMULATION_ /* * clear FCS field in simulation mode */ temp_field = UART_GOODFCS; #else /* _SIMULATION_ */ temp_field = (0xff - fcs); #endif /* _SIMULATION_ */ /* * frame complete */ transmit_state = UART_TX_END; break; default: TRACE_EVENT_P1("Warning: Unexpected TX ISR state %d", transmit_state); break; } if((temp_field EQ UART_HDLC_FLAG) || (temp_field EQ UART_HDLC_ESCAPE) || (temp_field EQ uart_device->xon) || (temp_field EQ uart_device->xoff)) { /* * send Control Escape and map character */ /*lint -e661 (Warning -- access of out-of-bounds pointer) */ uart_device->tx.dest[i][pos] = UART_HDLC_ESCAPE; /*lint +e661 (Warning -- access of out-of-bounds pointer) */ temp_field ^= 0x20; /* * increase destination position */ pos++; uart_device->tx.size[i]--; while((i < uart_device->tx.ndest) && (uart_device->tx.size[i] EQ 0)) { pos = 0; i++; } } /* * send character */ /*lint -e661 -e662 (Warning -- access/creation of out-of-bounds pointer) */ uart_device->tx.dest[i][pos] = temp_field; /*lint +e661 +e662 (Warning -- access/creation of out-of-bounds pointer) */ /* * increase destination position */ pos++; uart_device->tx.size[i]--; while((i < uart_device->tx.ndest) && (uart_device->tx.size[i] EQ 0)) { pos = 0; i++; } } /* * send stop HDLC Flag */ /*lint -e661 -e662 (Warning -- access/creation of out-of-bounds pointer) */ uart_device->tx.dest[i][pos] = UART_HDLC_FLAG; /*lint +e661 +e662 (Warning -- access/creation of out-of-bounds pointer) */ /* * update size value */ uart_device->tx.size[i]--; } } /* * write current descriptor back to table */ dlc->transmit_data = cur_desc; #ifndef _SIMULATION_ PSIGNAL(hCommUART, UART_DRIVER_SENT_IND, uart_device); #endif /* !_SIMULATION_ */ *uart_device->tx.reInstall = rm_noInstall; /* * update pointer in UART driver */ if((error_code = UF_OutpAvail (uart_device->device)) < 0) { TRACE_ERROR_P2("UF Driver: data pointer update failed, [%d], uart_txf.c(%d)", error_code, __LINE__); } } /* tx_proc_output() */ /* +------------------------------------------------------------------------------ | Function : tx_init +------------------------------------------------------------------------------ | Description : The function tx_init() initializes the TX service. | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void tx_init () { #ifndef _SIMULATION_ #ifdef WIN32 #ifndef _TARGET_ char buf[80]; #endif /* !_TARGET_ */ STATUS sts; #endif /* WIN32 */ #endif /* !_SIMULATION_ */ TRACE_FUNCTION( "tx_init" ); #ifndef _SIMULATION_ #ifdef WIN32 sts = NU_Create_HISR (&uart_data->tx.tx_HISR, "TX_HISR", tx_proc_output, 2, uart_data->HISR_stack, HISR_STACK_SIZE); #ifndef _TARGET_ sprintf (buf, "NU_Create_HISR(TX) = %d", sts); TRACE_EVENT (buf); #endif /* !_TARGET_ */ #endif /* WIN32 */ #endif /* !_SIMULATION_ */ uart_data->tx.lines = 0x80000000; /* invalid */ uart_data->tx.dlc_instance = UART_EMPTY_INSTANCE; uart_data->tx.p_zero = 0; uart_data->tx.send_state = UART_TX_NOT_SENDING; INIT_STATE( UART_SERVICE_TX , TX_DEAD ); } /* tx_init() */ /* +------------------------------------------------------------------------------ | Function : tx_flushUart +------------------------------------------------------------------------------ | Description : The function tx_flushUart() flush the output buffer of the | UART driver. | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void tx_flushUart () { #ifndef _TARGET_ USHORT oa; /* output available */ #endif /* !_TARGET_ */ #ifndef ALR T_UFRET mt; #endif /* ALR */ USHORT counter; TRACE_FUNCTION( "tx_flushUart" ); counter = 0; while( #ifndef ALR ((mt = UF_CheckXEmpty(uart_data->device)) == UF_NOT_READY) || #endif /* !ALR */ (UF_OutpAvail (uart_data->device) < UF_MAX_BUFFER_SIZE)) { #ifndef _TARGET_ oa = UF_OutpAvail (uart_data->device); TRACE_EVENT_P1("waiting - output not flushed oa:%d",oa); #endif /* !_TARGET_ */ /* * poll permanent in the first 500ms * after that poll 1 minute only every second * after that give up */ if(counter < 50) { if(vsi_t_sleep (VSI_CALLER ONE_FRAME) NEQ VSI_OK) { TRACE_ERROR_P1("VSI entity: Can't suspend thread, uart_txf.c(%d)", __LINE__); } } else if(counter < 110) { if(vsi_t_sleep (VSI_CALLER 1000) NEQ VSI_OK) { TRACE_ERROR_P1("VSI entity: Can't suspend thread, uart_txf.c(%d)", __LINE__); } } else { break; } counter++; } } /* tx_flushUart() */ /* +------------------------------------------------------------------------------ | Function : tx_next_send_allowed +------------------------------------------------------------------------------ | Description : The function tx_next_send_allowed() determines which dlc is the | next dlc allow to send. The result of the calculation is stored | in dlc_instance. | | Parameters : no parameters | +------------------------------------------------------------------------------ */ GLOBAL void tx_next_send_allowed () { UBYTE diff; UBYTE inst; UBYTE next_inst; T_DLC* dlc; TRACE_FUNCTION( "tx_next_send_allowed" ); diff = 255; next_inst = UART_EMPTY_INSTANCE; for(inst = 0; inst <= UART_MAX_NUMBER_OF_CHANNELS; inst++) { dlc = &uart_data->dlc_table[inst]; if(dlc->transmit_data) { if(dlc->p_counter EQ uart_data->tx.p_zero) { uart_data->tx.dlc_instance = inst; return; } if(diff > (dlc->p_counter - uart_data->tx.p_zero)) { diff = dlc->p_counter - uart_data->tx.p_zero; next_inst = inst; } } } uart_data->tx.p_zero+= diff; uart_data->tx.dlc_instance = next_inst; } /* tx_next_send_allowed() */ /* +------------------------------------------------------------------------------ | Function : tx_writeInFunc_0 +------------------------------------------------------------------------------ | Description : The function tx_writeInFunc_0() is the official callback | function to write data into the send buffer of UART device 0. | It just copies the parameters and calls then the actual | function. | | Parameters : cldFromIrq - called from interrupt | reInstall - reinstallation mode | ndest - number of destination pointers | dest - array of destination pointers | size - array of sizes for every destinition pointer | +------------------------------------------------------------------------------ */ GLOBAL void tx_writeInFunc_0 (BOOL cldFromIrq, T_reInstMode *reInstall, UBYTE ndest, UBYTE *dest[], USHORT *size) { #ifndef _SIMULATION_ #ifndef _TARGET_ char buf[40]; #endif /* !_TARGET_ */ #endif /* !_SIMULATION_ */ T_UART_DATA* uart_device; TRACE_FUNCTION( "tx_writeInFunc_0" ); /* * select UART device 0 */ uart_device = &(uart_data_base[0]); /* * store parameters */ uart_device->tx.cldFromIrq = cldFromIrq; uart_device->tx.ndest = ndest; uart_device->tx.dest[0] = dest[0]; uart_device->tx.dest[1] = dest[1]; uart_device->tx.size = size; uart_device->tx.reInstall = reInstall; #ifndef _SIMULATION_ #ifdef WIN32 if (cldFromIrq) { STATUS sts; /* * interrupt context of the UART driver -> activate the HISR */ sts = NU_Activate_HISR (&uart_device->tx.tx_HISR); #ifndef _TARGET_ sprintf (buf, "NU_Activate_HISR(TX) = %d", sts); TRACE_EVENT (buf); #endif /* !_TARGET_ */ } else #endif /* WIN32 */ #endif /* !_SIMULATION_ */ { /* * normal callback from UF_WriteData */ tx_proc_output(uart_device); #ifdef _SIMULATION_ { /* * trace output */ UBYTE* trace_dest[2]; USHORT trace_size[2]; USHORT i; USHORT pos; char buf[90]; trace_dest[0] = dest[0]; trace_dest[1] = dest[1]; trace_size[0] = size[0]; trace_size[1] = size[1]; trace_size[0]-= uart_device->tx.size[0]; trace_size[1]-= uart_device->tx.size[1]; if((trace_size[0]) || (trace_size[1])) { TRACE_EVENT("=== OUTRAW"); i = 0; pos = 0; while(pos < trace_size[0]) { i+= sprintf(&buf[i], "0x%02x, ", trace_dest[0][pos]); pos++; if(i > 80) { TRACE_EVENT( buf ); i = 0; } else if(pos >= trace_size[0]) { TRACE_EVENT( buf ); } } i = 0; pos = 0; while(pos < trace_size[1]) { i+= sprintf(&buf[i], "0x%02x, ", trace_dest[1][pos]); pos++; if(i > 80) { TRACE_EVENT( buf ); i = 0; } else if(pos >= trace_size[1]) { TRACE_EVENT( buf ); } } } } #endif /* _SIMULATION_ */ } } /* tx_writeInFunc_0() */ #ifdef FF_TWO_UART_PORTS /* +------------------------------------------------------------------------------ | Function : tx_writeInFunc_1 +------------------------------------------------------------------------------ | Description : The function tx_writeInFunc_1() is the official callback | function to write data into the send buffer of UART device 0. | It just copies the parameters and calls then the actual | function. | | Parameters : cldFromIrq - called from interrupt | reInstall - reinstallation mode | ndest - number of destination pointers | dest - array of destination pointers | size - array of sizes for every destinition pointer | +------------------------------------------------------------------------------ */ GLOBAL void tx_writeInFunc_1 (BOOL cldFromIrq, T_reInstMode *reInstall, UBYTE ndest, UBYTE *dest[], USHORT *size) { #ifndef _SIMULATION_ #ifndef _TARGET_ char buf[40]; #endif /* !_TARGET_ */ #endif /* !_SIMULATION_ */ T_UART_DATA* uart_device; TRACE_FUNCTION( "tx_writeInFunc_1" ); /* * select UART device 1 */ uart_device = &(uart_data_base[1]); /* * store parameters */ uart_device->tx.cldFromIrq = cldFromIrq; uart_device->tx.ndest = ndest; uart_device->tx.dest[0] = dest[0]; uart_device->tx.dest[1] = dest[1]; uart_device->tx.size = size; uart_device->tx.reInstall = reInstall; #ifndef _SIMULATION_ #ifdef WIN32 if (cldFromIrq) { STATUS sts; /* * interrupt context of the UART driver -> activate the HISR */ sts = NU_Activate_HISR (&uart_device->tx.tx_HISR); #ifndef _TARGET_ sprintf (buf, "NU_Activate_HISR(TX) = %d", sts); TRACE_EVENT (buf); #endif /* !_TARGET_ */ } else #endif /* WIN32 */ #endif /* !_SIMULATION_ */ { /* * normal callback from UF_WriteData */ tx_proc_output(uart_device); #ifdef _SIMULATION_ { /* * trace output */ UBYTE* trace_dest[2]; USHORT trace_size[2]; USHORT i; USHORT pos; char buf[90]; trace_dest[0] = dest[0]; trace_dest[1] = dest[1]; trace_size[0] = size[0]; trace_size[1] = size[1]; trace_size[0]-= uart_device->tx.size[0]; trace_size[1]-= uart_device->tx.size[1]; if((trace_size[0]) || (trace_size[1])) { TRACE_EVENT("=== OUTRAW"); i = 0; pos = 0; while(pos < trace_size[0]) { i+= sprintf(&buf[i], "0x%02x, ", trace_dest[0][pos]); pos++; if(i > 80) { TRACE_EVENT( buf ); i = 0; } else if(pos >= trace_size[0]) { TRACE_EVENT( buf ); } } i = 0; pos = 0; while(pos < trace_size[1]) { i+= sprintf(&buf[i], "0x%02x, ", trace_dest[1][pos]); pos++; if(i > 80) { TRACE_EVENT( buf ); i = 0; } else if(pos >= trace_size[1]) { TRACE_EVENT( buf ); } } } } #endif /* _SIMULATION_ */ } } /* tx_writeInFunc_1() */ #endif /* FF_TWO_UART_PORTS */ #endif /* !FF_MULTI_PORT */