IsrInfoSeg MACRO ;******************************************************************************** ; Interrupt Service Routine ;******************************************************************************** ; Updated 19 November 1999 - Nick Kelsey ; * Fixed fault in IrdaTxData and UartTxData where the stop bit was one ; interrupt cycle too long. ; Updated 6 December 1999 - Nick Kelsey ; * Added RTS/CTS defines for debug UART. ;******************************************************************************** ENDM IsrDataSeg MACRO ;******************************************************************************** ; Interrupt Service Routine ;******************************************************************************** org $10 IsrBank = $10 IsrTime50MHz = -108 ;50Mhz * 2.17us = 108.5 IsrTime = IsrTime50MHz ;Constant = MHz * 2.17us ;**** Isr **** IsrMReg ds 1 IsrIntFlags ds 1 ;**** IsrStatus **** (Global varible providing an interface to the Isr) TimerOverflow = IsrStatus.0 IrdaTxStart = IsrStatus.1 IrdaTxEmpty = IsrStatus.2 ;1 = finished sending byte IrdaRxAvail = IsrStatus.3 ;1 = received byte available to be read UartTxStart = IsrStatus.4 UartTxEmpty = IsrStatus.5 UartRxAvail = IsrStatus.6 ;1 = received byte available to be read DebugSend = UartTxStart ;**** Irda & Uart Status **** IrdaUartStatus ds 1 IrdaRxPulse = IrdaUartStatus.0 IrdaRxMode = IrdaUartStatus.1 ;1 = currently receiving a byte, 0 = idle IrdaTxMode = IrdaUartStatus.2 ;1 = currently transmitting a byte, 0 = idle UartRxMode = IrdaUartStatus.3 ;1 = currently receiving a byte, 0 = idle UartTxMode = IrdaUartStatus.4 ;1 = currently transmitting a byte, 0 = idle ;**** Irda **** IrdaTxPin = rb.7 ;Output - Idle Low IrdaRxPin = rb.6 ;Input - Idle High IrdaRxInt = 6 ;Interrupt = bit 6 Irda9600 = 48 ;+0.47% Irda19200 = 24 ;+0.47% Irda38400 = 12 ;+0.47% Irda57600 = 8 ;+0.47% Irda115200 = 4 ;+0.47% IrdaSpeed ds 1 IrdaData ds 1 IrdaRxBits ds 1 IrdaBitCount ds 1 IrdaDivide ds 1 ;**** Uart **** UartTxPin = rb.2 ;Output - Idle High UartRxPin = rb.0 ;Input - Idle High UartRtsPin = rb.1 ;Output UartCtsPin = rb.3 ;Input Uart9600 = 48 ;+0.47% Uart19200 = 24 ;+0.47% Uart38400 = 12 ;+0.47% Uart57600 = 8 ;+0.47% Uart115200 = 4 ;+0.47% UartSpeed = Uart115200 UartTxData = DebugData ;Global Variable UartTxBits ds 1 UartTxBitCount ds 1 UartTxDivide ds 1 UartRxData ds 1 UartRxBits ds 1 UartRxBitCount ds 1 UartRxDivide ds 1 org $30 TimerBank = $30 ;Shared with Framing layer Random ds 1 ;Increments every timer interrupt (108 cycles @ 50MHz) Timer1 ds 1 ;Resetable, Increments every timer interrupt (108 cycles @ 50MHz) Timer2 ds 1 ;Resetable, Increments every Timer1 overflow (27648 cycles @ 50MHz) Timer3 ds 1 ;Resetable, Increments every Timer2 overflow (7077888 cycles @ 50MHz) ;******************************************************************************** ENDM IsrCodeSeg MACRO ;******************************************************************************** ; Interrupt Service Routine ;******************************************************************************** GlobalIsr ;Interrupt = Timer bank TimerBank inc Random ;1 Random increment (Note: The main code is synchronous with RTCC and so RTCC is not a random number) inc Timer1 ;1 Timer: increment snz ;1/2 Timer: overflow ? inc Timer2 ;1 Timer: Yes => increment snz ;1/2 Timer: overflow ? inc Timer3 ;1 Timer: Yes => increment snz ;1/2 Timer: overflow ? setb TimerOverflow ;1 Timer: Yes => set flag (Timer = 7 cycles) bank IsrBank ;1 mov IsrMReg, m ;2 Backup M register mov m, #WKPND ;1 Set mode to examine port b interrupt flags mov w, #0 ;1 Clear W mov !rb, w ;1 Swap contents of W and WKPEN_B (interrupt flags are cleared) mov IsrIntFlags, w ;1 Store cause of interrupt IrdaIsr ; Irda -> IrdaRet: Idle = 6 cycles, Tx = 9/19/23 cycles, Rx = 12/21/27 cycles, RxStart = 18 cycles snb IrdaTxMode ;1/2 Irda Tx ? jmp IrdaTxDataIsr ;3 Yes => IrdaTxDataIsr snb IrdaTxStart ;1/2 Irda Tx ? jmp IrdaTxStartIsr ;3 Yes => IrdaTxStartIsr snb IrdaRxMode ;1/2 Irda Rx ? jmp IrdaRxDataIsr ;3 Yes => IrdaRxDataIsr snb IsrIntFlags.IrdaRxInt ;1/2 Falling edge of Rx pin indicating start bit ? jmp IrdaRxStartIsr ;3 Yes => IrdaRxStartIsr IrdaRet ; Irda -> IrdaRet: Idle = 6 cycles, Tx = 9/19/23 cycles, Rx = 12/21/27 cycles, RxStart = 18 cycles UartTxIsr snb UartTxMode ;1/2 Transmitting ? jmp UartTxDataIsr ;3 Yes => UartTxDataIsr snb UartTxStart ;1/2 Start transmit ? jmp UartTxStartIsr ;3 Yes => UartTxStartIsr UartTxRet UartRxIsr snb UartRxMode ;1/2 Receiving ? jmp UartRxDataIsr ;3 Yes => UartRxDataIsr sb UartRxPin ;1/2 Start bit ? (start bit = 0) jmp UartRxStartIsr ;3 Yes => UartRxStartIsr UartRxRet mov m, IsrMReg ;2 Restore M register mov w, #IsrTime ;1 Interrupt in 108 @ 50Mhz cycles retiw ;3 Total Isr Time = x cycles IrdaTxDataIsr ; Time = 5/13/16/20 cycles clrb IrdaTxPin ;1 return to idle decsz IrdaDivide ;1/2 jmp IrdaRet ;3 Isr Time = +5 cycles from IrdaTxIsr decsz IrdaBitCount ;1/2 Sent all bits? jmp :Bit ;3 No => output next bit :End snb IrdaTxStart ;1/2 Yes => complete, Another byte to transmit? jmp IrdaTxStartIsr ;3 Yes => IrdaTxStartIsr clrb IrdaTxMode ;1 Finished setb IrdaTxEmpty ;1 Flag to indicate that the transmission is complete clrb ledTX ;1 Turn off TX LED (indication LED not actual IR emitter) jmp IrdaRet ;3 Isr Time = +19 cycles from IrdaTxIsr :Bit sb IrdaData.0 ;1/2 Output next bit setb IrdaTxPin ;1 Output next bit stc ;1 Stop bit (idle = 1) rr IrdaData ;1 mov IrdaDivide, IrdaSpeed ;2 Apply baud rate jmp IrdaRet ;3 Isr Time = +16 cycles from IrdaTxIsr IrdaTxStartIsr clrb IrdaTxStart ;1 Clear start mode setb ledTX ;1 Turn on TX LED (indication LED not actual IR emitter) setb IrdaTxPin ;1 Output start pulse (note position of this instruction is such that it matches the setb of the TxDataIsr) mov IrdaDivide, IrdaSpeed ;2 Apply baud rate mov IrdaBitCount, #10 ;2 Bit count = 8 data + 1 stop + 1 for stop bit to complete setb IrdaTxMode ;1 Enter Tx mode jmp IrdaRet ;3 Isr Time = +n cycles IrdaRxDataIsr ; Time = 4/13/19 cycles snb IsrIntFlags.IrdaRxInt ;1/2 Was a pulse received ? setb IrdaRxPulse ;1 Yes => Flag pulse decsz IrdaDivide ;1/2 jmp IrdaRet ;3 Isr Time = +4 cycles from IrdaRxIsr clc ;1 Determine bit sb IrdaRxPulse ;1/2 Determine bit stc ;1 Determine bit rr IrdaRxBits ;1 Record bit clrb IrdaRxPulse ;1 Reset pulse flag mov IrdaDivide, IrdaSpeed ;2 Apply baud rate decsz IrdaBitCount ;1/2 jmp IrdaRet ;3 Isr Time = +13 cycles from IrdaRxIsr mov IrdaData, IrdaRxBits ;2 Copy bits into IrdaData clrb IrdaRxMode ;1 Finished setb IrdaRxAvail ;1 clrb ledRX ;1 Turn off RX LED (indication LED not actual IR emitter) jmp IrdaRet ;3 Isr Time = +19 cycles from IrdaRxIsr IrdaRxStartIsr ; Time = 10 cycles setb ledRX ;1 Turn on RX LED (indication LED not actual IR emitter) clc ;1 mov w, >>IrdaSpeed ;1 W = IrdaSpeed / 2 mov IrdaDivide, w ;1 IrdaDivide = IrdaSpeed * 0.5 mov IrdaBitCount, #9 ;2 Bit count = 9 (1/2 start, 8 data, ignore stop) setb IrdaRxMode ;1 Enter rx mode jmp IrdaRet ;3 Isr Time = +10 cycles from IrdaRxStartIsr UartTxDataIsr ; Time = 4/11/17 cycles decsz UartTxDivide ;1/2 jmp UartTxRet ;3 Isr Time = +n cycles from UartTxIsr decsz UartTxBitCount ;1/2 Sent all bits? jmp :Bit ;3 No => output next bit :End snb UartTxStart ;1/2 Yes => complete, Another byte to transmit? jmp UartTxStartIsr ;3 Yes => UartTxStartIsr clrb UartTxMode ;1 No => Complete setb UartTxEmpty ;1 Flag to indicate that the transmission is complete jmp UartTxRet ;3 Complete :Bit movb UartTxPin, UartTxBits.0 ;4 Output next bit stc ;1 Stop bit (idle = 1) rr UartTxBits ;1 mov UartTxDivide, #UartSpeed ;2 Apply UartSpeed jmp UartTxRet ;3 Isr Time = +n cycles from UartTxIsr UartTxStartIsr clrb UartTxPin ;1 Output start bit mov UartTxBits, UartTxData ;2 Load data for transmission mov UartTxDivide, #UartSpeed ;2 Apply UartSpeed mov UartTxBitCount, #10 ;2 Bit count = 8 data + 1 stop + 1 for stop bit to complete clrb UartTxStart ;1 Clear start mode setb UartTxMode ;1 Enter Tx mode jmp UartTxRet ;3 Isr Time = +n cycles UartRxDataIsr decsz UartRxDivide ;1/2 jmp UartRxRet ;3 Isr Time = +n cycles decsz UartRxBitCount ;1/2 jmp :Read ;3 :Stop mov UartRxData, UartRxBits ;2 Copy bits into UartData clrb UartRxMode ;1 Finished setb UartRxAvail ;1 jmp UartRxRet ;3 Isr Time = +n cycles :Read clc ;1 Determine bit snb UartRxPin ;1/2 Determine bit stc ;1 Determine bit rr UartRxBits ;1 Record bit mov UartRxDivide, #UartSpeed ;2 Apply baud rate jmp UartRxRet ;3 Isr Time = +n cycles UartRxStartIsr mov UartRxDivide, #UartSpeed / 2 ;2 UartDivide = UartSpeed * 0.5 mov UartRxBitCount, #10 ;2 Bit count = 10 (1/2 start, 8 data, 1 stop) setb UartRxMode ;1 Enter rx mode jmp UartRxRet ;3 Isr Time = +n cycles IsrInit clr IsrStatus bank IsrBank clr IrdaUartStatus mov IrdaSpeed, #Irda9600 mov !option, #%10011111 ;enable rtcc interrupt retp ;******************************************************************************** ENDM
file: /Techref/scenix/lib/io/osi2/ir/da/ISR.SRC, 9KB, , updated: 1999/12/6 14:37, local time: 2024/11/15 20:27,
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