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|
;********************************************************
; *
; Filename: f767duino.asm *
; Date: 20061016 *
; File Version: 0.6 *
; Fixed a bug in receive interrupt handler and *
; buffer increment *
; Date: 20061012 *
; File Version: 0.5 *
; Using shadow registers for tris *
; registers to avoid bcf and bsf instructions *
; Date: 20061012 *
; File Version: 0.4 *
; Fixed another bug. Digital out still doesn't *
; work. Next try using shadow registers for tris *
; registers to avoid bcf and bsf instructions *
; Date: 20061011 *
; File Version: 0.3 *
; fixed a couple of bugs. Now analog input works *
; Date: 20060927 *
; File Version: 0.2 *
; completed port to PIC asm *
; Date: 20060921 *
; File Version: 0.1 *
; *
; Author: Martin Peach *
; *
; *
;********************************************************
; *
; Files required: P16F767.INC *
; *
; *
;************************************************************************************************
; *
; This is an implementation of the Arduino using a PIC16F767 instead of an ATmega8. *
; See PICduino.CKT for the schematic. *
; *
;************************************************************************************************
;___Arduino_Pin_Name____=___PIC_Pin_Name____*
; DigitalPin0 RXD = RC7 *
; DigitalPin1 TXD = RC6 *
; DigitalPin2 = RC5 *
; DigitalPin3 = RC4 *
; DigitalPin4 = RC3 *
; DigitalPin5 = RB0 *
; DigitalPin6 = RB4 *
; DigitalPin7 = RB7 *
; DigitalPin8 = RB6 *
; DigitalPin9 PWM = RB5 *
; DigitalPin10 PWM = RC2 *
; DigitalPin11 PWM = RC1 *
; DigitalPin12 = RC0 *
; DigitalPin13 = RB1 *
; AnalogInput0 = RA0/AN0 *
; AnalogInput1 = RA1/AN1 *
; AnalogInput2 = RA2/AN2 *
; AnalogInput3 = RA5/AN4 *
; AnalogInput4 = RB2/AN8 *
; AnalogInput5 = RB3/AN9 *
; VRef = RA3/AN3 *
; *
; Timing parameters:
; FOsc = 14745600Hz
; TOsc = 67.8ns
; Tad = 2.17us, Tcnv = 26.04us
; ADC needs 20us (~10Tad) to charge the sampling capacitor + 2Tad(~5us) after each conversion
;********************************************
; This is based on Pd_firmware_pde
; Copyright (C) 2006 Hans-Christoph Steiner
; This library is free software; you can redistribute it and/or
; modify it under the terms of the GNU Lesser General Public
; License as published by the Free Software Foundation; either
; version 2.1 of the License, or (at your option) any later version.
;
; This library is distributed in the hope that it will be useful,
; but WITHOUT ANY WARRANTY; without even the implied warranty of
; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
; Lesser General Public License for more details.
;
; You should have received a copy of the GNU Lesser General
; Public License along with this library; if not, write to the
; Free Software Foundation, Inc., 59 Temple Place, Suite 330,
; Boston, MA 02111-1307 USA
;
; -----------------------------
; Firmata, the Arduino firmware
; -----------------------------
;
; Firmata turns the Arduino into a Plug-n-Play sensorbox, servo
; controller, and/or PWM motor/lamp controller.
;
; It was originally designed to work with the Pd object [arduino]
; which is included in Pd-extended. This firmware is intended to
; work with any host computer software package. It can easily be
; used with other programs like Max/MSP, Processing, or whatever can
; do serial communications.;
; @authors: Hans-Christoph Steiner <hans@at.or.at>
; help with protocol redesign: Jamie Allen <jamie@heavyside.net>
; key bugfixes: Georg Holzmann <grh@mur.at>
; Gerda Strobl <gerda.strobl@student.tugraz.at>
; @date: 2006-05-19
; @locations: STEIM, Amsterdam, Netherlands
; IDMI/Polytechnic University, Brookyn, NY, USA
; Electrolobby Ars Electronica, Linz, Austria
;
;
; TODO: add pulseIn functionality
; TODO: add software PWM for servos, etc (servo.h or pulse.h)
; TODO: redesign protocol to accomodate boards with more I/Os
; TODO:
; TODO: add "outputMode all 0/1" command
; TODO: add cycle markers to mark start of analog, digital, pulseIn, and PWM
;
; =========================================================================
list p=16f767 ; list directive to define processor
#include <P16F767.inc> ; processor specific variable definitions
__CONFIG _CONFIG1, _CP_OFF & _CCP2_RC1 & _DEBUG_OFF & _VBOR_2_0 & _BOREN_0 & _MCLR_ON & _PWRTE_ON & _WDT_OFF & _HS_OSC
__CONFIG _CONFIG2, _BORSEN_0 & _IESO_OFF & _FCMEN_OFF
; === CONSTANTS ===========================================================
B19200 equ d'47' ; time constant for baud rate generator
B9600 equ d'95' ; time constant for baud rate generator
; firmware version numbers. The protocol is still changing, so these version
; numbers are important
MAJOR_VERSION equ 0
MINOR_VERSION equ 1
; firmata protocol
; ===============
; data: 0-127
; control: 128-255
; computer->Arduino commands
; --------------------
; 128-129 UNUSED
SET_PIN_ZERO_TO_IN equ d'130' ; set digital pin 0 to INPUT
SET_PIN_ONE_TO_IN equ d'131' ; set digital pin 1 to INPUT
SET_PIN_TWO_TO_IN equ d'132' ; set digital pin 2 to INPUT
SET_PIN_THREE_TO_IN equ d'133' ; set digital pin 3 to INPUT
SET_PIN_FOUR_TO_IN equ d'134' ; set digital pin 4 to INPUT
SET_PIN_FIVE_TO_IN equ d'135' ; set digital pin 5 to INPUT
SET_PIN_SIX_TO_IN equ d'136' ; set digital pin 6 to INPUT
SET_PIN_SEVEN_TO_IN equ d'137' ; set digital pin 7 to INPUT
SET_PIN_EIGHT_TO_IN equ d'138' ; set digital pin 8 to INPUT
SET_PIN_NINE_TO_IN equ d'139' ; set digital pin 9 to INPUT
SET_PIN_TEN_TO_IN equ d'140' ; set digital pin 10 to INPUT
SET_PIN_ELEVEN_TO_IN equ d'141' ; set digital pin 11 to INPUT
SET_PIN_TWELVE_TO_IN equ d'142' ; set digital pin 12 to INPUT
SET_PIN_THIRTEEN_TO_IN equ d'143' ; set digital pin 13 to INPUT
; 144-149 UNUSED
DISABLE_DIGITAL_INPUTS equ d'150' ; disable reporting of digital inputs
ENABLE_DIGITAL_INPUTS equ d'151' ; enable reporting of digital inputs
; 152-159 UNUSED
ZERO_ANALOG_INS equ d'160' ; disable reporting on all analog ins
ONE_ANALOG_IN equ d'161' ; enable reporting for 1 analog in (0)
TWO_ANALOG_INS equ d'162' ; enable reporting for 2 analog ins (0,1)
THREE_ANALOG_INS equ d'163' ; enable reporting for 3 analog ins (0-2)
FOUR_ANALOG_INS equ d'164' ; enable reporting for 4 analog ins (0-3)
FIVE_ANALOG_INS equ d'165' ; enable reporting for 5 analog ins (0-4)
SIX_ANALOG_INS equ d'166' ; enable reporting for 6 analog ins (0-5)
; 167-199 UNUSED
SET_PIN_ZERO_TO_OUT equ d'200' ; set digital pin 0 to OUTPUT
SET_PIN_ONE_TO_OUT equ d'201' ; set digital pin 1 to OUTPUT
SET_PIN_TWO_TO_OUT equ d'202' ; set digital pin 2 to OUTPUT
SET_PIN_THREE_TO_OUT equ d'203' ; set digital pin 3 to OUTPUT
SET_PIN_FOUR_TO_OUT equ d'204' ; set digital pin 4 to OUTPUT
SET_PIN_FIVE_TO_OUT equ d'205' ; set digital pin 5 to OUTPUT
SET_PIN_SIX_TO_OUT equ d'206' ; set digital pin 6 to OUTPUT
SET_PIN_SEVEN_TO_OUT equ d'207' ; set digital pin 7 to OUTPUT
SET_PIN_EIGHT_TO_OUT equ d'208' ; set digital pin 8 to OUTPUT
SET_PIN_NINE_TO_OUT equ d'209' ; set digital pin 9 to OUTPUT
SET_PIN_TEN_TO_OUT equ d'210' ; set digital pin 10 to OUTPUT
SET_PIN_ELEVEN_TO_OUT equ d'211' ; set digital pin 11 to OUTPUT
SET_PIN_TWELVE_TO_OUT equ d'212' ; set digital pin 12 to OUTPUT
SET_PIN_THIRTEEN_TO_OUT equ d'213' ; set digital pin 13 to OUTPUT
; 214-228 UNUSED
OUTPUT_TO_DIGITAL_PINS equ d'229' ; next two bytes set digital output data
; 230-239 UNUSED
REPORT_VERSION equ d'240' ; return the firmware version
; 240-249 UNUSED
DISABLE_PWM equ d'250' ; next byte sets pin # to disable
ENABLE_PWM equ d'251' ; next two bytes set pin # and duty cycle
DISABLE_SOFTWARE_PWM equ d'252' ; next byte sets pin # to disable
ENABLE_SOFTWARE_PWM equ d'253' ; next two bytes set pin # and duty cycle
SET_SOFTWARE_PWM_FREQ equ d'254' ; set master frequency for software PWMs
; 255 UNUSED
;***************
; two byte digital output data format
; ----------------------
; 0 get ready for digital input bytes (229)
; 1 digitalOut 7-13 bitmask
; 2 digitalOut 0-6 bitmask
; two byte PWM data format
; ----------------------
; 0 get ready for digital input bytes (ENABLE_SOFTWARE_PWM/ENABLE_PWM)
; 1 pin #
; 2 duty cycle expressed as 1 byte (255 = 100%)
; digital input message format
; ----------------------
; 0 digital input marker (255/11111111)
; 1 digital read from Arduino // 7-13 bitmask
; 2 digital read from Arduino // 0-6 bitmask
; analog input message format
; ----------------------
; 0 analog input marker
; 1 high byte from analog input pin 0
; 2 low byte from analog input pin 0
; 3 high byte from analog input pin 1
; 4 low byte from analog input pin 1
; 5 high byte from analog input pin 2
; 6 low byte from analog input pin 2
; 7 high byte from analog input pin 3
; 8 low byte from analog input pin 3
; 9 high byte from analog input pin 4
; 10 low byte from analog input pin 4
; 11 high byte from analog input pin 5
; 12 low byte from analog input pin 5
TOTAL_DIGITAL_PINS equ d'14'
INPUT equ d'0' ; these aren't defined in Pd_firmware.pde
OUTPUT equ d'1' ; these aren't defined in Pd_firmware.pde
; for comparing along with INPUT and OUTPUT
PWM equ d'2'
; maximum number of post-command data bytes
MAX_DATA_BYTES equ d'2'
; == VARIABLES ============================================================
; this flag says the next serial input will be data
;byte waitForData = 0;
waitForData equ 0x20 ; initialize to 0;
;byte executeMultiByteCommand = 0; // command to execute after getting multi-byte data
executeMultiByteCommand equ 0x21 ; initialize to 0
;byte storedInputData[MAX_DATA_BYTES] = {0,0}; // multi-byte data
storedInputData0 equ 0x22 ; initialize to 0,0
storedInputData1 equ 0x23 ; initialize to 0,0
; this flag says the first data byte for the digital outs is next
;boolean firstInputByte = false;
firstInputByte equ 0x24 ; initialize to 0
; this int serves as a bit-wise array to store pin status
; 0 = INPUT, 1 = OUTPUT
; int digitalPinStatus;
digitalPinStatusHi equ 0x25 ; initialize to 0,0
digitalPinStatusLo equ 0x26 ; initialize to 0,0
; this byte stores the status of whether PWM is on or not
; bit 9 = PWM0, bit 10 = PWM1, bit 11 = PWM2
; the rest of the bits are unused and should remain 0
;int pwmStatus;
pwmStatusHi equ 0x27 ; initialize to 0,0
pwmStatusLo equ 0x28 ; initialize to 0,0
; this byte stores the status of whether software PWM is on or not
; 00000010 00000000 means bit 10 is softWarePWM enabled
;int softPwmStatus;
softPwmStatusHi equ 0x29 ; initialize to 0,0
softPwmStatusLo equ 0x2A ; initialize to 0,0
;boolean digitalInputsEnabled = true;
digitalInputsEnabled equ 0x2B ; initialize to 1
;byte analogInputsEnabled = 6;
analogInputsEnabled equ 0x2C ; initialize to 6;
;byte analogPin;
analogPin equ 0x2D ;
;int analogData;
analogDataHi equ 0x2E ;
analogDataLo equ 0x2F ;
rxBuf equ 0x40 ;
rxBufEnd equ 0x50 ;
i equ 0x51 ; local variable in setup()
pin equ 0x52 ; pin number for pinMode()
mode equ 0x53 ; pin mode for pinMode()
maskHi equ 0x54
maskLo equ 0x55
rxWrPtr equ 0x56
rxRdPtr equ 0x57
inputData equ 0x58
digitalPin equ 0x59
transmitByte equ 0x5A
digitalData equ 0x5B
fsr_temp equ 0x70 ; variable used for context saving
w_temp equ 0x71 ; variable used for context saving
status_temp equ 0x72 ; variable used for context saving
pclath_temp equ 0x73 ; variable used for context saving
trisa_shadow equ 0x74
trisb_shadow equ 0x75
trisc_shadow equ 0x76
portb_shadow equ 0x77
portc_shadow equ 0x78
; =========================================================================
ORG 0x000 ; processor reset vector
goto setup ; go to beginning of program
; =========================================================================
ORG 0x004 ; interrupt vector location
movwf w_temp ; save off current W register contents
movf STATUS,w ; move status register into W register
movwf status_temp ; save off contents of STATUS register
movf PCLATH,w ; move pclath register into w register
movwf pclath_temp ; save off contents of PCLATH register
btfss PIR1,RCIF
goto intout
;receive interrupt
; 6. Flag bit RCIF will be set when reception is complete and an interrupt will be generated if enable bit RCIE is set.
; 7. Read the RCSTA register to get the ninth bit (if enabled) and determine if any error occurred during reception.
bcf STATUS,RP0 ; bank 0
movf RCSTA,w
andlw b'00000110' ; Framing, Overrun Errors
btfss STATUS,Z
goto RxError
; 8. Read the 8-bit received data by reading the RCREG register.
; handle the character by saving it into rxBuf and incrementing rxWrPtr
movf FSR,w ; first save FSR
movwf fsr_temp
movf rxWrPtr,w ; get the pointer to the buffer
movwf FSR ; into FSR
movf RCREG,w ; read the character
movwf INDF ; store it in the buffer
movf fsr_temp,w ; restore FSR
movwf FSR
incf rxWrPtr,f ; point to next slot in buffer
movlw rxBufEnd ; check for end of buffer
xorwf rxWrPtr,w
btfss STATUS,Z
goto intout ; not yet at end
movlw rxBuf ; reset pointer to start of buffer
movwf rxWrPtr
intout
movf pclath_temp,w ; retrieve copy of PCLATH register
movwf PCLATH ; restore pre-isr PCLATH register contents
movf status_temp,w ; retrieve copy of STATUS register
movwf STATUS ; restore pre-isr STATUS register contents
swapf w_temp,f
swapf w_temp,w ; restore pre-isr W register contents
retfie ; return from interrupt
; 9. If any error occurred, clear the error by clearing enable bit CREN.
RxError
bcf RCSTA,CREN
movf RCREG,w
bsf RCSTA,CREN
goto intout
; =========================================================================
;
; -------------------------------------------------------------------------
;void setup()
;{
setup
clrf waitForData ; init all the variables
clrf executeMultiByteCommand
clrf storedInputData0
clrf storedInputData1
clrf firstInputByte
clrf digitalPinStatusHi
clrf digitalPinStatusLo
clrf pwmStatusHi
clrf pwmStatusLo
clrf softPwmStatusHi
clrf softPwmStatusLo
movlw 1
movwf digitalInputsEnabled ; initialize to 1
movlw 6
movwf analogInputsEnabled ; initialize to 6;
movlw rxBuf
movwf rxWrPtr
movwf rxRdPtr
clrf portb_shadow
clrf portc_shadow
clrf PORTB ; PORTB is cleared anyway at reset
clrf PORTC ; PORTC is cleared anyway at reset
movlw 0xFF ; all inputs (they are anyway after reset)
bsf STATUS,RP0 ; bank 1
movwf TRISA
movwf trisa_shadow
movwf TRISB
movwf trisb_shadow
movwf TRISC
movwf trisc_shadow
bcf STATUS,RP0 ; bank 0
; byte i;
;
; beginSerial(19200);
call beginSerial_19200
; for(i=0; i<TOTAL_DIGITAL_PINS; ++i)
; {
clrf i
; setPinMode(i,INPUT);
slp_1
movf i,w
movwf pin
movlw INPUT
movwf mode
call setPinMode
incf i,f
movlw TOTAL_DIGITAL_PINS
subwf i,w
btfss STATUS,C
goto slp_1
; setup analog pins
;The following steps should be followed to do an A/D conversion:
;1. Configure the A/D module:
; Configure analog pins, voltage reference and digital I/O (ADCON1)
movlw b'10010101' ; right-justified 10-bit result. VRef+ = RA3, AN0-AN9 analog
bsf STATUS,RP0 ; bank 1
movwf ADCON1
bcf STATUS,RP0 ; bank 0
; Select A/D input channel (ADCON0)
movlw b'10000000' ; start with channel 0, 32 Tosc conversion, module off
movwf ADCON0
; Select A/D acquisition time (ADCON2)
movlw b'00101000' ; wait 12Tad
bsf STATUS,RP0 ; bank 1
movwf ADCON2
bcf STATUS,RP0 ; bank 0
; Select A/D conversion clock (ADCON0)
; Turn on A/D module (ADCON0)
bsf ADCON0,ADON
;2. Configure A/D interrupt (if desired):
; Clear ADIF bit
; Set ADIE bit
; Set PEIE bit
; Set GIE bit
;3. Wait the required acquisition time (if required).
;4. Start conversion:
; Set GO/DONE bit (ADCON0 register)
;5. Wait for A/D conversion to complete, by either:
; Polling for the GO/DONE bit to be cleared
;OR
; Waiting for the A/D interrupt
;6. Read A/D Result registers (ADRESH:ADRESL); clear bit ADIF (if required).
;7. For next conversion, go to step 1 or step 2 as required. The A/D conversion time per bit is
; defined as TAD. A minimum wait of 2 TAD is required before the next acquisition starts.
; }
;}
;
; setup falls through into loop and stays there forever...
;
; -------------------------------------------------------------------------
;void loop()
;{
loop
; checkForInput();
call checkForInput
;
; // read all digital pins, in enabled
; if(digitalInputsEnabled)
btfss digitalInputsEnabled,0
goto lp_1
; {
; printByte(ENABLE_DIGITAL_INPUTS);
movlw ENABLE_DIGITAL_INPUTS
call printByte
; transmitDigitalInput(7);
movlw d'7'
call transmitDigitalInput
; checkForInput();
call checkForInput
; transmitDigitalInput(0);
movlw d'0'
call transmitDigitalInput
; checkForInput();
call checkForInput
; }
lp_1
;
; /* get analog in, for the number enabled */
; for(analogPin=0; analogPin<analogInputsEnabled; ++analogPin)
clrf analogPin
lp_2
movf analogInputsEnabled,w
subwf analogPin,w
btfsc STATUS,C
goto loop
; {
; analogData = analogRead(analogPin);
call analogRead ; analogRead sets analogDataHi and analogDataLo according to analogPin
; // these two bytes get converted back into the whole number in Pd
; // the higher bits should be zeroed so that the 8th bit doesn't get set
; printByte(ONE_ANALOG_IN + analogPin);
movlw ONE_ANALOG_IN
addwf analogPin,w
call printByte
; printByte(analogData >> 7); // bitshift the big stuff into the output byte
rlf analogDataLo,w ; bit7 into C
rlf analogDataHi,w ; C into bit0
andlw b'00000111' ; only 10 bits
call printByte
; printByte(analogData % 128); // mod by 32 for the small byte
movf analogDataLo,w
andlw b'01111111'
call printByte
; checkForInput();
call checkForInput
incf analogPin,f
goto lp_2
; }
;}
;
; ============subroutines======================================================
;
; -------------------------------------------------------------------------
; this function checks to see if there is data waiting on the serial port
; then processes all of the stored data
;void checkForInput()
;{
checkForInput
movf rxWrPtr,w
xorwf rxRdPtr,w
btfsc STATUS,Z
return
; if(serialAvailable())
; {
; while(serialAvailable())
; {
movf rxRdPtr,w
movwf FSR
movf INDF,w
; processInput( (byte)serialRead() );
call processInput
incf rxRdPtr,f
movlw rxBufEnd
xorwf rxRdPtr,w
btfss STATUS,Z
goto checkForInput
movlw rxBuf ; wrap to start of buffer
movwf rxRdPtr
goto checkForInput
; }
; }
;}
; -------------------------------------------------------------------------
; printByte: on entry w contains the byte to send
printByte
bsf STATUS,RP0 ; bank 1
btfss TXSTA,TRMT
goto $-1
bcf STATUS,RP0 ; bank 0
movwf TXREG
return
; -------------------------------------------------------------------------
beginSerial_19200 ; setup USART for 19200 asynchronous receive and transmit, 8bitsNoParity1Stop
; Bits TRISC<7:6> have to be set in order to configure pins RC6/TX/CK and RC7/RX/DT as the USART.
; (They are set at reset)
bsf STATUS,RP0 ; bank 1
; When setting up an Asynchronous Transmission, follow these steps:
; 1. Initialize the SPBRG register for the appropriate baud rate. If a high-speed baud rate is desired,
; set bit BRGH (see Section 11.1 “AUSART Baud Rate Generator (BRG)”).
; * * * For 14.745600MHz crystal clock, SPBRG=47, BRGH=1 gives 19200 baud. * * *
movlw B19200 ; = d'47'
movwf SPBRG
bsf TXSTA,BRGH
; 2. Enable the asynchronous serial port by clearing bit SYNC and setting bit SPEN.
bcf STATUS,RP0 ; bank 0
bsf RCSTA,SPEN
; 3. If interrupts are desired, then set enable bit TXIE.
; 4. If 9-bit transmission is desired, then set transmit bit TX9.
; 5. Enable the transmission by setting bit TXEN which will also set bit TXIF.
bsf STATUS,RP0 ; bank 1
bsf TXSTA,TXEN
; 6. If 9-bit transmission is selected, the ninth bit should be loaded in bit TX9D.
; 7. Load data to the TXREG register (starts transmission).
; 8. If using interrupts, ensure that GIE and PEIE (bits 7 and 6) of the INTCON register are set.
;When setting up an Asynchronous Reception, follow these steps:
; 1. Initialize the SPBRG register for the appropriate baud rate. If a high-speed baud rate is desired,
; set bit BRGH (see Section 11.1 “AUSART Baud Rate Generator (BRG)”).
; 2. Enable the asynchronous serial port by clearing bit SYNC and setting bit SPEN.
; 3. If interrupts are desired, then set enable bit RCIE.
bsf PIE1,RCIE
; 4. If 9-bit reception is desired, then set bit RX9.
; 5. Enable the reception by setting bit CREN.
bcf STATUS,RP0 ; bank 0
bsf RCSTA,CREN
; 6. Flag bit RCIF will be set when reception is complete and an interrupt will be generated if enable bit RCIE is set.
; 7. Read the RCSTA register to get the ninth bit (if enabled) and determine if any error occurred during reception.
; 8. Read the 8-bit received data by reading the RCREG register.
; 9. If any error occurred, clear the error by clearing enable bit CREN.
; 10. If using interrupts, ensure that GIE and PEIE (bits 7 and 6) of the INTCON register are set.
bsf INTCON,PEIE
bsf INTCON,GIE
return
; -------------------------------------------------------------------------
;void transmitDigitalInput(byte startPin)
;{
transmitDigitalInput ; on entry w contains startPin
; byte i;
; byte digitalPin;
;// byte digitalPinBit;
; byte transmitByte = 0;
clrf transmitByte
; byte digitalData;
;
movwf digitalPin
movwf i
clrf maskLo
clrf maskHi
bsf STATUS,C
tdilp_1 ; set up the mask with bit startPin set
rlf maskLo,f
rlf maskHi,f
movf i,f
btfsc STATUS,Z
goto tdi_1 ; mask is at startPin
decf i,f
goto tdilp_1
; for(i=0;i<7;++i)
; {
tdi_2
; digitalPin = i+startPin;
incf i,f ; ++i
movlw d'7'
xorwf i,w ; i == 7?
btfsc STATUS,Z
goto tdi_3 ; yes
incf digitalPin,f ; no
bcf STATUS,C
rlf maskLo,f
rlf maskHi,f
;/* digitalPinBit = OUTPUT << digitalPin;
;// only read the pin if its set to input
;if(digitalPinStatus & digitalPinBit) {
;digitalData = 0; // pin set to OUTPUT, don't read
;}
;else if( (digitalPin >= 9) && (pwmStatus & (1 << digitalPin)) ) {
;digitalData = 0; // pin set to PWM, don't read
;}*/
; if( !(digitalPinStatus & (1 << digitalPin)) )
tdi_1
movf digitalPinStatusLo,w
andwf maskLo,w ; maskLo is lowbyte of 1<<digitalPin
btfss STATUS,Z
goto tdi_2
movf digitalPinStatusHi,w
andwf maskHi,w
btfss STATUS,Z
goto tdi_2
; {
;
; digitalData = (byte) digitalRead(digitalPin);
call digitalRead ; sets carry to match pin w input data
; transmitByte = transmitByte + ((1 << i) * digitalData);
; rlf transmitByte,f ; carry bit shifts into transmitByte
rrf transmitByte,f ; carry bit shifts into transmitByte
goto tdi_2
; }
; }
; printByte(transmitByte);
tdi_3
bcf STATUS,C ; shift 0 into high bit
rrf transmitByte,f
movf transmitByte,w
call printByte
;}
return
;
; -------------------------------------------------------------------------
digitalRead0
btfsc PORTC,7
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead1
btfsc PORTC,6
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead2
btfsc PORTC,5
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead3
btfsc PORTC,4
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead4
btfsc PORTC,3
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead5
btfsc PORTB,0
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead6
btfsc PORTB,4
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead7
btfsc PORTB,7
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead8
btfsc PORTB,6
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead9
btfsc PORTB,5
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead10
btfsc PORTC,2
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead11
btfsc PORTC,1
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead12
btfsc PORTC,0
bsf STATUS,C
return
; -------------------------------------------------------------------------
digitalRead13
btfsc PORTB,1
bsf STATUS,C
return
;
; -------------------------------------------------------------------------
analogRead0 ; AN0
movlw b'10000101' ; Fosc/32 channel0 Go On
goto analogWait
; -------------------------------------------------------------------------
analogRead1 ; AN1
movlw b'10001101' ; Fosc/32 channel1 Go On
goto analogWait
; -------------------------------------------------------------------------
analogRead2 ; AN2
movlw b'10010101' ; Fosc/32 channel2 Go On
goto analogWait
; -------------------------------------------------------------------------
analogRead3 ; AN4
movlw b'10100101' ; Fosc/32 channel4 Go On
goto analogWait
; -------------------------------------------------------------------------
analogRead4 ; AN8
movlw b'10000111' ; Fosc/32 channel8 Go On
goto analogWait
; -------------------------------------------------------------------------
analogRead5 ; AN9
movlw b'10001111' ; Fosc/32 channel9 Go On
goto analogWait
; -------------------------------------------------------------------------
analogWait
movwf ADCON0
;3. Wait the required acquisition time (if required).
; we set 12Tad in ADCON2
;4. Start conversion:
; Set GO/DONE bit (ADCON0 register)
;5. Wait for A/D conversion to complete, by either:
; Polling for the GO/DONE bit to be cleared
btfsc ADCON0,GO_DONE
goto $-1
;OR
; Waiting for the A/D interrupt
;6. Read A/D Result registers (ADRESH:ADRESL); clear bit ADIF (if required).
movf ADRESH,w
movwf analogDataHi
bsf STATUS,RP0 ; bank 1
movf ADRESL,w
bcf STATUS,RP0 ; bank 0
movwf analogDataLo
;7. For next conversion, go to step 1 or step 2 as required. The A/D conversion time per bit is
; defined as TAD. A minimum wait of 2 TAD is required before the next acquisition starts.
return
; -------------------------------------------------------------------------
; this function sets the pin mode to the correct state and sets the relevant
; bits in the two bit-arrays that track Digital I/O and PWM status
;void setPinMode(int pin, int mode)
;{
; if(mode == INPUT)
; {
setPinMode ; on entry pin contains the digital pin number, mode contains the mode
movlw INPUT
xorwf mode,w
btfss STATUS,Z
goto setPinToOutOrPwm
goto setPinToIn
; digitalPinStatus = digitalPinStatus &~ (1 << pin);
; pwmStatus = pwmStatus &~ (1 << pin);
; pinMode(pin,INPUT);
; -------------------------------------------------------------------------
setPinZeroToIn ; pin0 is RX!!!
bcf digitalPinStatusLo,0
bcf pwmStatusLo,0
bsf trisc_shadow,7
write_trisc
movf trisc_shadow,w
bsf STATUS,RP0 ; bank 1
movwf TRISC ; was bsf TRISC,7
bcf STATUS,RP0 ; bank 0
return
; -------------------------------------------------------------------------
setPinOneToIn ; pin1 is TX!!!!
bcf digitalPinStatusLo,1
bcf pwmStatusLo,1
bsf trisc_shadow,6
goto write_trisc
; -------------------------------------------------------------------------
setPinTwoToIn
bcf digitalPinStatusLo,2
bcf pwmStatusLo,2
bsf trisc_shadow,5
goto write_trisc
; -------------------------------------------------------------------------
setPinThreeToIn
bcf digitalPinStatusLo,3
bcf pwmStatusLo,3
bsf trisc_shadow,4
goto write_trisc
; -------------------------------------------------------------------------
setPinFourToIn
bcf digitalPinStatusLo,4
bcf pwmStatusLo,4
bsf trisc_shadow,3
goto write_trisc
; -------------------------------------------------------------------------
setPinFiveToIn
bcf digitalPinStatusLo,5
bcf pwmStatusLo,5
bsf trisb_shadow,0
write_trisb
movf trisb_shadow,w
bsf STATUS,RP0 ; bank 1
movwf TRISB ; was bsf TRISB,0
bcf STATUS,RP0 ; bank 0
return
; -------------------------------------------------------------------------
setPinSixToIn
bcf digitalPinStatusLo,6
bcf pwmStatusLo,6
bsf trisb_shadow,4
goto write_trisb
; -------------------------------------------------------------------------
setPinSevenToIn
bcf digitalPinStatusLo,7
bcf pwmStatusLo,7
bsf trisb_shadow,7
goto write_trisb
; -------------------------------------------------------------------------
setPinEightToIn
bcf digitalPinStatusHi,0
bcf pwmStatusHi,0
bsf trisb_shadow,6
goto write_trisb
; -------------------------------------------------------------------------
setPinNineToIn
bcf digitalPinStatusHi,1
bcf pwmStatusHi,1
bsf trisb_shadow,5
goto write_trisb
; -------------------------------------------------------------------------
setPinTenToIn
bcf digitalPinStatusHi,2
bcf pwmStatusHi,2
bsf trisc_shadow,2
goto write_trisc
; -------------------------------------------------------------------------
setPinElevenToIn
bcf digitalPinStatusHi,3
bcf pwmStatusHi,3
bsf trisc_shadow,1
goto write_trisc
; -------------------------------------------------------------------------
setPinTwelveToIn
bcf digitalPinStatusHi,4
bcf pwmStatusHi,4
bsf trisc_shadow,0
goto write_trisc
; -------------------------------------------------------------------------
setPinThirteenToIn
bcf digitalPinStatusHi,5
bcf pwmStatusHi,5
bsf trisb_shadow,1
goto write_trisb
; }
; else if(mode == OUTPUT)
; {
; -------------------------------------------------------------------------
setPinToOutOrPwm
movlw OUTPUT
xorwf mode,w
btfsc STATUS,Z
goto setPinToPwmOrNo
goto setPinToOut
; digitalPinStatus = digitalPinStatus | (1 << pin);
; pwmStatus = pwmStatus &~ (1 << pin);
; pinMode(pin,OUTPUT);
; -------------------------------------------------------------------------
setPinZeroToOut ; pin0 is RX!!! Don't allow this to happen! TRISC.7 must be 1
; bsf digitalPinStatusLo,0
; bcf pwmStatusLo,0
; bcf trisc_shadow,7
; goto write_trisc
return
; -------------------------------------------------------------------------
setPinOneToOut ; pin1 is TX!!!! Don't allow this to happen! TRISC.6 must be 1
; bsf digitalPinStatusLo,1
; bcf pwmStatusLo,1
; bcf trisc_shadow,6
; goto write_trisc
return
; -------------------------------------------------------------------------
setPinTwoToOut
bsf digitalPinStatusLo,2
bcf pwmStatusLo,2
bcf trisc_shadow,5
goto write_trisc
; -------------------------------------------------------------------------
setPinThreeToOut
bsf digitalPinStatusLo,3
bcf pwmStatusLo,3
bcf trisc_shadow,4
goto write_trisc
; -------------------------------------------------------------------------
setPinFourToOut
bsf digitalPinStatusLo,4
bcf pwmStatusLo,4
bcf trisc_shadow,3
goto write_trisc
; -------------------------------------------------------------------------
setPinFiveToOut
bsf digitalPinStatusLo,5
bcf pwmStatusLo,5
bcf trisb_shadow,0
goto write_trisb
; -------------------------------------------------------------------------
setPinSixToOut
bsf digitalPinStatusLo,6
bcf pwmStatusLo,6
bcf trisb_shadow,4
goto write_trisb
; -------------------------------------------------------------------------
setPinSevenToOut
bsf digitalPinStatusLo,7
bcf pwmStatusLo,7
bcf trisb_shadow,7
goto write_trisb
; -------------------------------------------------------------------------
setPinEightToOut
bsf digitalPinStatusHi,0
bcf pwmStatusHi,0
bcf trisb_shadow,6
goto write_trisb
; -------------------------------------------------------------------------
setPinNineToOut
bsf digitalPinStatusHi,1
bcf pwmStatusHi,1
bcf trisb_shadow,5
goto write_trisb
; -------------------------------------------------------------------------
setPinTenToOut
bsf digitalPinStatusHi,2
bcf pwmStatusHi,2
bcf trisc_shadow,2
goto write_trisc
; -------------------------------------------------------------------------
setPinElevenToOut
bsf digitalPinStatusHi,3
bcf pwmStatusHi,3
bcf trisc_shadow,1
goto write_trisc
; -------------------------------------------------------------------------
setPinTwelveToOut
bsf digitalPinStatusHi,4
bcf pwmStatusHi,4
bcf trisc_shadow,0
goto write_trisc
; -------------------------------------------------------------------------
setPinThirteenToOut
bsf digitalPinStatusHi,5
bcf pwmStatusHi,5
bcf trisb_shadow,1
goto write_trisb
; }
; else if( (mode == PWM) && (pin >= 9) && (pin <= 11) )
; {
; -------------------------------------------------------------------------
setPinToPwmOrNo
movlw PWM
xorwf mode,w
btfsc STATUS,Z
return ; no more choices
goto setPinToPwm
; digitalPinStatus = digitalPinStatus | (1 << pin);
; pwmStatus = pwmStatus | (1 << pin);
; pinMode(pin,OUTPUT);
; -------------------------------------------------------------------------
setPinZeroToPWM ; pin0 is RX!!! Don't allow this to happen! TRISC.7 must be 1
; bsf digitalPinStatusLo,0
; bsf pwmStatusLo,0
; bcf trisc_shadow,7
; goto write_trisc
; bsf STATUS,RP0 ; bank 1
; bcf TRISC,7
; bcf STATUS,RP0 ; bank 0
return
; -------------------------------------------------------------------------
setPinOneToPWM ; pin1 is TX!!!! Don't allow this to happen! TRISC.6 must be 1
; bsf digitalPinStatusLo,1
; bsf pwmStatusLo,1
; bcf trisc_shadow,6
; goto write_trisc
; bsf STATUS,RP0 ; bank 1
; bcf TRISC,6
; bcf STATUS,RP0 ; bank 0
return
; -------------------------------------------------------------------------
setPinTwoToPWM
bsf digitalPinStatusLo,2
bsf pwmStatusLo,2
bcf trisc_shadow,5
goto write_trisc
; -------------------------------------------------------------------------
setPinThreeToPWM
bsf digitalPinStatusLo,3
bsf pwmStatusLo,3
bcf trisc_shadow,4
goto write_trisc
; -------------------------------------------------------------------------
setPinFourToPWM
bsf digitalPinStatusLo,4
bsf pwmStatusLo,4
bcf trisc_shadow,3
goto write_trisc
; -------------------------------------------------------------------------
setPinFiveToPWM
bsf digitalPinStatusLo,5
bsf pwmStatusLo,5
bcf trisb_shadow,0
goto write_trisb
; -------------------------------------------------------------------------
setPinSixToPWM
bsf digitalPinStatusLo,6
bsf pwmStatusLo,6
bcf trisb_shadow,4
goto write_trisb
; -------------------------------------------------------------------------
setPinSevenToPWM
bsf digitalPinStatusLo,7
bsf pwmStatusLo,7
bcf trisb_shadow,7
goto write_trisb
; -------------------------------------------------------------------------
setPinEightToPWM
bsf digitalPinStatusHi,0
bsf pwmStatusHi,0
bcf trisb_shadow,6
goto write_trisb
; -------------------------------------------------------------------------
setPinNineToPWM
bsf digitalPinStatusHi,1
bsf pwmStatusHi,1
bcf trisb_shadow,5
goto write_trisb
; -------------------------------------------------------------------------
setPinTenToPWM
bsf digitalPinStatusHi,2
bsf pwmStatusHi,2
bcf trisc_shadow,2
goto write_trisc
; -------------------------------------------------------------------------
setPinElevenToPWM
bsf digitalPinStatusHi,3
bsf pwmStatusHi,3
bcf trisc_shadow,1
goto write_trisc
; -------------------------------------------------------------------------
setPinTwelveToPWM
bsf digitalPinStatusHi,4
bsf pwmStatusHi,4
bcf trisc_shadow,0
goto write_trisc
; -------------------------------------------------------------------------
setPinThirteenToPWM
bsf digitalPinStatusHi,5
bsf pwmStatusHi,5
bcf trisb_shadow,1
goto write_trisb
; }
;}
; return
; -------------------------------------------------------------------------
;
;void setSoftPwm (int pin, byte pulsePeriod) {
; byte i;
; /* for(i=0; i<7; ++i) {
; mask = 1 << i;
; if(digitalPinStatus & mask) {
; digitalWrite(i, inputData & mask);
; }
; }
; */
; //read timer type thing
;
; //loop through each pin, turn them on if selected
; //softwarePWMStatus
; //check timer type thing against pulsePeriods for each pin
; //throw pin low if expired
;}
;
; -------------------------------------------------------------------------
;void setSoftPwmFreq(byte freq) {
;}
;
;
; -------------------------------------------------------------------------
;void disSoftPwm(int pin) {
; //throw pin low
;
;}
;
write_portc
movf portc_shadow,w
movwf PORTC
return
write_portb
movf portb_shadow,w
movwf PORTB
return
; -------------------------------------------------------------------------
digitalWrite0 ; write carry bit to digital pin 0 (Pin0 is RX!!!)
bsf portc_shadow,7
btfss STATUS,C
bcf portc_shadow,7
goto write_portc
; -------------------------------------------------------------------------
digitalWrite1 ; write carry bit to digital pin 1 (Pin1 is tX!!!)
bsf portc_shadow,6
btfss STATUS,C
bcf portc_shadow,6
goto write_portc
; -------------------------------------------------------------------------
digitalWrite2 ; write carry bit to digital pin 2
bsf portc_shadow,5
btfss STATUS,C
bcf portc_shadow,5
goto write_portc
; -------------------------------------------------------------------------
digitalWrite3 ; write carry bit to digital pin 3
bsf portc_shadow,4
btfss STATUS,C
bcf portc_shadow,4
goto write_portc
; -------------------------------------------------------------------------
digitalWrite4 ; write carry bit to digital pin 4
bsf portc_shadow,3
btfss STATUS,C
bcf portc_shadow,3
goto write_portc
; -------------------------------------------------------------------------
digitalWrite5 ; write carry bit to digital pin 5
bsf portb_shadow,0
btfss STATUS,C
bcf portb_shadow,0
goto write_portb
; -------------------------------------------------------------------------
digitalWrite6 ; write carry bit to digital pin 6
bsf portb_shadow,4
btfss STATUS,C
bcf portb_shadow,4
goto write_portb
; -------------------------------------------------------------------------
digitalWrite7 ; write carry bit to digital pin 7
bsf portb_shadow,7
btfss STATUS,C
bcf portb_shadow,7
goto write_portb
; -------------------------------------------------------------------------
digitalWrite8 ; write carry bit to digital pin 8
bsf portb_shadow,6
btfss STATUS,C
bcf portb_shadow,6
goto write_portb
; -------------------------------------------------------------------------
digitalWrite9 ; write carry bit to digital pin 9
bsf portb_shadow,5
btfss STATUS,C
bcf portb_shadow,5
goto write_portb
; -------------------------------------------------------------------------
digitalWrite10 ; write carry bit to digital pin 10
bsf portc_shadow,2
btfss STATUS,C
bcf portc_shadow,2
goto write_portc
; -------------------------------------------------------------------------
digitalWrite11 ; write carry bit to digital pin 11
bsf portc_shadow,1
btfss STATUS,C
bcf portc_shadow,1
goto write_portc
; -------------------------------------------------------------------------
digitalWrite12 ; write carry bit to digital pin 12
bsf portc_shadow,0
btfss STATUS,C
bcf portc_shadow,0
goto write_portc
; -------------------------------------------------------------------------
digitalWrite13 ; write carry bit to digital pin 13
bsf portb_shadow,1
btfss STATUS,C
bcf portb_shadow,1
goto write_portb
;
;
; -------------------------------------------------------------------------
disableDigitalInputs
clrf digitalInputsEnabled
return
; -------------------------------------------------------------------------
enableDigitalInputs
bsf digitalInputsEnabled,0
return
; -------------------------------------------------------------------------
setZeroAnalogIns
clrw
goto setAnalogIns
; -------------------------------------------------------------------------
setOneAnalogIn
movlw d'1'
goto setAnalogIns
; -------------------------------------------------------------------------
setTwoAnalogIns
movlw d'2'
goto setAnalogIns
; -------------------------------------------------------------------------
setThreeAnalogIns
movlw d'3'
goto setAnalogIns
; -------------------------------------------------------------------------
setFourAnalogIns
movlw d'4'
goto setAnalogIns
; -------------------------------------------------------------------------
setFiveAnalogIns
movlw d'5'
goto setAnalogIns
; -------------------------------------------------------------------------
setSixAnalogIns
movlw d'6'
; -------------------------------------------------------------------------
setAnalogIns
; analogInputsEnabled = inputData - ZERO_ANALOG_INS;
; break;
movwf analogInputsEnabled
return
; -------------------------------------------------------------------------
; case ENABLE_PWM:
enablePwm
; case ENABLE_SOFTWARE_PWM:
enableSoftPwm
; waitForData = 2; // 2 bytes needed (pin#, dutyCycle)
movlw d'2'
movwf waitForData
; executeMultiByteCommand = inputData;
movf inputData,w
movwf executeMultiByteCommand
; break;
return
; -------------------------------------------------------------------------
; case DISABLE_PWM:
disablePwm
; case SET_SOFTWARE_PWM_FREQ:
setSoftPwmFreq
; case DISABLE_SOFTWARE_PWM:
disableSoftPwm
; waitForData = 1; // 1 byte needed (pin#)
movlw d'1'
movwf waitForData
; executeMultiByteCommand = inputData;
movf inputData,w
movwf executeMultiByteCommand
; break;
return
; -------------------------------------------------------------------------
; case OUTPUT_TO_DIGITAL_PINS: // bytes to send to digital outputs
setOutputToDigitalPins
; firstInputByte = true;
bsf firstInputByte,0
; break;
return
; -------------------------------------------------------------------------
; case REPORT_VERSION:
reportVersion
; printByte(REPORT_VERSION);
movlw REPORT_VERSION
call printByte
; printByte(MAJOR_VERSION);
movlw MAJOR_VERSION
call printByte
; printByte(MINOR_VERSION);
movlw MINOR_VERSION
call printByte
; break;
; }
; }
return
;}
;
; -------------------------------------------------------------------------
; processInput() is called whenever a byte is available on the
; Arduino's serial port. This is where the commands are handled.
;
;void processInput(byte inputData)
;{
processInput ; on entry w contains a byte of input data from rxBuf
; int i;
; int mask;
movwf inputData ; save the new byte
;
; // a few commands have byte(s) of data following the command
; if( waitForData > 0)
; {
movf waitForData,f
btfsc STATUS,Z
goto pi_1
; waitForData--;
decf waitForData,f
; storedInputData[waitForData] = inputData;
movlw storedInputData0
addwf waitForData,w
movwf FSR
movf inputData,w
movwf INDF
;
; if(executeMultiByteCommand && (waitForData==0))
movf executeMultiByteCommand,f
btfsc STATUS,Z
return ; executeMultiByteCommand == 0
movf waitForData,f
btfss STATUS,Z
return ; waitForData != 0
; {
; //we got everything
goto doMultiByteCommand
; -------------------------------------------------------------------------
mb_enablePwm
; case ENABLE_PWM: ; 251
; setPinMode(storedInputData[1],PWM);
movf storedInputData1,w
movwf pin
movlw PWM
movwf mode
call setPinMode
; analogWrite(storedInputData[1], storedInputData[0]);
; break;
goto pi_6
; -------------------------------------------------------------------------
mb_disablePwm
; case DISABLE_PWM: ; 250
; setPinMode(storedInputData[0],INPUT);
movf storedInputData0,w
movwf pin
movlw INPUT
movwf mode
call setPinMode
; break;
goto pi_6
; -------------------------------------------------------------------------
mb_enableSoftPwm
; case ENABLE_SOFTWARE_PWM: ; 253
; setPinMode(storedInputData[1],PWM);
movf storedInputData1,w
movwf pin
movlw PWM
movwf mode
call setPinMode
; setSoftPwm(storedInputData[1], storedInputData[0]);
; break;
goto pi_6
; -------------------------------------------------------------------------
mb_disableSoftPwm
; case DISABLE_SOFTWARE_PWM: ; 252
; disSoftPwm(storedInputData[0]);
; break;
goto pi_6
; -------------------------------------------------------------------------
mb_setSoftPwmFreq
; case SET_SOFTWARE_PWM_FREQ: ; 254
; setSoftPwmFreq(storedInputData[0]);
; break;
goto pi_6
; }
; -------------------------------------------------------------------------
pi_6
; executeMultiByteCommand = 0;
clrf executeMultiByteCommand
; }
return
; }
; -------------------------------------------------------------------------
; else if(inputData < 128)
; {
pi_1
btfsc inputData,7
goto doCommand
; if(firstInputByte)
movf pwmStatusLo,w
xorlw 0xFF
andwf digitalPinStatusLo,w
movwf maskLo
movf pwmStatusHi,w
xorlw 0xFF
andwf digitalPinStatusHi,w
movwf maskHi
btfss firstInputByte,0
goto pi_8
; {
; // output data for pins 7-13
; for(i=7; i<TOTAL_DIGITAL_PINS; ++i)
; {
; mask = 1 << i;
; if( (digitalPinStatus & mask) && !(pwmStatus & mask) )
; {
; // inputData is a byte and mask is an int, so align the high part of mask
btfss maskLo,7
goto pi_12
bcf STATUS,C ; the data bit is zero
btfsc inputData,0
bsf STATUS,C ; unless it's one
call digitalWrite7
pi_12
btfss maskHi,0
goto pi_11
bcf STATUS,C ; the data bit is zero
btfsc inputData,1
bsf STATUS,C ; unless it's one
call digitalWrite8
pi_11
btfss maskHi,1
goto pi_10
bcf STATUS,C ; the data bit is zero
btfsc inputData,2
bsf STATUS,C ; unless it's one
call digitalWrite9
pi_10
btfss maskHi,2
goto pi_09
bcf STATUS,C ; the data bit is zero
btfsc inputData,3
bsf STATUS,C ; unless it's one
call digitalWrite10
pi_09
btfss maskHi,3
goto pi_08
bcf STATUS,C ; the data bit is zero
btfsc inputData,4
bsf STATUS,C ; unless it's one
call digitalWrite11
pi_08
btfss maskHi,4
goto pi_07
bcf STATUS,C ; the data bit is zero
btfsc inputData,5
bsf STATUS,C ; unless it's one
call digitalWrite12
pi_07
btfss maskHi,5
goto pi_06
bcf STATUS,C ; the data bit is zero
btfsc inputData,6
bsf STATUS,C ; unless it's one
call digitalWrite13
; digitalWrite(i, inputData & (mask >> 7));
; }
; }
pi_06
; firstInputByte = false;
clrf firstInputByte
return
; }
; else
pi_8
; { //
; for(i=0; i<7; ++i)
; {
; mask = 1 << i;
; if( (digitalPinStatus & mask) && !(pwmStatus & mask) )
; {
; digitalWrite(i, inputData & mask);
btfss maskLo,0
goto pi_13
bcf STATUS,C ; the data bit is zero
btfsc inputData,0
bsf STATUS,C ; unless it's one
call digitalWrite0
pi_13
btfss maskLo,1
goto pi_14
bcf STATUS,C ; the data bit is zero
btfsc inputData,1
bsf STATUS,C ; unless it's one
call digitalWrite1
pi_14
btfss maskLo,2
goto pi_15
bcf STATUS,C ; the data bit is zero
btfsc inputData,2
bsf STATUS,C ; unless it's one
call digitalWrite2
pi_15
btfss maskLo,3
goto pi_16
bcf STATUS,C ; the data bit is zero
btfsc inputData,3
bsf STATUS,C ; unless it's one
call digitalWrite3
pi_16
btfss maskLo,4
goto pi_17
bcf STATUS,C ; the data bit is zero
btfsc inputData,4
bsf STATUS,C ; unless it's one
call digitalWrite4
pi_17
btfss maskLo,5
goto pi_18
bcf STATUS,C ; the data bit is zero
btfsc inputData,5
bsf STATUS,C ; unless it's one
call digitalWrite5
pi_18
btfss maskLo,6
goto pi_19
bcf STATUS,C ; the data bit is zero
btfsc inputData,6
bsf STATUS,C ; unless it's one
call digitalWrite6
; }
; }
; }
pi_19
return
; }
ORG 0x400 ; table lookup works better when it doesn't cross a 256-byte page boundary
; -------------------------------------------------------------------------
; else
; {
; inputData > 127
; switch (inputData)
; {
doCommand
movlw HIGH commandTab
movwf PCLATH
movf inputData,w
andlw 0x7F ; skip the first 127 values
addwf PCL,f ; jump to command
commandTab
; 128-129 UNUSED
return ; 128
return ; 129
goto setPinZeroToIn ;SET_PIN_ZERO_TO_IN equ d'130' ; set digital pin 0 to INPUT
goto setPinOneToIn ;SET_PIN_ONE_TO_IN equ d'131' ; set digital pin 1 to INPUT
goto setPinTwoToIn ;SET_PIN_TWO_TO_IN equ d'132' ; set digital pin 2 to INPUT
goto setPinThreeToIn ;SET_PIN_THREE_TO_IN equ d'133' ; set digital pin 3 to INPUT
goto setPinFourToIn ;SET_PIN_FOUR_TO_IN equ d'134' ; set digital pin 4 to INPUT
goto setPinFiveToIn ;SET_PIN_FIVE_TO_IN equ d'135' ; set digital pin 5 to INPUT
goto setPinSixToIn ;SET_PIN_SIX_TO_IN equ d'136' ; set digital pin 6 to INPUT
goto setPinSevenToIn ;SET_PIN_SEVEN_TO_IN equ d'137' ; set digital pin 7 to INPUT
goto setPinEightToIn ;SET_PIN_EIGHT_TO_IN equ d'138' ; set digital pin 8 to INPUT
goto setPinNineToIn ;SET_PIN_NINE_TO_IN equ d'139' ; set digital pin 9 to INPUT
goto setPinTenToIn ;SET_PIN_TEN_TO_IN equ d'140' ; set digital pin 10 to INPUT
goto setPinElevenToIn ;SET_PIN_ELEVEN_TO_IN equ d'141' ; set digital pin 11 to INPUT
goto setPinTwelveToIn ;SET_PIN_TWELVE_TO_IN equ d'142' ; set digital pin 12 to INPUT
goto setPinThirteenToIn ;SET_PIN_THIRTEEN_TO_IN equ d'143' ; set digital pin 13 to INPUT
; 144-149 UNUSED
return ; 144
return ; 145
return ; 146
return ; 147
return ; 148
return ; 149
goto disableDigitalInputs ;DISABLE_DIGITAL_INPUTS equ d'150' ; disable reporting of digital inputs
goto enableDigitalInputs ;ENABLE_DIGITAL_INPUTS equ d'151' ; enable reporting of digital inputs
; 152-159 UNUSED
return ; 152
return ; 153
return ; 154
return ; 155
return ; 156
return ; 157
return ; 158
return ; 159
goto setZeroAnalogIns ;ZERO_ANALOG_INS equ d'160' ; disable reporting on all analog ins
goto setOneAnalogIn ;ONE_ANALOG_IN equ d'161' ; enable reporting for 1 analog in (0)
goto setTwoAnalogIns ;TWO_ANALOG_INS equ d'162' ; enable reporting for 2 analog ins (0,1)
goto setThreeAnalogIns ;THREE_ANALOG_INS equ d'163' ; enable reporting for 3 analog ins (0-2)
goto setFourAnalogIns ;FOUR_ANALOG_INS equ d'164' ; enable reporting for 4 analog ins (0-3)
goto setFiveAnalogIns ;FIVE_ANALOG_INS equ d'165' ; enable reporting for 5 analog ins (0-4)
goto setSixAnalogIns ;SIX_ANALOG_INS equ d'166' ; enable reporting for 6 analog ins (0-5)
; 167-199 UNUSED
return ; 167
return ; 168
return ; 169
return ; 170
return ; 171
return ; 172
return ; 173
return ; 174
return ; 175
return ; 176
return ; 177
return ; 178
return ; 179
return ; 180
return ; 181
return ; 182
return ; 183
return ; 184
return ; 185
return ; 186
return ; 187
return ; 188
return ; 189
return ; 190
return ; 191
return ; 192
return ; 193
return ; 194
return ; 195
return ; 196
return ; 197
return ; 198
return ; 199
goto setPinZeroToOut ;SET_PIN_ZERO_TO_OUT equ d'200' ; set digital pin 0 to OUTPUT
goto setPinOneToOut ;SET_PIN_ONE_TO_OUT equ d'201' ; set digital pin 1 to OUTPUT
goto setPinTwoToOut ;SET_PIN_TWO_TO_OUT equ d'202' ; set digital pin 2 to OUTPUT
goto setPinThreeToOut ;SET_PIN_THREE_TO_OUT equ d'203' ; set digital pin 3 to OUTPUT
goto setPinFourToOut ;SET_PIN_FOUR_TO_OUT equ d'204' ; set digital pin 4 to OUTPUT
goto setPinFiveToOut ;SET_PIN_FIVE_TO_OUT equ d'205' ; set digital pin 5 to OUTPUT
goto setPinSixToOut ;SET_PIN_SIX_TO_OUT equ d'206' ; set digital pin 6 to OUTPUT
goto setPinSevenToOut ;SET_PIN_SEVEN_TO_OUT equ d'207' ; set digital pin 7 to OUTPUT
goto setPinEightToOut ;SET_PIN_EIGHT_TO_OUT equ d'208' ; set digital pin 8 to OUTPUT
goto setPinNineToOut ;SET_PIN_NINE_TO_OUT equ d'209' ; set digital pin 9 to OUTPUT
goto setPinTenToOut ;SET_PIN_TEN_TO_OUT equ d'210' ; set digital pin 10 to OUTPUT
goto setPinElevenToOut ;SET_PIN_ELEVEN_TO_OUT equ d'211' ; set digital pin 11 to OUTPUT
goto setPinTwelveToOut ;SET_PIN_TWELVE_TO_OUT equ d'212' ; set digital pin 12 to OUTPUT
goto setPinThirteenToOut ;SET_PIN_THIRTEEN_TO_OUT equ d'213' ; set digital pin 13 to OUTPUT
; 214-228 UNUSED
return ; 214
return ; 215
return ; 216
return ; 217
return ; 218
return ; 219
return ; 220
return ; 221
return ; 222
return ; 223
return ; 224
return ; 225
return ; 226
return ; 227
return ; 228
goto setOutputToDigitalPins ;OUTPUT_TO_DIGITAL_PINS equ d'229' ; next two bytes set digital output data
; 230-239 UNUSED
return; 230
return; 231
return; 232
return; 233
return; 234
return; 235
return; 236
return; 237
return; 238
return; 239
goto reportVersion ;REPORT_VERSION equ d'240' ; return the firmware version
; 240-249 UNUSED
return ; 241
return ; 242
return ; 243
return ; 244
return ; 245
return ; 246
return ; 247
return ; 248
return ; 249
goto disablePwm ;DISABLE_PWM equ d'250' ; next byte sets pin # to disable
goto enablePwm ;ENABLE_PWM equ d'251' ; next two bytes set pin # and duty cycle
goto disableSoftPwm ;DISABLE_SOFTWARE_PWM equ d'252' ; next byte sets pin # to disable
goto enableSoftPwm ;ENABLE_SOFTWARE_PWM equ d'253' ; next two bytes set pin # and duty cycle
goto setSoftPwmFreq ;SET_SOFTWARE_PWM_FREQ equ d'254' ; set master frequency for software PWMs
; 255 UNUSED
return ; 255
; -------------------------------------------------------------------------
digitalRead ; on entry digitalPin is the pin to read, returns value in carry
movlw HIGH digRdTab
movwf PCLATH
movf digitalPin,w
bcf STATUS,C
addwf PCL,f
digRdTab
goto digitalRead0
goto digitalRead1
goto digitalRead2
goto digitalRead3
goto digitalRead4
goto digitalRead5
goto digitalRead6
goto digitalRead7
goto digitalRead8
goto digitalRead9
goto digitalRead10
goto digitalRead11
goto digitalRead12
goto digitalRead13
; -------------------------------------------------------------------------
setPinToIn
; digitalPinStatus = digitalPinStatus &~ (1 << pin);
; pwmStatus = pwmStatus &~ (1 << pin);
; pinMode(pin,INPUT);
movlw HIGH pinintab
movwf PCLATH
movf pin,w
addwf PCL,f
pinintab
goto setPinZeroToIn
goto setPinOneToIn
goto setPinTwoToIn
goto setPinThreeToIn
goto setPinFourToIn
goto setPinFiveToIn
goto setPinSixToIn
goto setPinSevenToIn
goto setPinEightToIn
goto setPinNineToIn
goto setPinTenToIn
goto setPinElevenToIn
goto setPinTwelveToIn
goto setPinThirteenToIn
; -------------------------------------------------------------------------
setPinToOut
movlw HIGH pinoutTab
movwf PCLATH
movf pin,w
addwf PCL,f
pinoutTab
goto setPinZeroToOut
goto setPinOneToOut
goto setPinTwoToOut
goto setPinThreeToOut
goto setPinFourToOut
goto setPinFiveToOut
goto setPinSixToOut
goto setPinSevenToOut
goto setPinEightToOut
goto setPinNineToOut
goto setPinTenToOut
goto setPinElevenToOut
goto setPinTwelveToOut
goto setPinThirteenToOut
; -------------------------------------------------------------------------
setPinToPwm
movlw HIGH pinpwmTab
movwf PCLATH
movf pin,w
addwf PCL,f
pinpwmTab
goto setPinZeroToPWM
goto setPinOneToPWM
goto setPinTwoToPWM
goto setPinThreeToPWM
goto setPinFourToPWM
goto setPinFiveToPWM
goto setPinSixToPWM
goto setPinSevenToPWM
goto setPinEightToPWM
goto setPinNineToPWM
goto setPinTenToPWM
goto setPinElevenToPWM
goto setPinTwelveToPWM
goto setPinThirteenToPWM
; -------------------------------------------------------------------------
analogRead ; analogRead sets analogDataHi and analogDataLo according to analogPin
movlw HIGH analogRdTab
movwf PCLATH
movf analogPin,w
addwf PCL,f
analogRdTab
goto analogRead0
goto analogRead1
goto analogRead2
goto analogRead3
goto analogRead4
goto analogRead5
; -------------------------------------------------------------------------
doMultiByteCommand
; switch(executeMultiByteCommand)
; {
movlw HIGH mbctab
movwf PCLATH
movlw DISABLE_PWM ; 250
subwf executeMultiByteCommand,w ; remove offset of 250
addwf PCL,f
mbctab
goto mb_disablePwm ; 250
goto mb_enablePwm ; 251
goto mb_disableSoftPwm ; 252
goto mb_enableSoftPwm ; 253
goto mb_setSoftPwmFreq ; 254
; -------------------------------------------------------------------------
;
END ; directive 'end of program'
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