;PIC Microcontoller Basic Math Method
;Mainly Maths Macros for PIC18F458 (16bit & some 32bit)
;By Roger Froud
;Overview...
;This approach to handling 16bit maths is borrowed from Microchips
;Embedded Control Handbook where it is flirted with but not generalised
;or published in any useful form.
;The aim is to provide the user with 16bit pseudo registers in RAM
;that behave very much like an extended native 16bit instuction set.
;You can create your own 16 bit variables by reserving 2 consecutive bytes
;and then freely mix them with the 16bit macros.
;This allows you to have as many 16bit files as you need while allowing
;easy manipulation of their values using the macros.
;The only downside of this approach is that it exposes a nasty bug in MPLAB
;that has been made worse post V7.11. Up to V7.11 the assembler often shows
;errors listed against the wrong line numbers. It does single step correctly
;through the macros though. By V7.31, the assembler not only gives the wrong
;line numbers but MPLAB no longer shows the correct lines while stepping
;through the macros. The code still works fine but you don't see the
;lines that are being executed. Microchip have acknowledged this problem
;so perhaps they will at last get both these problems sorted out.
;These macros have been tested and published here in good faith but
;no liability can be accepted for any inaccuracies.
;Please feel free to correct, improve or add to these for the greater good.
;Caution:-
;Do not assume that the W register or status registers are preserved
;unless specifically mentioned.
;Don't forget that these routines use memory pairs which can be
;corrupted if you use these macros in interrupt routines as well
;as in the main body of the code. You are responsible for storing
;their contents. Beware High & Low level interrupts that may need to
;store their own copies. The code routines are shown below are complete
;to show what resources would be used if you used all of the macros.
;Typically you will only have definitions for ACCaLO & ACCaHI
;If you forget to allocate memory for them, the assembler will complain
;so you could just use the macros and let the assembler tell you
;what definitions you need to include.
;The pseudo registers are normally stored in Access RAM so that they
;are readily available without Bank switching.
;Beware changing macro names as some are used in other macros
;16 Bit Pseudo register definitions. LS & MS explicitly defined
;so they can be accessed by macros
;ACCaLO RES 1 ;LS of accumulator 'a'
;ACCaHI RES 1 ;MS
;ACCbLO RES 1 ;LS of accumulator 'b'
;ACCbHI RES 1 ;MS
;ACCcLO RES 1 ;LS of accumulator 'c'
;ACCcHI RES 1 ;MS
;ACCdLO RES 1 ;LS of accumulator 'd'
;ACCdHI RES 1 ;MS
;M_TEMP RES 1 ;Temp counter for 16bit/16bit maths routines
;The following are only required for 16bit x 16bit multiplication
;RES0 RES 1 ;LS Destination for multiply result
;RES1 RES 1
;RES2 RES 1
;RES3 RES 1 ;MS
;Beware! 2 sets of temp stores required as low priority interrupt can be interrupted by a high priority one!
;These can be defined in other banks as their data is stored using movff instructions that include the full address
;W_TEMP_L RES 1 ; variable used for context saving durng interrupts
;W_TEMP_H RES 1 ; variable used for context saving durng interrupts
;NB:- STATUS_TEMP etc in another bank to save acces bank space
;M_TEMP_L RES 1 ;Counter for some maths routines (check if you are using it by leaving it out)
;M_TEMP_H RES 1 ;Counter for some maths routines (check if you are using it by leaving it out)
;ACCaLO_TEMP_L RES 1 ; for context saving LS of accumulator 'A'
;ACCaHI_TEMP_L RES 1 ; for context saving MS
;ACCbLO_TEMP_L RES 1 ; for context saving LS of accumulator 'b'
;ACCbHI_TEMP_L RES 1 ; for context saving MS
;ACCcLO_TEMP_L RES 1 ; for context saving LS of accumulator 'c'
;ACCcHI_TEMP_L RES 1 ; for context saving MS
;ACCdLO_TEMP_L RES 1 ; for context saving LS of accumulator 'd'
;ACCdHI_TEMP_L RES 1 ; for context saving MS
;The following are only required for 16bit x 16bit multiplication
;RES0_L RES 1 ;LS Destination for multiply result
;RES1_L RES 1
;RES2_L RES 1
;RES3_L RES 1 ;MS
;ACCaLO_TEMP_H RES 1 ; for context saving LS of accumulator 'A'
;ACCaHI_TEMP_H RES 1 ; for context saving MS
;ACCbLO_TEMP_H RES 1 ; for context saving LS of accumulator 'b'
;ACCbHI_TEMP_H RES 1 ; for context saving MS
;ACCcLO_TEMP_H RES 1 ; for context saving LS of accumulator 'b'
;ACCcHI_TEMP_H RES 1 ; for context saving MS
;ACCdLO_TEMP_H RES 1 ; for context saving LS of accumulator 'b'
;ACCdHI_TEMP_H RES 1 ; for context saving MS
;The following are only required for 16bit x 16bit multiplication
;RES0_H RES 1 ;LS Destination for multiply result
;RES1_H RES 1
;RES2_H RES 1
;RES3_H RES 1 ;MS
;Use same style definition for High priority interrupt but change the _L to _H for variables
;LOWINT MOVWF W_TEMP_L ;Copy W register else it will be corrupted
; MOVFF STATUS,STATUS_TEMP_L ;save status
; MOVFF BSR,BSR_TEMP_L ;Save BSR register
; ;Leave out any or all of the following if macros
; ;are not used in the interrupt routine. Just check the
; ;macros to see what they use.
; MOVFF ACCaLO,ACCaLO_TEMP_L ;Save my pseudo registers for 16 bit macros
; MOVFF ACCaHI,ACCaHI_TEMP_L ;Save my pseudo registers for 16 bit macros
; MOVFF ACCbLO,ACCbLO_TEMP_L ;Save my pseudo registers for 16 bit macros
; MOVFF ACCbHI,ACCbHI_TEMP_L ;Save my pseudo registers for 16 bit macros
; MOVFF ACCcLO,ACCaLO_TEMP_L ;Save my pseudo registers for 16 bit macros
; MOVFF ACCcHI,ACCaHI_TEMP_L ;Save my pseudo registers for 16 bit macros
; MOVFF ACCdLO,ACCbLO_TEMP_L ;Save my pseudo registers for 16 bit macros
; MOVFF ACCdHI,ACCbHI_TEMP_L ;Save my pseudo registers for 16 bit macros
; MOVFF M_TEMP,M_TEMP_L ;Save counter
; MOVFF RES0,RES0_L ;Save 32bit result of 16 x 16 bit multiply
; MOVFF RES1,RES1_L
; MOVFF RES2,RES2_L
; MOVFF RES3,RES3_L
;
; body of low priority interrupt
;
; MOVFF RES3_L,RES3
; MOVFF RES2_L,RES2
; MOVFF RES1_L,RES1
; MOVFF RES0_L,RES0
; MOVFF M_TEMP_L,M_TEMP ;Restore counter
; MOVFF ACCdHI_TEMP_L,ACCbHI ;Restore my pseudo registers for 16 bit macros
; MOVFF ACCdLO_TEMP_L,ACCbLO
; MOVFF ACCcHI_TEMP_L,ACCbHI ;Restore my pseudo registers for 16 bit macros
; MOVFF ACCcLO_TEMP_L,ACCbLO
; MOVFF ACCbHI_TEMP_L,ACCbHI ;Restore my pseudo registers for 16 bit macros
; MOVFF ACCbLO_TEMP_L,ACCbLO
; MOVFF ACCaHI_TEMP_L,ACCaHI ;Restore my pseudo registers for 16 bit macros
; MOVFF ACCaLO_TEMP_L,ACCaLO
; MOVFF BSR_TEMP_L,BSR ;Restore BSR register
; MOVF W_TEMP_L,W ;Restore W reg.
; MOVFF STATUS_TEMP_L,STATUS ;Restore status reg.
; RETFIE ;back to interrupted program
;16 bit pseudo-register macro definitions
;Test accumulator and set Z flag if zero & c flag if MS bit set
;Corrupts W reg.
TSTA MACRO
TSTF16 ACCaLO
ENDM
;Test accumulator and set Z flag if zero & c flag if MS bit set
;Corrupts W reg.
TSTB MACRO
TSTF16 ACCbLO
ENDM
;Test 16 bit file and set Z flag if zero
;Corrupts W reg.
TSTF16 MACRO ADDRESS
BCF STATUS,C
BTFSC ADDRESS+1,7 ;Set carry if MS bit=1
BSF STATUS,C ;None of the following changes Carry
MOVF ADDRESS,W ;get LS
IORWF ADDRESS+1,W ;Z flag set if both zero
ENDM
TSTW MACRO
IORLW 0
ENDM
;Make accumulator +ve if -ve (assuming signed numbers of course)
ABSA MACRO
ABSF16 ACCaLO
ENDM
;Make 16bit file +ve if -ve (assuming signed numbers of course)
ABSF16 MACRO ADDRESS
LOCAL PLUSNOW
BTFSS ADDRESS+1,7 ;MS byte
GOTO PLUSNOW
NEGF16 ADDRESS
PLUSNOW
ENDM
;Moves 16bit file in LS/MS format to Accumulator A
MOVFA MACRO ADDRESS
MOVF16 ADDRESS,ACCaLO
ENDM
;Moves Accumulator A to Accumulator B
MOVAB MACRO
MOVF16 ACCaLO,ACCbLO
ENDM
;Moves 16bit file in LS/MS format from Accumulator A
MOVAF MACRO ADDRESS
MOVF16 ACCaLO,ADDRESS
ENDM
;moves 16bit file in LS/MS format to Accumulator B
MOVFB MACRO ADDRESS
MOVF16 ADDRESS,ACCbLO ;Move LS
ENDM
;moves 16bit file in LS/MS format from Accumulator B
MOVBF MACRO ADDRESS
MOVF16 ACCbLO,ADDRESS
ENDM
;moves 16bit file in LS/MS format to Accumulator C
MOVFC MACRO ADDRESS
MOVF16 ADDRESS,ACCcLO
ENDM
;moves 16bit file in LS/MS format from Accumulator C
MOVCF MACRO ADDRESS
MOVF16 ACCcLO,ADDRESS
ENDM
;moves 16bit file in LS/MS format to Accumulator D
MOVFD MACRO ADDRESS
MOVF16 ADDRESS,ACCdLO
ENDM
;moves 16bit file in LS/MS format from Accumulator D
MOVDF MACRO ADDRESS
MOVF16 ACCdLO,ADDRESS
ENDM
;Moves 16 bit literal to accumulator A
MOVLAA MACRO VALUE
MOVLW LOW VALUE
MOVWF ACCaLO
MOVLW HIGH VALUE
MOVWF ACCaHI
ENDM
;Moves 16 bit literal to accumulator B
MOVLAB MACRO VALUE
MOVLW LOW VALUE
MOVWF ACCbLO
MOVLW HIGH VALUE
MOVWF ACCbHI
ENDM
;Moves 16 bit literal to accumulator C
MOVLAC MACRO VALUE
MOVLW LOW VALUE
MOVWF ACCcLO
MOVLW HIGH VALUE
MOVWF ACCcHI
ENDM
;Moves 16 bit literal to accumulator D
MOVLAD MACRO VALUE
MOVLW LOW VALUE
MOVWF ACCdLO
MOVLW HIGH VALUE
MOVWF ACCdHI
ENDM
;Moves 8 bit literal to file (corrupts W)
MOVLF MACRO VALUE,ADDRESS
MOVLW VALUE
MOVWF ADDRESS
ENDM
;Make file absolute
ABSF MACRO ADDRESS
BTFSC ADDRESS,7 ;-ve?
NEGF ADDRESS ;Make -ve into +ve
ENDM
;Moves 16 bit literal to file
;NB:-Done MS first to writes to 16bit timers work correctly.
;You can't use this for reading 16 bit timers, you must reverse the order!
MOVLF16 MACRO VALUE,ADDRESS
MOVLW HIGH VALUE
MOVWF ADDRESS+1 ;MS
MOVLW LOW VALUE
MOVWF ADDRESS ;LS
ENDM
;Moves 16 bit file to file. Uses MOVFF so it is page independant
;NB:-Done MS first to writes to 16bit timers work correctly.
;You can't use this for reading 16 bit timers, you must reverse the order!
MOVF16 MACRO ADDRESS,ADDRESS1
MOVFF ADDRESS+1,ADDRESS1+1 ;MS
MOVFF ADDRESS,ADDRESS1 ;LS
ENDM
;Add 16 bit file to accumulator A
ADDFA MACRO ADDRESS ;a+f->a
MOVF ADDRESS,W
ADDWF ACCaLO,F
MOVF ADDRESS+1,W
ADDWFC ACCaHI,F
ENDM
;Add accumulator A to 16 bit file
ADDAF MACRO ADDRESS ;f+a->f
MOVF ACCaLO,W
ADDWF ADDRESS,F ;Save LS back to file
MOVF ACCaHI,W
ADDWFC ADDRESS+1,F
ENDM
;Add 16 bit file to accumulator B
ADDFB MACRO ADDRESS ;b+f->b
MOVF ADDRESS,W
ADDWF ACCbLO,F
MOVF ADDRESS+1,W
ADDWFC ACCbHI,F
ENDM
;Add literal to accumulator 'A'
ADDLA MACRO VALUE ;a+l->a
MOVLW LOW VALUE
ADDWF ACCaLO,F
MOVLW HIGH VALUE
ADDWFC ACCaHI,F
ENDM
;Add literal to file'
ADDLF16 MACRO VALUE,ADDRESS ;f+l->f
MOVLW LOW VALUE
ADDWF ADDRESS,F
MOVLW HIGH VALUE
ADDWFC ADDRESS+1,F
ENDM
;Subtract 16 bit file from 'A' result in 'A'
SUBFA MACRO ADDRESS ;See AN526
MOVF ADDRESS,W
SUBWF ACCaLO,F
MOVF ADDRESS+1,W
SUBWFB ACCaHI,F
ENDM
;Subtract 16 bit file ADDRESS from 16 bit file ADDRESS1. result in ADDRESS1
SUBF16 MACRO ADDRESS,ADDRESS1 ;See AN526
MOVF ADDRESS,W
SUBWF ADDRESS1,F
MOVF ADDRESS+1,W
SUBWFB ADDRESS1+1,F
ENDM
;Subtract 16 bit literal from 'A' result in 'A'
SUBLA MACRO VALUE ;a-l->a
MOVLW LOW VALUE
SUBWF ACCaLO,F
MOVLW HIGH VALUE
SUBWFB ACCaHI,F
ENDM
;Subtract 16 bit file from 'B' result in 'B'
SUBFB MACRO ADDRESS ;See AN526
MOVF ADDRESS,W
SUBWF ACCbLO,F
MOVF ADDRESS+1,W
SUBWFB ACCbHI,F
ENDM
;Subtract 16 bit literal from 'B' result in 'B'
SUBLB MACRO VALUE ;b-l->b
MOVLW LOW VALUE
SUBWF ACCbLO,F
MOVLW HIGH VALUE
SUBWFB ACCbHI,F
ENDM
;Subtract 16 bit literal from 'f' result in 'f'
SUBLF16 MACRO VALUE,ADDRESS ;f-l->f
MOVLW LOW VALUE
SUBWF ADDRESS,F
MOVLW HIGH VALUE
SUBWFB ADDRESS+1,F
ENDM
;Unsigned Compare of 16 bit file with 'A' (A-f)
;Set carry & zero flags to reflect unsigned 16bit result
;so we can use BLT macros etc the same as for signed compare
CMPFAU MACRO ADDRESS ;See signed compare below
LOCAL NOCHK
LOCAL LSCHK
MOVF ADDRESS+1,W ;ms
SUBWF ACCaHI,W ;check if File > A
BZ LSCHK ;continue if File=A
GOTO NOCHK ;ms result tells all
LSCHK MOVF ADDRESS,W ;ms same so LS tells all
SUBWF ACCaLO,W ;carry set if A > File
NOCHK
ENDM
;Unsigned Compare of 16 bit file with Literal (L-f)
;Set carry & zero flags to reflect unsigned 16bit result
;so we can use BLT macros etc the same as for signed compare
CMPFLU MACRO VALUE,ADDRESS ;See signed compare below
LOCAL NOCHK
LOCAL LSCHK
MOVF ADDRESS+1,W ;ms
SUBLW HIGH VALUE ;check if File > L
BZ LSCHK ;continue if File=L
GOTO NOCHK ;ms result tells all
LSCHK MOVF ADDRESS,W ;ms same so LS tells all
SUBLW LOW VALUE ;carry set if L > File
NOCHK
ENDM
;Compare signed 16 bit file with 'A' (A-f)
;Using biased (inverted sign) method to set carry & zero flags
;to reflect signed 16bit result
CMPFA MACRO ADDRESS ;See AN526
LOCAL NOCHK
LOCAL LSCHK
;first invert sign bit of accumulator
BTG ACCaHI,7 ;inverts bit
;Now do unsigned compare on biased values
MOVF ADDRESS+1,W ;ms
XORLW H'80' ;invert sign of file
SUBWF ACCaHI,W ;check if file > a (both numbers are biased)
BZ LSCHK ;continue if file=a
GOTO NOCHK ;ms result tells all
LSCHK MOVF ADDRESS,W ;ms same so LS tells all
SUBWF ACCaLO,W ;carry set if a > file
NOCHK
;Z and C bits now set but we must repair accumulator sign without
;corrupting the Z flag
BTG ACCaHI,7 ;inverts bit
ENDM
;Compare signed 16 bit accumulator with literal (A-L)
;Using biased (inverted sign) method to set carry & zero flags
;to reflect signed 16bit result
CMPLA MACRO VALUE
LOCAL NOCHK
LOCAL LSCHK
;first invert sign bit of accumulator
BTG ACCaHI,7 ;inverts bit
;Now do unsigned compare on biased values
MOVLW HIGH VALUE ;ms
XORLW H'80' ;invert sign of value
SUBWF ACCaHI,W ;check if value > a (both numbers are biased)
BZ LSCHK ;continue if file=a
GOTO NOCHK ;ms result tells all
LSCHK MOVLW LOW VALUE ;ms same so LS tells all
SUBWF ACCaLO,W ;carry set if a > value
NOCHK
;Z and C bits now set but we must repair accumulator sign without corrupting the Z flag
BTG ACCaHI,7 ;inverts bit
ENDM
;Compare unsigned 16 bit accumulator with literal (A-L)
;carry & zero flags reflect unsigned 16bit result
CMPLAU MACRO VALUE
LOCAL NOCHK
LOCAL LSCHK
MOVLW HIGH VALUE ;ms
SUBWF ACCaHI,W ;check if value > a (both numbers are biased)
BZ LSCHK ;continue if file=a
GOTO NOCHK ;ms result tells all
LSCHK MOVLW LOW VALUE ;ms same so LS tells all
SUBWF ACCaLO,W ;carry set if a > value
NOCHK
ENDM
;Compare signed 16 bit file with 16 bit file (f2-f1)
;Using biased (inverted sign) method to set carry & zero flags
;to reflect signed 16bit result
CMPFF16 MACRO ADDRESS1,ADDRESS2 ;See AN526
LOCAL NOCHK
LOCAL LSCHK
;first invert sign bit of accumulator
BTG ADDRESS2+1,7 ;inverts bit
;Now do unsigned compare on biased values
MOVF ADDRESS1+1,W ;ms
XORLW H'80' ;invert sign of file
SUBWF ADDRESS2+1,W ;check if file > file (both numbers are biased)
BZ LSCHK ;continue if file=file
GOTO NOCHK ;ms result tells all
LSCHK MOVF ADDRESS1,W ;ms same so LS tells all
SUBWF ADDRESS2,W ;carry set if a > file
NOCHK
;Z and C bits now set but we must repair accumulator sign without
;corrupting the Z flag
BTG ADDRESS2+1,7 ;inverts bit
ENDM
;Unsigned compare 16 bit file with 16 bit file (f2-f1)
;carry & zero flags reflect unsigned 16bit result
CMPFFU16 MACRO ADDRESS1,ADDRESS2 ;See AN526
LOCAL NOCHK
LOCAL LSCHK
MOVF ADDRESS1+1,W ;ms
SUBWF ADDRESS2+1,W ;check if file > file
BZ LSCHK ;continue if file=file
GOTO NOCHK ;ms result tells all
LSCHK MOVF ADDRESS1,W ;ms same so LS tells all
SUBWF ADDRESS2,W ;carry set if a > file
NOCHK
ENDM
;Compare unsigned 16 bit file with literal (F-L)
;carry & zero flags reflect unsigned 16bit result
CMPLFU16 MACRO VALUE,ADDRESS
LOCAL NOCHK
LOCAL LSCHK
MOVLW HIGH VALUE ;ms
SUBWF ADDRESS+1,W ;check if file > l
BZ LSCHK ;continue if file=l
GOTO NOCHK ;ms result tells all
LSCHK MOVLW LOW VALUE ;ms same so LS tells all
SUBWF ADDRESS,W ;carry set if l > value
NOCHK
ENDM
;Compare signed 16 bit file with literal (F-L)
;Using biased (inverted sign) method to set carry & zero flags
;to reflect signed 16bit result
CMPLF16 MACRO VALUE,ADDRESS
LOCAL NOCHK
LOCAL LSCHK
;first invert sign bit of accumulator
BTG ACCaHI,7 ;inverts bit
;Now do unsigned compare on biased values
MOVLW HIGH VALUE ;ms
XORLW H'80' ;invert sign of file
SUBWF ADDRESS+1,W ;check if file > a (both numbers are biased)
BZ LSCHK ;continue if file=a
GOTO NOCHK ;ms result tells all
LSCHK MOVLW LOW VALUE ;ms same so LS tells all
SUBWF ADDRESS,W ;carry set if a > value
NOCHK
;Z and C bits now set but we must repair file sign without corrupting the Z flag
BTG ADDRESS+1,7 ;inverts bit
ENDM
;Branch if >
BGT MACRO ADDRESS
LOCAL ONE
BTFSC STATUS,Z
GOTO ONE ;Equal so not >
BTFSC STATUS,C ;Take branch if Carry clear
GOTO ADDRESS
ONE
ENDM
;Branch if <
BLT MACRO ADDRESS
LOCAL ONE
BTFSC STATUS,Z
GOTO ONE ;Equal so not <
BTFSS STATUS,C ;Take branch if carry set
GOTO ADDRESS
ONE
ENDM
;Branch if >=
BGE MACRO ADDRESS
LOCAL ONE
BTFSC STATUS,C ;Take branch if carry clear
GOTO ONE
BTFSC STATUS,Z ;Take branch if not zero
ONE GOTO ADDRESS
ENDM
;Branch if <=
BLE MACRO ADDRESS
LOCAL ONE
BTFSS STATUS,C ;Take branch if carry set
GOTO ONE
BTFSC STATUS,Z ;Take branch if not zero
ONE GOTO ADDRESS
ENDM
;Negate accumulator A
NEGA MACRO ;2's comp.
NEGF16 ACCaLO
ENDM
;Negate accumulator B
NEGB MACRO ;2's comp.
NEGF16 ACCbLO
ENDM
;Negate 16 bit file
NEGF16 MACRO ADDRESS ;See AN526 P5-14 2's comp.
COMF ADDRESS,F ;LS
INCF ADDRESS,F
BTFSC STATUS,Z
DECF ADDRESS+1,F ;MS
COMF ADDRESS+1,F
ENDM
;Clip 'A' to signed 15bits so that 2 of these added together
;can never exceed 16bits signed. The result can then be clipped itself
CLIPA15 MACRO
LOCAL CLIPPLU
LOCAL SATDAT
BTFSS ACCaHI,7 ;Test if -ve (ms bit set)
GOTO CLIPPLU
;This way if -ve
BTFSC ACCaHI,6
GOTO SATDAT
MOVLAA H'C000'
GOTO SATDAT
;-----------------------
;This way to clip plus
CLIPPLU BTFSS ACCaHI,6
GOTO SATDAT
MOVLAA H'3FFF'
SATDAT
ENDM
;Clip 'A' to signed 14bits to limit swings in control system
CLIPA14 MACRO
LOCAL CLIPPLU
LOCAL SATDAT
LOCAL NEGCLIP
LOCAL POSCLIP
BTFSS ACCaHI,7 ;Test if -ve (ms bit set)
GOTO CLIPPLU
;This way if -ve
BTFSS ACCaHI,6
GOTO NEGCLIP
BTFSC ACCaHI,5
GOTO SATDAT
NEGCLIP MOVLAA H'E000'
GOTO SATDAT
;-----------------------
;This way to clip plus
CLIPPLU BTFSC ACCaHI,6
GOTO POSCLIP
BTFSS ACCaHI,5
GOTO SATDAT
POSCLIP MOVLAA H'1FFF'
SATDAT
ENDM
;Clip A to the value in F ie if A>F then A=F
CLIPAF MACRO ADDRESS
LOCAL NOCLIP
NOP
CMPFA ADDRESS ;Is it > clip value?
BLT NOCLIP
NOP
MOVFA ADDRESS ;Use clip value
NOCLIP
ENDM
;Clip A to the Literal value ie if A>L then A=L
CLIPAL MACRO VALUE
LOCAL NOCLIP
NOP
CMPLA VALUE ;Is it > clip value?
BLT NOCLIP
NOP
MOVLAA VALUE ;Use clip value
NOCLIP
ENDM
;Clip F to A
CLIPFA MACRO ADDRESS
LOCAL NOCLIP
CMPFA ADDRESS ;Is it < clip value?
BGE NOCLIP
MOVAF ADDRESS ;Use clip value
NOCLIP
ENDM
;Increment 16 bit file and test if zero
INCF16 MACRO ADDRESS
INCF ADDRESS,F
BTFSC STATUS,Z
INCF ADDRESS+1,F
TSTF16 ADDRESS
ENDM
;Increment accumulator 'A' and test if zero
INCA MACRO
INCF16 ACCaLO
ENDM
;Increment accumulator 'B' and test if zero
INCB MACRO
INCF16 ACCbLO
ENDM
;Decrement accumulator 'A' and test if zero
DECA MACRO
DECF16 ACCaLO
ENDM
;Decrement accumulator 'B' and test if zero
DECB MACRO
DECF16 ACCbLO
ENDM
;The following are Used for timers in interrupt routine which
;are then polled outside
;Decrement 16 bit file and test if zero
DECF16 MACRO ADDRESS
LOCAL NBORROW
TSTFSZ ADDRESS ;LS
GOTO NBORROW
DECF ADDRESS+1,F ;MS
NBORROW DECF ADDRESS,F ;LS
TSTF16 ADDRESS
ENDM
;Decrement A to zero if not already zero
DECATZ MACRO
DECFTZ16 ACCaLO
ENDM
;Decrement B to zero if not already zero
DECBTZ MACRO
DECFTZ16 ACCbLO
ENDM
;Decrement 8 bit file if not already zero
;Sets Z bit to suit
DECFTZ MACRO ADDRESS
TSTFSZ ADDRESS ;Aready zero
DECF ADDRESS,F
TSTF ADDRESS
ENDM
;Decrement 16 bit file if not already zero
DECFTZ16 MACRO ADDRESS
LOCAL ZEXIT
TSTF16 ADDRESS
BTFSC STATUS,Z
GOTO ZEXIT
;This way if not zero so decrement it
DECF16 ADDRESS
ZEXIT
ENDM
;XOR 16 bit file with accumulator 'A', result in 'A'
XORFA MACRO ADDRESS
MOVF ADDRESS,W
XORWF ACCaLO,F
MOVF ADDRESS+1,W
XORWF ACCaHI,F
TSTA ;use previous macro
ENDM
;XOR literal with accumulator 'A', result in 'A'
XORLA MACRO VALUE
MOVLW LOW VALUE
XORWF ACCaLO,F
MOVLW HIGH VALUE
XORWF ACCaHI,F
TSTA ;use previous macro
ENDM
;clears the 16bit file in LS/MS format
CLRF16 MACRO ADDRESS
CLRF ADDRESS ;Clear LS
CLRF ADDRESS+1 ;MS
ENDM
;clears the accumulator 'A'
CLRA MACRO
CLRF16 ACCaLO ;Clear LS/MS
ENDM
;Sets the accumulator 'A'
SETA MACRO
SETF16 ACCaLO ;Clear LS/MS
ENDM
;Set 16bit file
SETF16 MACRO ADDRESS
SETF ADDRESS
SETF ADDRESS+1
ENDM
;clears the accumulator 'B'
CLRB MACRO
CLRF16 ACCbLO ;Clear LS/MS
ENDM
;Sets the accumulator 'B'
SETB MACRO
SETF16 ACCaLO ;Clear LS/MS
ENDM
;clears the accumulator 'C'
CLRAC MACRO
CLRF16 ACCcLO ;Clear LS/MS
ENDM
;clears the accumulator 'B'
CLRD MACRO
CLRF16 ACCdLO ;Clear LS/MS
ENDM
;clears the 24bit file in LS/MS format
CLRF24 MACRO ADDRESS
CLRF ADDRESS ;Clear LS
CLRF ADDRESS+1
CLRF ADDRESS+2 ;MS
ENDM
;Shift 16 bit file left one bit
LSLF16 MACRO ADDRESS
CLRC ;so it won't corrupt LS bit
RLCF ADDRESS,F ;LS setting carry as appropriate
RLCF ADDRESS+1,F ;MS with any carry from LS byte
ENDM
;Shift 16bit accumulator left 1 bit
LSLA MACRO ;See LSLF16 for comments
LSLF16 ACCaLO
ENDM
;Shift 16bit accumulator left 1 bit
LSLB MACRO ;See LSLF16 for comments
LSLF16 ACCbLO
ENDM
;Shift 16 bit file right one bit
LSRF16 MACRO ADDRESS
CLRC ;so it won't corrupt MS bit
RRCF ADDRESS+1,F ;MS setting carry as appropriate
RRCF ADDRESS,F ;LS with any carry from MS byte
ENDM
;Logical Shift 16bit accumulator right 1 bit
LSRA MACRO ;See LSLF16 for comments
LSRF16 ACCaLO
ENDM
;Logical Shift 16bit accumulator right 1 bit
LSRB MACRO ;See LSLF16 for comments
LSRF16 ACCbLO
ENDM
;Logical Shift 32bits right where 'B' holds MS and 'A' holds LS part
LSRBA MACRO
RLCF ACCbHI,W ;Get Sign bit into carry without corrupting file
RRCF ACCbHI,F
RRCF ACCbLO,F
RRCF ACCaHI,F
RRCF ACCaLO,F
ENDM
;Logical shift right 32bit number by 8 bits through 'B' and 'A'
;where 'B' holds MS and 'A' holds LS
LSRBA8 MACRO
MOVFF ACCaHI,ACCaLO
MOVFF ACCbLO,ACCaHI
MOVFF ACCbHI,ACCbLO
CLRF ACCbHI
ENDM
;Arithmetic shift right 32bit number by 8 bits through 'B' and 'A'
;where 'B' holds MS and 'A' holds LS
ASRBA8 MACRO
MOVFF ACCaHI,ACCaLO
MOVFF ACCbLO,ACCaHI
MOVFF ACCbHI,ACCbLO
CLRF ACCbHI
BTFSC ADDRESS+1,7 ;If original MS bit is set
SETF ACCbHI ;Then new MS is all 1's
ENDM
;Increment 32bits in 'B' MS and 'A' LS
INCBA MACRO
INCF ACCaLO,F
BTFSC STATUS,Z
INCF ACCaHI,F
BTFSC STATUS,Z
INCF ACCbLO,F
BTFSC STATUS,Z
INCF ACCbHI,F
ENDM
;Arithmetic Shift 16 bit file right one bit
;Same as logical shift except MS bit is copied into new MS bit
ASRF16 MACRO ADDRESS
CLRC
BTFSC ADDRESS+1,7 ;If MS bit is set
SETC ;Then set carry ready for copying
RRCF ADDRESS+1,F ;MS setting carry as appropriate
RRCF ADDRESS,F ;LS with any carry from MS byte
ENDM
;Arithmetic Shift 16bit accumulator right 1 bit
;Same as logical shift except MS bit is copied into new MS bit
ASRA MACRO
ASRF16 ACCaLO
ENDM
;Add source file to destination file (corrupts W reg)
ADDFF MACRO ADDRSRC,ADDRDEST
MOVF ADDRSRC,W
ADDWF ADDRDEST,F
ENDM
;Add source file to destination file with carry (corrupts W reg)
ADDFFC MACRO ADDRSRC,ADDRDEST
MOVF ADDRSRC,W
ADDWFC ADDRDEST,F
ENDM
;Add literal to designated file (corrupts W reg)
ADDLF MACRO ADDRESS,VALUE
MOVLW VALUE
ADDWF ADDRESS,F
ENDM
;Add literal with carry to designated file (corrupts W reg)
ADDLFC MACRO ADDRESS,VALUE
MOVLW VALUE
ADDWFC ADDRESS,F
ENDM
;Double precision unsigned 16x16 bit multiplication of accumulator x file
;with LS result in accumulator 'a'
;and MS result in accumulator 'b'
;NB:-Uses RES0:RES3 so don't use it in interrupt routine as well as
;in main loop without saving RES0:RES3 context
MULFA MACRO ADDRESS
MULFA16 ADDRESS ;Unsigned multiply
MOVF32 RES0,ACCaLO ;Get result in accumulator pair 'ab'
ENDM
;Double precision Signed 16x16 bit multiplication of accumulator x file
;with LS result in accumulator 'a'
;and MS result in accumulator 'b'
;NB:-Uses RES0:RES3 so don't use it in interrupt routine as well as
;in main loop without saving RES0:RES3 context
MULFAS MACRO ADDRESS
MULFA16S ADDRESS ;Signed multiply
MOVF32 RES0,ACCaLO ;Get result in accumulator pair 'ab'
ENDM
;Unsigned multiply accumulator 'a' by file, answer in RES0:RES3
;Copied from PIC18FXX8 manual P76
;NB:-Uses RES0:RES3 so don't use it in interrupt routine as well as
;in main loop without saving RES0:RES3 context
MULFA16 MACRO ADDRESS
MOVF ACCaLO,W
MULWF ADDRESS
MOVFF PRODH,RES1
MOVFF PRODL,RES0
MOVF ACCaHI,W
MULWF ADDRESS+1
MOVFF PRODH,RES3
MOVFF PRODL,RES2
MOVF ACCaLO,W
MULWF ADDRESS+1
MOVF PRODL,W
ADDWF RES1
MOVF PRODH,W
ADDWFC RES2
CLRF WREG
ADDWFC RES3
MOVF ACCaHI,W
MULWF ADDRESS
MOVF PRODL,W
ADDWF RES1
MOVF PRODH,W
ADDWFC RES2
CLRF WREG
ADDWFC RES3
ENDM
;Signed multiply accumulator 'a' by file, answer in RES0:RES3
MULFA16S MACRO ADDRESS
LOCAL SIGN_ARG1
LOCAL CONT_CODE
MULFA16 ADDRESS ;Unsigned multiply
;Now handle signs
BTFSS ADDRESS+1,7
BRA SIGN_ARG1
MOVF ACCaLO,W
SUBWF RES2
MOVF ACCaHI,W
SUBWFB RES3
SIGN_ARG1
BTFSS ACCaHI,7
BRA CONT_CODE
MOVF ADDRESS,W
SUBWF RES2
MOVF ADDRESS+1,W
SUBWFB RES3
CONT_CODE
ENDM
;Double Precision unsigned 16/16 division ACCb/ACCa->ACCb with remainder in ACCc
;Source modified from AN526 P5-36
;Beware, make sure that ACCb > ACCa
;Beware,don't use Div routine in interrupt routines as it uses M_TEMP unless you save it
;Uses register 'd'
DIVBA MACRO
LOCAL DLOOP
LOCAL NOCHK
LOCAL NOGO
;First move 16 bit register b to register d
; INTERRUPTS_OFF ;Make sure it doesn't change between reading MS & LS halves!
MOVFF ACCbHI,ACCdHI ;MS
MOVFF ACCbLO,ACCdLO ;LS
; INTERRUPTS_ON
;And clear register b
CLRF ACCbHI
CLRF ACCbLO
;Also clear register c
CLRF ACCcHI
CLRF ACCcLO
;And setup loop counter
MOVLW .16
MOVWF M_TEMP
DLOOP BCF STATUS,C
RLCF ACCdLO,F
RLCF ACCdHI,F
RLCF ACCcLO,F
RLCF ACCcHI,F
MOVF ACCaHI,W
SUBWF ACCcHI,W ;Check if a>c
BTFSS STATUS,Z ;carry set if c>a
GOTO NOCHK
MOVF ACCaLO,W
SUBWF ACCcLO,W ;If msb equal then check lsb
NOCHK BTFSS STATUS,C
GOTO NOGO
MOVF ACCaLO,W ;C-A into C
SUBWF ACCcLO,F
BTFSS STATUS,C
DECF ACCcHI,F
MOVF ACCaHI,W
SUBWF ACCcHI,F
BSF STATUS,C ;Shift a 1 into b (result)
NOGO RLCF ACCbLO,F
RLCF ACCbHI,F
DECFSZ M_TEMP,F ;Loop until all bits checked
GOTO DLOOP
ENDM
;32/16 bit division
;(ACCa,ACCb)/ACCc-> (ACCa,ACCb) rem ACCd
;Move ab pair into ef pair & clear ab pair & d
;Setup loop counter to 32
;Shift d & ef left one bit (ef ms into d ls)
;Check if c>d
;If yes then d-c->d & shift a 1 into lsb of ab (result)
;Else shift a 0 into lsb of ab (result)
;Repeat for all bits
;Double Precision unsigned 32/16 division (ACCa,ACCb)/ACCc->(ACCa,ACCb) with remainder in (ACCe,ACCf)
;Source modified from above DIVBA
;Beware, make sure that ACCb > ACCa
;Beware,don't use Div routine in interrupt routines as it uses M_TEMP unless you save it
DIVABC MACRO
LOCAL DLOOP
LOCAL NOCHK
LOCAL NOGO
;First move 32 bit register ab to register gh
; INTERRUPTS_OFF ;Make sure it doesn't change between reading each byte!
MOVF16 ACCaLO,ACCgLO ;Done as 2 lots so explicit use of Acc h makes sure it exists!
MOVF16 ACCbLO,ACChLO
; INTERRUPTS_ON
CLRAB ;Clear 32bit register pair ab that will hold the answer
CLREF ;Also clear 32 bit register pair EF
;And setup loop counter
MOVLW d'32'
MOVWF M_TEMP
DLOOP
LSLGH ;Logical shift left GH pair
RLFEFC ;into EF with carry
NOP
NOP
;if EF > C
CLRC ;Following MOVF does not affect C flag
MOVF ACCfHI,W ;F register contains overflow from E register so will always be bigger than C if non zero
BNZ SUBIT
MOVF ACCfLO,W
BNZ SUBIT
MOVF ACCcHI,W
SUBWF ACCeHI,W
BTFSS STATUS,Z
GOTO NOCHK
MOVF ACCcLO,W
SUBWF ACCeLO,W
NOCHK BTFSS STATUS,C
GOTO NOGO ;Shift a 0 into b (result)
SUBIT
MOVF ACCcLO,W ;EF-C into EF
SUBWF ACCeLO,F
MOVF ACCcHI,W
SUBWFB ACCeHI,F
CLRF WREG
SUBWFB ACCfLO,F
CLRF WREG
SUBWFB ACCfHI,F
BSF STATUS,C ;Shift a 1 into b (result)
NOGO
RLCF ACCaLO,F ;Shift 1 or 0 into result
RLCF ACCaHI,F
RLCF ACCbLO,F
RLCF ACCbHI,F
DECFSZ M_TEMP,F ;Loop until all bits checked
GOTO DLOOP
ENDM
;Start of 32Bit maths definitions
;When using register pairs eg A & B then A is LS and B is MS
MOVF32 MACRO ADDRESS,ADDRESS1
MOVFF ADDRESS,ADDRESS1
MOVFF ADDRESS+1,ADDRESS1+1
MOVFF ADDRESS+2,ADDRESS1+2
MOVFF ADDRESS+3,ADDRESS1+3
ENDM
;Move 16bit file into 32bit file & sign extend
MOVF16E32 MACRO ADDRESS,ADDRESS1
LOCAL PLUS
MOVFF ADDRESS,ADDRESS1
MOVFF ADDRESS+1,ADDRESS1+1
CLRF ADDRESS1+2
CLRF ADDRESS1+3
BTFSS ADDRESS+1,7 ;Original sign
GOTO PLUS
SETF ADDRESS1+2
SETF ADDRESS1+3
PLUS
ENDM
;Move 32bit pair AB to File MOVABF
MOVABF MACRO ADDRESS
MOVF32 ACCaLO,ADDRESS
ENDM
;Move File to 32bit pair AB
MOVFAB MACRO ADDRESS
MOVF32 ADDRESS,ACCaLO
ENDM
;Move 16 bit File to 32bit pair AB & sign extend
MOVF16EAB MACRO ADDRESS
MOVF16E32 ADDRESS,ACCaLO
ENDM
;Move 16 bit File to 32bit pair CD & sign extend
MOVF16ECD MACRO ADDRESS
MOVF16E32 ADDRESS,ACCcLO
ENDM
;Move File to 32bit pair CD
MOVFCD MACRO ADDRESS
MOVF32 ADDRESS,ACCcLO
ENDM
;Move 32bit pair CD to File
MOVCDF MACRO ADDRESS
MOVF32 ACCcLO,ADDRESS
ENDM
;Move 32bit pair AB to CD
MOVABCD MACRO
MOVF32 ACCaLO,ACCcLO
ENDM
;Move 32bit pair CD to AB
MOVCDAB MACRO
MOVF32 ACCcLO,ACCaLO
ENDM
;clears the 32bit file in LS/MS format
CLRF32 MACRO ADDRESS
CLRF ADDRESS ;Clear LS
CLRF ADDRESS+1
CLRF ADDRESS+2
CLRF ADDRESS+3 ;MS
ENDM
;Clear 32 bit register pair AB
CLRAB MACRO
CLRF32 ACCaLO
ENDM
;Clear 32 bit register pair CD
CLRCD MACRO
CLRF32 ACCcLO
ENDM
;Clear 32 bit register pair EF
CLREF MACRO
CLRF32 ACCeLO
ENDM
;Add CD to AB
ADDCDAB MACRO ;ab+cd->ab
ADDFAB ACCcLO
ENDM
;Add 32 bit file to accumulator pair AB
ADDFAB MACRO ADDRESS ;ab+f->ab
MOVF ADDRESS,W
ADDWF ACCaLO,F
MOVF ADDRESS+1,W
ADDWFC ACCaHI,F
MOVF ADDRESS+2,W
ADDWFC ACCbLO,F
MOVF ADDRESS+3,W
ADDWFC ACCbHI,F
ENDM
;Add accumulator pair AB to 32 bit file
ADDABF MACRO ADDRESS ;f+ab->f
MOVF ACCaLO,W
ADDWF ADDRESS,F
MOVF ACCaHI,W
ADDWFC ADDRESS+1,F
MOVF ACCbLO,W
ADDWFC ADDRESS+2,F
MOVF ACCbHI,W
ADDWFC ADDRESS+3,F
ENDM
;Subtract 32 bit file from 'AB' result in 'AB'
SUBFAB MACRO ADDRESS
MOVF ADDRESS,W
SUBWF ACCaLO,F
MOVF ADDRESS+1,W
SUBWFB ACCaHI,F
MOVF ADDRESS+2,W
SUBWFB ACCbLO,F
MOVF ADDRESS+3,W
SUBWFB ACCbHI,F
ENDM
;Subtract 'AB' from 32 bit file result in file
SUBABF MACRO ADDRESS
MOVF ACCaLO,W
SUBWF ADDRESS,F
MOVF ACCaHI,W
SUBWFB ADDRESS+1,F
MOVF ACCbLO,W
SUBWFB ADDRESS+2,F
MOVF ACCbHI,W
SUBWFB ADDRESS+3,F
ENDM
;Unsigned compare 32 bit file with 32 bit file (f2-f1)
;carry & zero flags reflect unsigned 32bit result
CMPFFU32 MACRO ADDRESS1,ADDRESS2 ;See AN526
LOCAL NOCHK
LOCAL LSCHK
MOVF ADDRESS1+3,W ;ms
SUBWF ADDRESS2+3,W ;check if file > file
BZ LSCHK1 ;continue if file=file
GOTO NOCHK ;ms result tells all
LSCHK1 MOVF ADDRESS1+2,W ;ms same so test next ms
SUBWF ADDRESS2+2,W ;carry set if a > file
BZ LSCHK2 ;continue if file=file
GOTO NOCHK ;next ms result tells all
LSCHK2 MOVF ADDRESS1+1,W ;ms same so test next ms
SUBWF ADDRESS2+1,W ;carry set if a > file
BZ LSCHK3 ;continue if file=file
GOTO NOCHK ;next ms result tells all
LSCHK3 MOVF ADDRESS1,W ;ms same so test next ms
SUBWF ADDRESS2,W ;carry set if a > file
NOCHK
ENDM
;Negate 32 bit register pair AB
NEGAB MACRO
NEGF32 ACCaLO
ENDM
;Negate 32 bit file
NEGF32 MACRO ADDRESS ;Invert then add 1
COMF ADDRESS,F ;LS
COMF ADDRESS+1,F
COMF ADDRESS+2,F
COMF ADDRESS+3,F
CLRF WREG
SETC
ADDWFC ADDRESS,F ;LS
ADDWFC ADDRESS+1,F
ADDWFC ADDRESS+2,F
ADDWFC ADDRESS+3,F
ENDM
;Shift 32 bit file left one bit
LSLF32 MACRO ADDRESS
CLRC ;so it won't corrupt LS bit
RLCF ADDRESS,F ;LS setting carry as appropriate
RLCF ADDRESS+1,F ;carry from LS byte
RLCF ADDRESS+2,F
RLCF ADDRESS+3,F
ENDM
;Rotate 32 bit file left one bit through carry
RLF32C MACRO ADDRESS
RLCF ADDRESS,F ;Using carry from caller
RLCF ADDRESS+1,F ;carry from LS byte
RLCF ADDRESS+2,F
RLCF ADDRESS+3,F
ENDM
;Rotate 32bit register pair EF left through carry
RLFEFC MACRO
RLF32C ACCeLO
ENDM
;Logical Shift 32bit register pair AB one bit right.
LSRAB MACRO
LSRF32 ACCaLO
ENDM
;Logical Shift 32 bit file right one bit
LSRF32 MACRO ADDRESS
CLRC ;so it won't corrupt MS bit
RRCF ADDRESS+3,F ;MS setting carry as appropriate
RRCF ADDRESS+2,F
RRCF ADDRESS+1,F
RRCF ADDRESS,F ;LS with any carry from MS byte
ENDM
;Arithmetic Shift 32 bit file right one bit
ASRF32 MACRO ADDRESS
CLRC
BTFSC ADDRESS+3,7 ;If MS bit is set
SETC ;Then set carry ready for copying
RRCF ADDRESS+3,F ;MS setting carry as appropriate
RRCF ADDRESS+2,F
RRCF ADDRESS+1,F
RRCF ADDRESS,F ;LS with any carry from MS byte
ENDM
;Arithmetic Shift accumulator pair AB one bit right
ASRAB MACRO
ASRF32 ACCbLO
ENDM
;Logical Shift accumulator pair AB one bit left
LSLAB MACRO
LSLF32 ACCaLO
ENDM
;Logical Shift accumulator pair CD one bit left
LSLCD MACRO
LSLF32 ACCcLO
ENDM
;Logical Shift accumulator pair EF one bit left
LSLEF MACRO
LSLF32 ACCeLO
ENDM
;Logical Shift accumulator pair GH one bit left
LSLGH MACRO
LSLF32 ACCgLO
ENDM
;Save 8 bit file to Indirection pointer 2
POST2F8 MACRO ADDRESS
MOVF ADDRESS,W
MOVWF POSTINC2 ;Save to Capture buffer & increment pointer
ENDM
;Save 16 bit file to Indirection pointer 2
POST2F16 MACRO ADDRESS
MOVF ADDRESS,W
MOVWF POSTINC2 ;Save to Capture buffer & increment pointer
MOVF ADDRESS+1,W
MOVWF POSTINC2 ;Save to Capture buffer & increment pointer
ENDM
;Save 32 bit file to Indirection pointer 2
POST2F32 MACRO ADDRESS
MOVF ADDRESS,W
MOVWF POSTINC2 ;Save to Capture buffer & increment pointer
MOVF ADDRESS+1,W
MOVWF POSTINC2 ;Save to Capture buffer & increment pointer
MOVF ADDRESS+2,W
MOVWF POSTINC2 ;Save to Capture buffer & increment pointer
MOVF ADDRESS+3,W
MOVWF POSTINC2 ;Save to Capture buffer & increment pointer
ENDM
;Odds & ends for PIC18F458
;Select databank given
REGBANK MACRO BANKNUMBER
MOVLB BANKNUMBER ;BSR=0 for bank 0 etc
ENDM
;Extend instruction set with more convenient op-codes
SAVEMAX8 MACRO ADDRESS
CPFSGT ADDRESS
MOVWF ADDRESS ;Save as its bigger
ENDM
SAVEMIN8 MACRO ADDRESS
CPFSLT ADDRESS
MOVWF ADDRESS ;Save as its smaller
ENDM
;Clear carry
CLRC MACRO
BCF STATUS,C
ENDM
;Set Carry
SETC MACRO
BSF STATUS,C
ENDM
;Logical shift left file
LSLF MACRO ADDRESS
CLRC ;So it won't corrupt LS bit
RLCF ADDRESS,F
ENDM
;Logical shift right file
LSRF MACRO ADDRESS
CLRC ;So it won't corrupt MS bit
RRCF ADDRESS,F
ENDM
;Sets Z and N flag but does not change file
TSTF MACRO ADDRESS
MOVF ADDRESS,F
ENDM
+
file: /Techref/member/RF-AMY-K22a/mathsdefs_h.htm, 34KB, , updated: 2014/4/9 15:37, local time: 2024/11/28 03:55,
owner: RF-AMY-K22a,
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