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----
*Factorial 2014
<nowiki>
_ AREA Add, CODE
ENTRY
; This program takes the factorial of n (in r2)
n EQU 0

ldr r2,=n ; Load r2 with the number to take the factorial of.
cmp r2,#0 ; Is n=0
bne check_for_1
mov r4,#1
b stop
check_for_1
cmp r2,#1
bne initialize_r4
mov r4,#1
b stop
initialize_r4
mov r4,r2
sub r3,r4,#1
loop
mul r5,r4,r3
mov r4,r5
subs r3,r3,#1
bne loop
stop b stop
END
</nowiki>
----
----


Line 78: Line 107:
; saving registers on the stack, etc.
; saving registers on the stack, etc.
; Rob Frohne, 1/3/2013
; Rob Frohne, 11/3/2013
stack_start EQU 0x40001000
stack_start EQU 0x40001000
Line 88: Line 117:
ldr sp, =stack_start ; Tell where we will place the stack.
ldr sp, =stack_start ; Tell where we will place the stack.
; (It goes down (lower addresses from here.)
; (It goes down (lower addresses from here.)
mov r1, #1 ; Store some numebers in some registers
mov r1, #1 ; Store some numebers in some registers
mov r2, #2
mov r2, #2
mov r3, #3
mov r3, #3
Line 99: Line 128:
subroutine
subroutine
stmfd sp!, {r1-r2,lr} ; save used registers and the link register (r14)
stmfd sp!, {r1-r2,lr} ; save used registers and the link register (r14)
mov r1,#0xffffffff ; mess up the registers
mov r1,#0xffffffff ; mess up the registers
mov r2, r1
mov r2, r1
ldmfd sp!, {r1,r2,pc} ; pop the stack and return
ldmfd sp!, {r1,r2,pc} ; pop the stack and return
Line 116: Line 145:
ENTRY
ENTRY


ldr r0,=end ; load the beginning address of the code & initialize it as the pointer.
ldr r0,=end ; load the end address of the code & initialize it as the pointer.
ldr r2,=begin ; load the ending address of the code.
ldr r2,=begin ; load the beginning address of the code.
mov r3,#0x7fffffff ; Initialize r3 as the most positive number.
mov r3,#0x7fffffff ; Initialize r3 as the most positive number.


loop
loop
ldr r6,[r2],#4 ; load the next data into r6 and post increment r2 for the next data.
ldr r6,[r2],#4 ; load the next data into r6 and post increment r2 for the next data.
cmp r6,r3 ; Find out if r6 > r3. result from r6-r3 like subs r7,r6,r3 without r6 necessary.
cmp r6,r3 ; Find out if r6 > r3. result from r6-r3 like subs r7,r6,r3 without r6 necessary.
bgt no_update ; If it is no update.
bgt no_update ; If it is no update.
mov r3,r6 ; update if r6 is lower than r3.
mov r3,r6 ; update if r6 is lower than r3.
no_update
no_update
cmp r0,r2 ; are we at the end yet
cmp r0,r2 ; are we at the end yet
bne loop ; if r7 != 0 then keep looping
bne loop ; if r7 != 0 then keep looping


stop b stop
stop b stop
Line 195: Line 224:
; Subroutine to add two BCD numbers in 32 bit form with each nibble
; Subroutine to add two BCD numbers in 32 bit form with each nibble
; representing a digit.
; representing a digit.
; locals: r8 for digit counter, mask 0xf, r5 & r6 for masked addends,
; locals: r8 for digit counter, single digit mask 0xf, r5 & r6 for masked addends,
; working BCD_carry, r7 for
; working BCD_carry, r7
; working result in r4
; working result in r4
; the summed digits go in r3
; the summed digits go in r3
; inputs: r0+r1
; inputs: r0+r1
; outupts: r0 result and r1 carry
; outputs: r0 result and r1 carry
; only r4-r8 are saved.
; only r4-r8 are saved.
; Rob Frohne 11/12/13
; Rob Frohne 11/12/13
Line 225: Line 254:
add r4, r4, r6 ; r4=r5+r6
add r4, r4, r6 ; r4=r5+r6
subs r4, r4, #10 ; Subtract 10 (base 10) to see if there is a carry.
subs r4, r4, #10 ; Subtract 10 (base 10) to see if there is a carry.
bpl carry
bmi no_carry
mov r7, #1 ; set the carry
b roll_to_next_digit
no_carry
mov r7, #0 ; set carry to zero
mov r7, #0 ; set carry to zero
add r4, r4, #10 ; Add the 10 back in as there was no carry needed.
add r4, r4, #10 ; Add the 10 back in as there was no carry needed.
b roll_to_next_digit
carry
mov r7, #1 ; set the carry
roll_to_next_digit
roll_to_next_digit
orr r3, r3, r4 ; Add thise digits into the sum.
orr r3, r3, r4 ; Add these digits into the sum.
ror r0, #4
ror r0, #4
ror r1, #4
ror r1, #4
ror r3, #4
ror r3, #4
subs r8, r8, #1 ; Decrement digit counter
subs r8, r8, #1 ; Decrement the digit counter
bne loop ; If it isn't zero do the next digit.
bne loop ; If it isn't zero do the next digit.
mov r0, r3 ; Set the output registers. r0 is result. r1 is carry.
mov r0, r3 ; Set the output registers. r0 is result. r1 is carry.
Line 243: Line 272:
END
END
</nowiki>
</nowiki>
----
*Bubble Sort
<nowiki>
; This is a program to bubble sort a list.
; Rob Frohne and the CPTR 215 class

stack_start EQU 0x40001000
length EQU (end_of_list - begin)
end_ram EQU (datastart + length)
; EQU statements must be at the beginning of the program.
AREA Subroutine_Example, CODE

ENTRY
; Copy list to RAM
ldr sp, =stack_start
LDR R9, =begin
ldr R7, =end_of_list
ldr r6, =datastart
loop
ldr r8,[r9],#4
str r8,[r6],#4
cmp r9,r7
bne loop
; End copy to RAM

start_sort
ldr r5,=(end_ram - 4)
loop_sort_outer ; r2 is our counter, it goes from 1 to item_count
mov r1, #1 ; has_changed = false (0 is true)
ldr r2,=datastart ; start of data in ram goes into r2
loop_sort_inner ;
ldr r3,[r2],#4
ldr r4,[r2],#0
cmp r3,r4
blhi subroutine_swap ; swaps the last two and sets has_changed
cmp r2,r5
bne loop_sort_inner
sub r5,r5,#4 ; the last item is in order, so we don't need to check it again.
cmp r1,#1
bne loop_sort_outer
stop b stop

subroutine_swap ; swaps the contents of the addresses held in
; r2 and r2 -4 (the previous address)
; has_changed is r1 and it sets it to 0 (true)
stmfd sp!, {r0,r2-r4,lr}
mov r1,#0 ; setting the has_changed to true.
ldr r0,[r2],#-4 ; swapping data
ldr r3,[r2]
str r0,[r2],#4
str r3,[r2]
ldmfd sp!, {r0,r2-r4,pc}
ALIGN
begin
DCD 0x8fffffff, 0x55555555, 0x44444444, 0x77777777, 0xffffffff
end_of_list
AREA Thedata, DATA, NOINIT, READWRITE
datastart SPACE 20
END
</nowiki>
----
----
*GPIO Example
*GPIO Example
Line 408: Line 497:


main
main
ldr sp, = Stack_Mem ; load stack pointer
ldr r1, =PINSEL0
ldr r1, =PINSEL0
mov r0, #0 ; set P0.0 to P0.15 as GPIO
mov r0, #0 ; set P0.0 to P0.15 as GPIO
Line 1,478: Line 1,566:


end_delay LDMFD SP!,{PC,r0,r1} ; Return
end_delay LDMFD SP!,{PC,r0,r1} ; Return

END
</nowiki>

* Propeller Drive Using Interrupts (not polled)
<nowiki>

;---------------------------------------------------------------------------
;
; Shell Programmer : Larry Aamodt, main: Rob Frohne
;
;
; File name : shell_2148.s
; Class : CPTR-215
; Language : ARM assembly
; Assembler : Keil
; Target MCU : NXP LPC-2148 on Embedded Artists board
; Date Written: 11/30/09
; change history: 11/30/09 LDA Updated with hardware start-up
; 12/03/09 LDA PWM register definitions added
; Description :
;
; Inputs :
;
; Outputs :
;
; Special :
; requirements
;
;
; NOTES:
;
;
;
;---------------------------------------------------------------------------

; Put application program definitions (i.e. equates) here:


; Standard definitions of Mode bits and Interrupt (I & F) flags in PSRs

Mode_USR EQU 0x10
Mode_FIQ EQU 0x11
Mode_IRQ EQU 0x12
Mode_SVC EQU 0x13
Mode_ABT EQU 0x17
Mode_UND EQU 0x1B
Mode_SYS EQU 0x1F

I_Bit EQU 0x80 ; when I bit is set, IRQ is disabled
F_Bit EQU 0x40 ; when F bit is set, FIQ is disabled

; Memory addresses for standard GPIO definitions
IO0PIN EQU 0xE0028000
IO0SET EQU 0xE0028004
IO0DIR EQU 0xE0028008
IO0CLR EQU 0xE002800C

; Vector Interrupt Controller Addresses
VICIntSelect EQU 0xFFFFF00C
VICVectAddr4 EQU 0xFFFFF110
VICVectCntl4 EQU 0xFFFFF210
VICIntEnable EQU 0xFFFFF010
VICVectAddr EQU 0xFFFFF030


; Timer addresses
T0PC EQU 0xE0004010 ; Timer 0 Prescale counter
T0IR EQU 0xE0004000 ; Timer 0 Interrupt Register
T0_TCR_ADDR EQU 0xE0004004
T0_PR_ADDR EQU 0xE000400C
T0_MCR_ADDR EQU 0xE0004014
T0_MR0_ADDR EQU 0xE0004018

; Memory addresses for Pulse Width Modulation (PWM)
PWM_TCR EQU 0xE0014004 ; PWM_TCR Timer Control Register
PWM_PR EQU 0xE001400C ; PWM_PR Prescaler Register
PWM_MCR EQU 0xE0014014 ; PWM_MCR Match Control Register
PWM_MR0 EQU 0xE0014018 ; PWM_MR0 Match Register 0 (sets pulse period)
PWM_MR4 EQU 0xE0014040 ; PWM_MR4 Match Register 4 (sets pulse length)
PWM_MR6 EQU 0xE0014048 ; PWM_MR6 Match Register 6 (sets pulse length)
PWM_PCR EQU 0xE001404C ; PWM_CR Control Register
PWM_LER EQU 0xE0014050 ; PWM_LER Latch Enable Register

PINSEL0 EQU 0xE002C000 ; Pin connect block - port 0
PINSEL1 EQU 0xE002C004 ; Pin connect block - port 1

; Stack size definitions
UND_Stack_Size EQU 0x00000000
SVC_Stack_Size EQU 0x00000008
ABT_Stack_Size EQU 0x00000000
FIQ_Stack_Size EQU 0x00000000
IRQ_Stack_Size EQU 0x00000080
USR_Stack_Size EQU 0x00000400

ISR_Stack_Size EQU (UND_Stack_Size + SVC_Stack_Size + ABT_Stack_Size + \
FIQ_Stack_Size + IRQ_Stack_Size)

AREA STACK, NOINIT, READWRITE, ALIGN=3

Stack_Mem SPACE USR_Stack_Size
__initial_sp SPACE ISR_Stack_Size
Stack_Top


; Area Definition and Entry Point
; Startup Code must be linked first at Address at which it expects to run.

AREA RESET, CODE, READONLY
ARM


; Exception Vectors
; Mapped to Address 0.
; Absolute addressing mode must be used.
; Dummy Handlers are implemented as infinite loops which can be modified.

Vectors LDR PC, Reset_Addr
LDR PC, Undef_Addr
LDR PC, SWI_Addr
LDR PC, PAbt_Addr
LDR PC, DAbt_Addr
NOP ; Reserved Vector
; LDR PC, IRQ_Addr
LDR PC, [PC, #-0x0FF0] ; Vector from VicVectAddr
LDR PC, FIQ_Addr

Reset_Addr DCD Reset_Handler
Undef_Addr DCD Undef_Handler
SWI_Addr DCD SWI_Handler
PAbt_Addr DCD PAbt_Handler
DAbt_Addr DCD DAbt_Handler
DCD 0 ; Reserved Address
IRQ_Addr DCD IRQ_Handler
FIQ_Addr DCD FIQ_Handler

; Exception Handlers
Undef_Handler B Undef_Handler
SWI_Handler B SWI_Handler
PAbt_Handler B PAbt_Handler
DAbt_Handler B DAbt_Handler
IRQ_Handler B IRQ_Handler
FIQ_Handler B FIQ_Handler

; Reset Handler

EXPORT Reset_Handler
Reset_Handler

; Setup Stack for each mode

LDR R0, =Stack_Top

; Enter Undefined Instruction Mode and set its Stack Pointer
MSR CPSR_c, #Mode_UND:OR:I_Bit:OR:F_Bit
MOV SP, R0
SUB R0, R0, #UND_Stack_Size

; Enter Abort Mode and set its Stack Pointer
MSR CPSR_c, #Mode_ABT:OR:I_Bit:OR:F_Bit
MOV SP, R0
SUB R0, R0, #ABT_Stack_Size

; Enter FIQ Mode and set its Stack Pointer
MSR CPSR_c, #Mode_FIQ:OR:I_Bit:OR:F_Bit
MOV SP, R0
SUB R0, R0, #FIQ_Stack_Size

; Enter IRQ Mode and set its Stack Pointer
MSR CPSR_c, #Mode_IRQ:OR:I_Bit:OR:F_Bit
MOV SP, R0
SUB R0, R0, #IRQ_Stack_Size

; Enter Supervisor Mode and set its Stack Pointer
MSR CPSR_c, #Mode_SVC:OR:I_Bit:OR:F_Bit
MOV SP, R0
SUB R0, R0, #SVC_Stack_Size

; Enter User Mode and set its Stack Pointer
MSR CPSR_c, #Mode_USR
MOV SP, R0
SUB SL, SP, #USR_Stack_Size

step_time_uS EQU 250000 ; uS between steps of the propeller motor.

main BL init_propeller ; Initialize GPIO and IRQ, and Timer 0.

LDR r0,=step1
LDR r1,=NextRoutine_Address
STR r0,[r1]
bl delay ; start the whole automated thing

do_nothing b do_nothing ; because the ISR will do it all!

; -----------------------------------------------------------------------------
; Step the motor routines. These are called by the Timer0 ISR (timer0ISR)
; -----------------------------------------------------------------------------

step1 STMFD SP!,{LR,r0-r12}
mov r1, #1 ; for handy access
mov r2, #0 ; for handy access
mov r0, r1, LSL #12 ; turn one on
mov r4, r2, LSL #21 ; two still off
orr r0, r4, r0 ; both on
ldr r3,=IO0PIN
str r0,[r3]
LDR r0,=step2
LDR r1,=NextRoutine_Address
STR r0,[r1]
bl delay
LDMFD SP!,{PC,r0-r12}

step2 STMFD SP!,{LR,r0-r12}
mov r1, #1 ; for handy access
mov r2, #0 ; for handy access
mov r0, r1, LSL #12
mov r4, r1, LSL #21
orr r0, r4, r0 ; both on
ldr r3,=IO0PIN
str r0,[r3]
LDR r0,=step3
LDR r1,=NextRoutine_Address
STR r0,[r1]
bl delay
LDMFD SP!,{PC,r0-r12}

step3 STMFD SP!,{LR,r0-r12}
mov r1, #1 ; for handy access
mov r2, #0 ; for handy access
mov r0, r2, LSL #12 ; turn one off
mov r4, r1, LSL #21 ; two still on
orr r0, r4, r0 ; both on
ldr r3,=IO0PIN
str r0,[r3]
LDR r0,=step4
LDR r1,=NextRoutine_Address
STR r0,[r1]
bl delay
LDMFD SP!,{PC,r0-r12}

step4 STMFD SP!,{LR,r0-r12}
mov r1, #1 ; for handy access
mov r2, #0 ; for handy access
mov r0, r2, LSL #12 ; turn one off
mov r4, r2, LSL #21 ; turn two off
orr r0, r4, r0 ; both on
ldr r3,=IO0PIN
str r0,[r3]
LDR r0,=step1
LDR r1,=NextRoutine_Address
STR r0,[r1]
bl delay
LDMFD SP!,{PC,r0-r12}

; -----------------------------------------------------------------------------
; Procedure init_propeller Must be called before to initialize the propeller.
; Set up GPIO P0.12 and P0.21 for output.
; Set up timer 0 and interrupts for IRQ (low priority)
; No parameters required
; -----------------------------------------------------------------------------

init_propeller STMFD SP!,{LR,r0,r1,r2,r3,r4}
LDR r1,=T0_PR_ADDR ; Prescale register
MOV r2,#2 ; prescale count value
STR r2,[r1] ; Prescaler will divide by 3 (1 uS period

; T0MCR = 0x00000003; //reset counter and generate IRQ on MR0 match

LDR r1,=T0_MCR_ADDR ; Match control register
MOV r2,#0x3 ; bit 2 = one: Stop on MR0: the TC and PC : bit 1 = 1 gives interrupt
; will be stopped and TCR[0] will be set to 0 if
; MR0 matches the TC
STR r2,[r1] ; stop counter when match reached

; VICIntSelect &= ~0x10; //Timer0 interrupt is assigned to IRQ (not FIQ)
LDR r1,=VICIntSelect
MOV r0,#~0x10
STR r0,[r1]

; VICVectAddr4 = (tU32)timer0ISR; //register ISR address
LDR r1,=VICVectAddr4
LDR r0,=timer0ISR
STR r0,[r1]

; VICVectCntl4 = 0x24; //enable vector interrupt for timer0
LDR r1,=VICVectCntl4
MOV r0,#0x24
STR r0,[r1]

; VICIntEnable = 0x10; //enable timer0 interrupt
LDR r1,=VICIntEnable
MOV r0,#0x10
STR r0,[r1]

LDR r0,=IO0DIR
LDR r4,[r0] ; read current Port 0 direction bits
LDR r3,=2101248 ; one's for pins to be set for output (2^12+2^21 = 2101248)
; 2134016 = 2^12+2^21+2^15 (for debugging LED on P0.15
ORR r4,r4,r3
STR r4,[r0] ; set propeller port bits to output without changing others

LDR r0,=PINSEL0
LDR r4,[r0] ; read current Port 0 direction bits
LDR r3,=50331648 ; zero's for pins to be set for output (2^24+2^25 = 50331648)
BIC r4,r4,r3 ;
STR r4,[r0] ; set propeller port P0.12 to GPIO without changing others.

LDR r0,=PINSEL1
LDR r4,[r0] ; read current Port 0 direction bits
LDR r3,=3072 ; zero's for pins to be set for output (2^10+2^11 = 3072)
BIC r4,r4,r3 ;
STR r4,[r0] ; set propeller port P0.21 to GPIO without changing others.

end_init_propeller LDMFD SP!,{PC,r0,r1,r2,r3,r4}

; -----------------------------------------------------------------------------
; Timer 0 Interrupt Service Routine timer0ISR
; Some comments are C equivalents.
; -----------------------------------------------------------------------------

timer0ISR SUB LR,LR,#4 ; Update the LR
STMFD SP!, {r0-r12,LR} ; Store registers (including LR)

; T0IR = 0xff; //reset all IRQ flags
LDR r1,=T0IR
MOV r0,#~0xff
STR r0,[r1]

; VICVectAddr = 0x00; //dummy write to VIC to signal end of interrupt
LDR r1,=VICVectAddr
MOV r0,#~0x00
STR r0,[r1]

; Here we will branch to the appropriate next step routine.
LDR r0,=NextRoutine_Address
push {r14} ; save LR for this return.
ldr r14,=end_timer0ISR ; load the LR because we are using an LDR PC below.
ldr PC,[r0] ; branch to the subroutine pointed to by NextRoutine_Address
end_timer0ISR pop {r14} ; restore the LR for this return.
LDMFD SP!, {r0-r12,PC}^ ; Return from ISR

; -----------------------------------------------------------------------------
; Procedure delay microsecond delay using timer 0
; (12Mhz clock & VPB divide by 4 assumed)
; Delay is set by step_time_uS
; -----------------------------------------------------------------------------

delay STMFD SP!,{LR,r0,r1}


; T0PC = 0x00000000; Didn't do this yet. Unnecessary? //no prescale of clock

; LDR r1,=T0PC
; MOV r0,#0x00000000
; STR r0,[r1]

; T0IR = 0x000000ff; //reset all flags before enable IRQs

LDR r1,=T0IR
MOV r0,#0x000000ff
STR r0,[r1]

; T0MR0 = delayInMs * //calculate no of timer ticks
; ((CRYSTAL_FREQUENCY * PLL_FACTOR) / (1000 * VPBDIV_FACTOR));
LDR r1,=T0_MR0_ADDR ; Match register zero
LDR r0,=step_time_uS
STR r0,[r1] ; load match count from step_time_uS

; T0TCR = 0x00000002; //disable and reset Timer0
LDR r1,=T0_TCR_ADDR ; Timer 0 Control Register
MOV r0,#2 ; bit 1 = one
; T0TCR = 0x00000001; //start Timer0
STR r0,[r1] ; Clear counter & prescaler
MOV r0,#0
STR r0,[r1]

MOV r0,#1 ; bit 0 = one
STR r0,[r1] ; Turn on counter

end_delay LDMFD SP!,{PC,r0,r1} ; Return

AREA Thedata, DATA, READWRITE
ALIGN
NextRoutine_Address SPACE 4 ; This holds the address of the next step subroutine.


END
END

Latest revision as of 11:58, 7 November 2014

  • Factorial
; Factorial Calculation
; The answer is in R10

; Rob Frohne 2013

	GLOBAL Reset_Handler 
	AREA Factorial, CODE, READONLY
	ENTRY

Reset_Handler
		movs r8, #0 ; Take the factorial of this number, n.
		mov r10, #1	 ; 0! and 1! are 1
		beq stop   ; If r8 is zero we are done
		cmp r8, #1	 ; If r8 is 1, 
		beq stop	  ; we are done
		subs r9, r8, #1	; n-1
loop	mulne r10, r9, r8 ; n(n-1)
		mov r8, r10
		subs r9, r9, #1
		bne loop
stop 	b stop
		END



  • Factorial 2014
_	AREA Add, CODE
 	ENTRY
	; This program takes the factorial of n (in r2)
n EQU 0

		ldr r2,=n ; Load r2 with the number to take the factorial of.
		cmp r2,#0 ; Is n=0
		bne check_for_1
		mov r4,#1
		b stop
check_for_1
		cmp r2,#1
		bne initialize_r4
		mov r4,#1
		b stop
initialize_r4
		mov r4,r2
		sub r3,r4,#1
loop
		mul r5,r4,r3
		mov r4,r5
		subs r3,r3,#1
		bne loop
stop b stop
	END


  • 64 Bit Add
VAL1A EQU 0xffffffff
VAL1B EQU 0x0000000f
VAL2A EQU 0x00000001
VAL2B EQU 0x00000001
	AREA LongAdd, CODE
	ENTRY
		ldr R0, = VAL1A
		ldr R1, = VAL1B
		ldr R2, = VAL2A
		ldr R3, = VAL2B
		adds R8,R0,R1
		adcs R9,R1,R3
stop 	b stop
	END

  • Copy to RAM
   AREA Exaddress, CODE, READONLY
   EXPORT Reset_Handler
Reset_Handler
   LDR R9, =list
   mov R7, #4 ; number in list
   ldr r6, =datastart 
loop
   ldr r8,[r9],#4
   str r8,[r6],#4
   subs r7,r7,#1
   bne loop
 
stop b stop
   ALIGN
list DCW 0x1111, 0x2222, 0x3333, 0x4444, 0x5555
   ALIGN
string DCB "This is a test.",0 ; This string is not used in the copy to ram program
string2 DCB 'T','h','i' ; This string2 is not used in the copy to ram program
   ALIGN
   AREA Thedata, DATA, NOINIT, READWRITE
datastart SPACE 20
 
   END

  • Subroutine Example1
; First Subroutine Example
; This program demonstrates using a subroutine,
; saving registers on the stack, etc.

; Rob Frohne, 11/3/2013

stack_start EQU 0x40001000
   AREA Subroutine_Example, CODE

   ENTRY

Start
   ldr sp, =stack_start ; Tell where we will place the stack.
                        ; (It goes down (lower addresses from here.)
   mov r1, #1           ; Store some numebers in some registers
   mov r2, #2
   mov r3, #3
   bl subroutine
stop b stop

; This subroutine saves the registers,
; messes up the registers locally,
; then restores the registers and returns.
subroutine
   stmfd sp!, {r1-r2,lr} ; save used registers and the link register (r14)
   mov r1,#0xffffffff    ; mess up the registers
   mov r2, r1
   ldmfd sp!, {r1,r2,pc} ; pop the stack and return 
   END

  • Minimum of a Signed Number
; This program finds the minimum of a list of constant words in signed format
; The result is in r3 at the end of the routine.
; Rob Frohne 10/30/2013

	AREA Program, CODE, READONLY

	ENTRY

	ldr r0,=end	; load the end address of the code & initialize it as the pointer.
	ldr r2,=begin	; load the beginning address of the code.
	mov r3,#0x7fffffff ; Initialize r3 as the most positive number.

loop	
	ldr r6,[r2],#4 ; load the next data into r6 and post increment r2 for the next data.
	cmp r6,r3      ; Find out if r6 > r3. result from r6-r3  like subs r7,r6,r3 without r6 necessary.
	bgt no_update  ; If it is no update.
	mov r3,r6      ; update if r6 is lower than r3.
no_update
	cmp r0,r2      ;  are we at the end yet
	bne loop       ; if r7 != 0 then keep looping

stop b stop
ALIGN
begin
	DCD 0x8fffffff, 0x55555555, 0x44444444, 0x77777777, 0xffffffff
end	
	END 



  • Compare Two Null Terminated Strings
; Subroutine to compare two null terminated ASCII strings.
; The address where the two strings start are in r0 and r1
; The return is in r0, 1 for match and 0 for don't match.
; If they don't match, r1 gives the number of the first 
; character that didn't match, starting with 0.
; r2 and r3 are not protected.
; Rob Frohne 11/6/2013
stack_start EQU 0x40001000
	AREA String_Compare, CODE
    ENTRY
Start
	ldr sp, =stack_start ; Tell where we will place the stack.
                        ; (It goes down (lower addresses from here.)
	ldr r0, =string1
	ldr r1, =string2
	bl compare_strings
stop b stop

compare_strings
	stmfd sp!, {r2,r4,r5,lr} ; save used registers and the link register (r14)
	mov r2, #0 ; Initialize the counter for the first position.
loop
	ldrb r4,[r0],#1
	ldrb r5,[r1],#1
	cmp r5,r4
	bne do_not_match
	cmp r4, #0 ; check for end of string.
	beq match
	add r2, #1
	b loop
do_not_match
	mov r0, #0 ; don't match
	b finish
match
	mov r0, #1
finish
	mov r1,r2 ; Move the count into the result register.	
	ldmfd sp!, {r2,r4,r5,pc} ; pop the stack and return 
string1 
	DCB "This is the first string.",00	; For testing purposes.
	ALIGN
string2 
	DCB "This is the first string.",00
	ALIGN
        END


  • BCD Add
; Subroutine to add two BCD numbers in 32 bit form with each nibble
; representing a digit.
; locals: r8 for digit counter, single digit mask 0xf, r5 & r6 for masked addends,
; working BCD_carry, r7
; working result in r4
; the summed digits go in r3
; inputs: r0+r1
; outputs: r0 result and r1 carry
; only r4-r8 are saved.
; Rob Frohne 11/12/13
stack_start EQU 0x40001000
	AREA ADD_BCD, CODE
    ENTRY
Start
	ldr sp, =stack_start ; Tell where we will place the stack.
                        ; (It goes down (lower addresses from here.)
	ldr r0, =0x12345678	  ; The two numbers to add.
	ldr r1, =0x87654321
	bl bcd_add
stop b stop

bcd_add	; The subroutine
	stmfd sp!, {r4-r8,lr}
	mov r8, #8 ; Set the counter to move through the eight digits
	mov r7, #0 ; Set the carry to zero to start with
	mov r3, #0	; This is where the resulting digits of the sum are stored.
loop
	and r5, r0, #0xf  ; mask for the rightmost digit.
	and r6, r1, #0xf
	add r4, r5, r7 ; add carry
	add r4, r4, r6 ; r4=r5+r6
	subs r4, r4, #10 ; Subtract 10 (base 10) to see if there is a carry.
	bpl carry
	mov r7, #0 ; set carry to zero
	add r4, r4, #10 ; Add the 10 back in as there was no carry needed.
	b roll_to_next_digit
carry
	mov r7, #1 ; set the carry
roll_to_next_digit
	orr r3, r3, r4 ; Add these digits into the sum.
	ror r0, #4
	ror r1, #4
	ror r3, #4
	subs r8, r8, #1	 ; Decrement the digit counter
	bne loop	  ; If it isn't zero do the next digit.
	mov r0, r3 ; Set the output registers. r0 is result. r1 is carry.
	mov r1, r7
	ldmfd sp!, {r4-r8,pc}
	END


  • Bubble Sort
; This is a program to bubble sort a list.
; Rob Frohne and the CPTR 215 class

stack_start EQU 0x40001000
length EQU (end_of_list - begin)
end_ram EQU (datastart + length)
	; EQU statements must be at the beginning of the program.
   AREA Subroutine_Example, CODE

   ENTRY
; Copy list to RAM
   ldr sp, =stack_start
   LDR R9, =begin
   ldr R7, =end_of_list
   ldr r6, =datastart 
loop
   ldr r8,[r9],#4
   str r8,[r6],#4
   cmp r9,r7
   bne loop
; End copy to RAM

start_sort
		ldr r5,=(end_ram - 4)		
loop_sort_outer ; r2 is our counter, it goes from 1 to item_count
		mov r1, #1 ; has_changed = false (0 is true)
		ldr r2,=datastart ; start of data in ram goes into r2
loop_sort_inner ; 
		ldr r3,[r2],#4
		ldr r4,[r2],#0
		cmp r3,r4
		blhi subroutine_swap ; swaps the last two and sets has_changed
		cmp r2,r5
		bne loop_sort_inner
		sub r5,r5,#4 ; the last item is in order, so we don't need to check it again.
		cmp r1,#1
		bne loop_sort_outer					
stop 	b stop

subroutine_swap ; swaps the contents of the addresses held in
                ; r2 and r2 -4 (the previous address)
				; has_changed is r1 and it sets it to 0 (true)
		stmfd sp!, {r0,r2-r4,lr}
		mov r1,#0 ; setting the has_changed to true.
		ldr r0,[r2],#-4  ; swapping data
		ldr r3,[r2]
		str r0,[r2],#4
		str r3,[r2]		
		ldmfd sp!, {r0,r2-r4,pc}
	ALIGN
begin
	DCD 0x8fffffff, 0x55555555, 0x44444444, 0x77777777, 0xffffffff
end_of_list
   AREA Thedata, DATA, NOINIT, READWRITE
datastart SPACE 20
	END 
 

  • GPIO Example
;---------------------------------------------------------------------------
;
;   Programmer  : Larry Aamodt
;
;   File name  	: shell_2148.s 
;   Class       : CPTR-215
;   Language    : ARM assembly
;   Assembler   : Keil
;   Target MCU	: NXP LPC-2148 on Embedded Artists board
;   Date Written: 11/30/09  
;    change history:  11/30/09  LDA  Updated with hardware start-up
;    		      12/03/09  LDA  PWM register definitions added 
;   Description	: 
;
;   Inputs      :
;   
;   Outputs     :
;
;   Special     :  
;  requirements
;   
;
; 	NOTES: 
;
; 
;
;---------------------------------------------------------------------------

; Put application program definitions (i.e. equates) here:


; Standard definitions of Mode bits and Interrupt (I & F) flags in PSRs

Mode_USR        EQU     0x10
Mode_FIQ        EQU     0x11
Mode_IRQ        EQU     0x12
Mode_SVC        EQU     0x13
Mode_ABT        EQU     0x17
Mode_UND        EQU     0x1B
Mode_SYS        EQU     0x1F

I_Bit           EQU     0x80            ; when I bit is set, IRQ is disabled
F_Bit           EQU     0x40            ; when F bit is set, FIQ is disabled

;  Memory addresses for standard GPIO definitions
IO0PIN		    EQU     0xE0028000
IO0SET		    EQU     0xE0028004
IO0DIR		    EQU     0xE0028008
IO0CLR		    EQU     0xE002800C
;  Memory addresses for Pulse Width Modulation (PWM)
PWM_TCR         EQU     0xE0014004      ; PWM_TCR Timer Control Register
PWM_PR          EQU     0xE001400C      ; PWM_PR Prescaler Register
PWM_MCR         EQU     0xE0014014      ; PWM_MCR Match Control Register
PWM_MR0         EQU     0xE0014018      ; PWM_MR0 Match Register 0 (sets pulse period)
PWM_MR4         EQU     0xE0014040      ; PWM_MR4 Match Register 4 (sets pulse length)
PWM_MR6         EQU     0xE0014048      ; PWM_MR6 Match Register 6 (sets pulse length)
PWM_PCR         EQU     0xE001404C      ; PWM_CR Control Register
PWM_LER         EQU     0xE0014050      ; PWM_LER Latch Enable Register

PINSEL0         EQU     0xE002C000      ; Pin connect block - port 0
PINSEL1         EQU     0xE002C004      ; Pin connect block - port 1

;  Stack size definitions
UND_Stack_Size  EQU     0x00000000
SVC_Stack_Size  EQU     0x00000008
ABT_Stack_Size  EQU     0x00000000
FIQ_Stack_Size  EQU     0x00000000
IRQ_Stack_Size  EQU     0x00000080
USR_Stack_Size  EQU     0x00000400

ISR_Stack_Size  EQU     (UND_Stack_Size + SVC_Stack_Size + ABT_Stack_Size + \
                         FIQ_Stack_Size + IRQ_Stack_Size)

                AREA    STACK, NOINIT, READWRITE, ALIGN=3

Stack_Mem       SPACE   USR_Stack_Size
__initial_sp    SPACE   ISR_Stack_Size
Stack_Top


; Area Definition and Entry Point
;  Startup Code must be linked first at Address at which it expects to run.

                AREA    RESET, CODE, READONLY
                ARM


; Exception Vectors
;  Mapped to Address 0.
;  Absolute addressing mode must be used.
;  Dummy Handlers are implemented as infinite loops which can be modified.

Vectors         LDR     PC, Reset_Addr         
                LDR     PC, Undef_Addr
                LDR     PC, SWI_Addr
                LDR     PC, PAbt_Addr
                LDR     PC, DAbt_Addr
                NOP                            ; Reserved Vector 
;               LDR     PC, IRQ_Addr
                LDR     PC, [PC, #-0x0FF0]     ; Vector from VicVectAddr
                LDR     PC, FIQ_Addr

Reset_Addr      DCD     Reset_Handler
Undef_Addr      DCD     Undef_Handler
SWI_Addr        DCD     SWI_Handler
PAbt_Addr       DCD     PAbt_Handler
DAbt_Addr       DCD     DAbt_Handler
                DCD     0                      ; Reserved Address 
IRQ_Addr        DCD     IRQ_Handler
FIQ_Addr        DCD     FIQ_Handler

Undef_Handler   B       Undef_Handler
SWI_Handler     B       SWI_Handler
PAbt_Handler    B       PAbt_Handler
DAbt_Handler    B       DAbt_Handler
IRQ_Handler     B       IRQ_Handler
FIQ_Handler     B       FIQ_Handler

; Reset Handler

                EXPORT  Reset_Handler
Reset_Handler   

; Setup Stack for each mode

                LDR     R0, =Stack_Top

;  Enter Undefined Instruction Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_UND:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #UND_Stack_Size

;  Enter Abort Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_ABT:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #ABT_Stack_Size

;  Enter FIQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_FIQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #FIQ_Stack_Size

;  Enter IRQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_IRQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #IRQ_Stack_Size

;  Enter Supervisor Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_SVC:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #SVC_Stack_Size

;  Enter User Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_USR

                MOV     SP, R0
                SUB     SL, SP, #USR_Stack_Size


; User program code goes here

main
	ldr r1, =PINSEL0
	mov r0, #0		  ; set P0.0 to P0.15 as GPIO
	str r0,[r1]
	ldr r1, =IO0DIR		; Get ready to set direction of data
	ldr r0, =0xffff		; output
	str r0, [r1] 	;	set the direction
	ldr r1, =IO0PIN	; load the address of the port0
	mov r0, #0
next
	str r0, [r1]
	add r0, r0, #1
	ldr  r2, =0x200
delay
	subs r2,r2,#1
	bne delay	
	b next


	AREA Thedata, DATA, READWRITE
	ALIGN
datastart EQU 0x40000004
	SPACE 20
	 ;FILL 20, 0xff		; Why is this stored at 0x50 instead of 0x58?
	 					; Or maybe a better question:  How do I set data at
						; a specific memory location?

 		END


  • LCD Example
;---------------------------------------------------------------------------
;
;   Programmer  : Larry Aamodt
;
;   File name  	: shell_2148.s 
;   Class       : CPTR-215
;   Language    : ARM assembly
;   Assembler   : Keil
;   Target MCU	: NXP LPC-2148 on Embedded Artists board
;   Date Written: 11/30/09  
;    change history:  11/30/09  LDA  Updated with hardware start-up
;    		      12/03/09  LDA  PWM register definitions added 
;   Description	: 
;
;   Inputs      :
;   
;   Outputs     :
;
;   Special     :  
;  requirements
;   
;
; 	NOTES: 
;
; 
;
;---------------------------------------------------------------------------

; Put application program definitions (i.e. equates) here:


; Standard definitions of Mode bits and Interrupt (I & F) flags in PSRs

Mode_USR        EQU     0x10
Mode_FIQ        EQU     0x11
Mode_IRQ        EQU     0x12
Mode_SVC        EQU     0x13
Mode_ABT        EQU     0x17
Mode_UND        EQU     0x1B
Mode_SYS        EQU     0x1F

I_Bit           EQU     0x80            ; when I bit is set, IRQ is disabled
F_Bit           EQU     0x40            ; when F bit is set, FIQ is disabled

;  Memory addresses for standard GPIO definitions
IO0PIN		    EQU     0xE0028000
IO0SET		    EQU     0xE0028004
IO0DIR		    EQU     0xE0028008
IO0CLR		    EQU     0xE002800C
;  Memory addresses for Pulse Width Modulation (PWM)
PWM_TCR         EQU     0xE0014004      ; PWM_TCR Timer Control Register
PWM_PR          EQU     0xE001400C      ; PWM_PR Prescaler Register
PWM_MCR         EQU     0xE0014014      ; PWM_MCR Match Control Register
PWM_MR0         EQU     0xE0014018      ; PWM_MR0 Match Register 0 (sets pulse period)
PWM_MR4         EQU     0xE0014040      ; PWM_MR4 Match Register 4 (sets pulse length)
PWM_MR6         EQU     0xE0014048      ; PWM_MR6 Match Register 6 (sets pulse length)
PWM_PCR         EQU     0xE001404C      ; PWM_CR Control Register
PWM_LER         EQU     0xE0014050      ; PWM_LER Latch Enable Register

PINSEL0         EQU     0xE002C000      ; Pin connect block - port 0
PINSEL1         EQU     0xE002C004      ; Pin connect block - port 1

;  Stack size definitions
UND_Stack_Size  EQU     0x00000000
SVC_Stack_Size  EQU     0x00000008
ABT_Stack_Size  EQU     0x00000000
FIQ_Stack_Size  EQU     0x00000000
IRQ_Stack_Size  EQU     0x00000080
USR_Stack_Size  EQU     0x00000400

ISR_Stack_Size  EQU     (UND_Stack_Size + SVC_Stack_Size + ABT_Stack_Size + \
                         FIQ_Stack_Size + IRQ_Stack_Size)

                AREA    STACK, NOINIT, READWRITE, ALIGN=3

Stack_Mem       SPACE   USR_Stack_Size
__initial_sp    SPACE   ISR_Stack_Size
Stack_Top


; Area Definition and Entry Point
;  Startup Code must be linked first at Address at which it expects to run.

                AREA    RESET, CODE, READONLY
                ARM


; Exception Vectors
;  Mapped to Address 0.
;  Absolute addressing mode must be used.
;  Dummy Handlers are implemented as infinite loops which can be modified.

Vectors         LDR     PC, Reset_Addr         
                LDR     PC, Undef_Addr
                LDR     PC, SWI_Addr
                LDR     PC, PAbt_Addr
                LDR     PC, DAbt_Addr
                NOP                            ; Reserved Vector 
;               LDR     PC, IRQ_Addr
                LDR     PC, [PC, #-0x0FF0]     ; Vector from VicVectAddr
                LDR     PC, FIQ_Addr

Reset_Addr      DCD     Reset_Handler
Undef_Addr      DCD     Undef_Handler
SWI_Addr        DCD     SWI_Handler
PAbt_Addr       DCD     PAbt_Handler
DAbt_Addr       DCD     DAbt_Handler
                DCD     0                      ; Reserved Address 
IRQ_Addr        DCD     IRQ_Handler
FIQ_Addr        DCD     FIQ_Handler

Undef_Handler   B       Undef_Handler
SWI_Handler     B       SWI_Handler
PAbt_Handler    B       PAbt_Handler
DAbt_Handler    B       DAbt_Handler
IRQ_Handler     B       IRQ_Handler
FIQ_Handler     B       FIQ_Handler

; Reset Handler

                EXPORT  Reset_Handler
Reset_Handler   

; Setup Stack for each mode

                LDR     R0, =Stack_Top

;  Enter Undefined Instruction Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_UND:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #UND_Stack_Size

;  Enter Abort Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_ABT:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #ABT_Stack_Size

;  Enter FIQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_FIQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #FIQ_Stack_Size

;  Enter IRQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_IRQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #IRQ_Stack_Size

;  Enter Supervisor Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_SVC:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #SVC_Stack_Size

;  Enter User Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_USR

                MOV     SP, R0
                SUB     SL, SP, #USR_Stack_Size


; User program code goes here

main
	bl lcdReset ; set up the lcd
	bl lcdClear
	mov r0, #32
loop
	bl lcdWRdata ; write to the LCD
	add r0, r0, #1 ; increment the data
	mov r9, r0
	ldr r0, =1000000
	bl delay
	mov r0, r9
	b loop

; User data area definition follows

                AREA  appdata, DATA, NOINIT, READWRITE

               

;-----------------------------------------------------------------------------
;	Copyright (C) 2012 ....
;
;   Programmer  : Larry Aamodt
;
; 	File name  	: lcd_routines.asm 
;   Language    : ARM assembly
;   Assembler   ; Keil
; 	Target MCU	: NXP LPC2148 on Embedded Artists education board
;   Date        : 12/05/12   LDA   lcd_routines.asm.  debugged

;    
; 	Description	:	LCD display routines 
;					Copy this code to your own program
;
;                  Procedures you can call are:
;                    lcdReset       must be called first.  no parameters.
;                    lcdClear       use to clear the display & home the cursor
;                                     no parameters are required.
;                    lcdWRdata      use to write one character on the display
;                                     place an ASCII char in r0 before calling.
;                                     The cursor will advance.
;                    lcdCursorAt    use to move the cursor.  Two parameters
;                                     r0 = row (1 or 2)
;                                     r1 = column to move cursor to (0-15)
;
;                  Example use of the LCD routines:
;                    bl    lcdReset   ; do this once at the top of your program
;
;                    mov   r0,#31h    ; place the ascii code for number one in r0
;					 bl    lcdWRdata  ; display the character '1' on LCD display
;
;					 bl    lcdClear   ; clear the display 
;
;                    mov   r0,#1      ; select LCD row 1
;                    mov   r1,#4      ; select LCD column 4
;                    bl    lcdCursorAt ;  move the cursor
;                  
;
;          NOTE:   All registers are saved by these routines, i.e. upon return
;                  from the subroutine all registers, except flags, have the
;                  same value in them as before the subroutine was called (this
;                  breaks with the ARM convention for subroutines but is done 
;                  to make it easier for you).
;
;-----------------------------------------------------------------------------

                    AREA  lcdroutines,CODE,READONLY

					EXPORT	lcdReset
					EXPORT	lcdClear
					EXPORT	lcdWRdata
					EXPORT	lcdCursorAt
					EXPORT	delay

; -----------------------------------------------------------------------------
;  LCD Procedures follow. 
;------------------------------------------------------------------------------
; ***** LCD equates	******
;IO0PIN          EQU     0xE0028000
;IO0SET          EQU     0xE0028004
;IO0DIR          EQU     0xE0028008
;IO0CLR          EQU     0xE002800C

IO1PIN          EQU     0xE0028010
IO1SET          EQU     0xE0028014
IO1DIR          EQU     0xE0028018
IO1CLR          EQU     0xE002801C

T0_TCR_ADDR		EQU		0xE0004004
T0_PR_ADDR		EQU		0xE000400C
T0_MCR_ADDR		EQU		0xE0004014
T0_MR0_ADDR		EQU		0xE0004018
; -----------------------------------------------------------------------------
;   Procedure lcdReset        Must be called before writing to the LCD
;                             No parameters required
; -----------------------------------------------------------------------------
lcdReset			STMFD	SP!,{LR,r0,r1,r2,r3,r4,r5,r6,r7,r8,r9}

					LDR		r1,=T0_PR_ADDR			; Prescale register 
					MOV		r2,#2 					; prescale count value
					STR		r2,[r1]					; Prescaler will divide by 3

					LDR		r1,=T0_MCR_ADDR			; Match control register
					MOV		r2,#0x6					; bit 2 = one
					STR		r2,[r1]					; stop counter when match reached

					LDR		r5,=IO0CLR
					LDR		r6,=IO0SET
					LDR		r7,=IO1CLR
					LDR		r8,=IO1SET
					
					LDR		r0,=35000
					BL		delay			; delay 35ms

					LDR		r0,=IO0DIR
				   	LDR		r4,[r0]			; read current Port 0 direction bits
					LDR		r3,=0x40408000  ; one's for pins to be set for output
					ORR		r4,r4,r3		;    bits 22 & 30 to be outputs
					STR		r4,[r0]			; set lcd port bits to output
					LDR		r3,=0x00400000	; 
					STR		r3,[r5]			; write 0 to LCD R/W signal
					LDR		r3,=0x40008000
					STR		r3,[r6]			; turn on backlight - write 1 to P0.30

					LDR		r0,=IO1DIR
					LDR		r4,[r0]			; read current Port 1 direction bits
					LDR		r3,=0x03FF0000  ; one's for lcd pins - set for output
					ORR		r4,r4,r3		;    bits 16 to 25 to be outputs
					STR		r4,[r0]			; set lcd port direction bits to output
					STR		r3,[r7]			; clear the LCD data & control bits					

					LDR		r9,=0x02000000	; bit pattern to turn on/off E

					LDR		r2,=0x00380000	; function: 2 lines, 5x7 dots
					STR		r2,[r8]			; set lcd function bits
					BL		pulse_e
					STR		r3,[r7]			; clear lcd bits

					MOV		r0,#40
					BL		delay			;  wait 40 microseconds

					LDR		r2,=0x000E0000	; function:  display on, cursor on
					STR		r2,[r8]			; set lcd function bits
					BL		pulse_e
					STR		r3,[r7]			; clear lcd bits

					MOV		r0,#40
					BL		delay			;  wait 40 microseconds
					
					LDR		r2,=0x00010000	; lcd function:  clear display
					STR		r2,[r8]			; set lcd function bits
					BL		pulse_e
					STR		r3,[r7]			; clear lcd bits

					MOV		r0,#1600
					BL		delay			; delay for 1600 microseconds

					LDR		r2,=0x00030000	; lcd function:  set entry mode
					STR		r2,[r8]			; set lcd function bits
					BL		pulse_e
					STR		r3,[r7]			; clear lcd bits

end_lcdReset		LDMFD	SP!,{PC,r0,r1,r2,r3,r4,r5,r6,r7,r8,r9}

;------------------------------------------------------------------------------
;   Procedure pulse_e		uses r0. Not interuptable (r14 not saved)
;							assumes r9 has 0x02000000 in it
;                           assumes r7 has IO1CLR address in it
;							assumes r8 has IO1SET address in it
;------------------------------------------------------------------------------
pulse_e 			MOV		r0,#4
					STR		r9,[r8]			; assert E
ploop1				SUBS	r0,r0,#1		; delay	600ns or so
					BNE		ploop1
					STR		r9,[r7]			; de-assert E
					MOV		r0,#8
ploop2				SUBS	r0,r0,#1		; delay 1100ns or so
					BNE		ploop2
end_pulse_e			BX		LR
					            
; -----------------------------------------------------------------------------
;   Procedure lcdClear    Clears the LCD and positions cursor to line1, left col
;               					no parameters required
; -----------------------------------------------------------------------------
lcdClear			STMFD	SP!,{LR,r0,r1,r2,r3,r7,r8,r9}

					LDR		r9,=0x02000000	; bit pattern to turn on/off E
					LDR		r3,=0x03FF0000  ; one's for pins used for lcd
					LDR		r7,=IO1CLR
					LDR		r8,=IO1SET

					LDR		r2,=0x00010000	; lcd function:  clear display
					STR		r2,[r8]			; set lcd function bits
					BL		pulse_e
					STR		r3,[r7]			; clear lcd bits

					MOV		r0,#1600
					BL		delay

end_lcdClear		LDMFD	SP!,{PC,r0,r1,r2,r3,r7,r8,r9}
; -----------------------------------------------------------------------------
;   Procedure lcdCursorAt
;                          r0 assumed to contain the row# (1 or 2)
;                          r1 assumed to contain col#(0-15)
;                          No cursor movement if invalid row or col # is found
; -----------------------------------------------------------------------------

lcdCursorAt			STMFD	SP!,{LR,r0,r1,r2,r3,r7,r8,r9}

					CMP		r1,#15			; check column & row range
					BHI		end_lcdCursorAt
					CMP		r0,#0
					BEQ		end_lcdCursorAt
					CMP		r0,#2
					BHI		end_lcdCursorAt
					ADDEQ	r1,r1,#0x40		; build the cursor address
					LDR		r0,=0x00800000
					ORR		r2,r0,r1,LSL #16 ; r2 now has the address

					LDR		r3,=0x03FF0000  ; one's for pins used for lcd
					LDR		r7,=IO1CLR
					LDR		r8,=IO1SET
					LDR		r9,=0x02000000	; bit pattern to turn on/off E

					STR		r2,[r8]			; set lcd function bits
					BL		pulse_e
					STR		r3,[r7]			; clear lcd bits

					MOV		r0,#40
					BL		delay

end_lcdCursorAt		LDMFD	SP!,{PC,r0,r1,r2,r3,r7,r8,r9}

; -----------------------------------------------------------------------------
;   Procedure lcdWRdata         Writes data (an ASCII character) to the
;                               current cursor position on the LCD
;                               r0 is assumed to contain the character to send
; -----------------------------------------------------------------------------
lcdWRdata	   		STMFD	SP!,{LR,r0,r1,r2,r3,r7,r8,r9}

					LDR		r9,=0x02000000	; bit pattern to turn on/off E
					LDR		r3,=0x03FF0000  ; one's for pins used for lcd
					LDR		r7,=IO1CLR
					LDR		r8,=IO1SET

					AND		r0,r0,#0xFF		; make sure only 8 bits are non-zero
					ORR		r0,r0,#0x100	; set bit that indicates writing
					LSL		r0,r0,#16
					STR		r0,[r8]			; write data
					BL		pulse_e
					STR		r3,[r7]			; clear lcd bits

end_lcdWRData		LDMFD	SP!,{PC,r0,r1,r2,r3,r7,r8,r9}

; -----------------------------------------------------------------------------
;   Procedure  delay          microsecond delay using timer 0
;                               (12Mhz clock & VPB divide by 4 assumed)
;                             reg R0 must contain a delay value in uS
;                             Not interruptable (r14 not saved)
;							  assumes lcdReset has been called prior to delay
;                             r0, r1 not preserved
; -----------------------------------------------------------------------------

delay				LDR		r1,=T0_MR0_ADDR			; Match register zero
					STR		r0,[r1]					; load match count per R0

;					ldr		r0,=0x8000
;					str		r0,[r5]					; turn on p0.15 led

					LDR		r1,=T0_TCR_ADDR			; Timer 0 Control Register
					MOV		r0,#2					; bit 1 = one
					STR		r0,[r1]					; Clear counter & prescaler
					MOV		r0,#0
					STR		r0,[r1]

					MOV		r0,#1					; bit 0 = one
					STR		r0,[r1]					; Turn on counter

dloop				LDR     r0,[r1]					; Read TCR register
					ANDS	r0,r0,#1
					BNE		dloop

;					ldr		r0,=0x8000
;					str		r0,[r6]					; turn off p0.15 led

end_delay			BX		LR						; Return

					END

  • PWM Example for running the servos on the robots
;---------------------------------------------------------------------------
;
;   Programmer  : Larry Aamodt
;
;   File name  	: shell_2148.s 
;   Class       : CPTR-215
;   Language    : ARM assembly
;   Assembler   : Keil
;   Target MCU	: NXP LPC-2148 on Embedded Artists board
;   Date Written: 11/30/09  
;    change history:  11/30/09  LDA  Updated with hardware start-up
;    		      12/03/09  LDA  PWM register definitions added 
;   Description	: 
;
;   Inputs      :
;   
;   Outputs     :
;
;   Special     :  
;  requirements
;   
;
; 	NOTES: 
;
; 
;
;---------------------------------------------------------------------------

; Put application program definitions (i.e. equates) here:


; Standard definitions of Mode bits and Interrupt (I & F) flags in PSRs

Mode_USR        EQU     0x10
Mode_FIQ        EQU     0x11
Mode_IRQ        EQU     0x12
Mode_SVC        EQU     0x13
Mode_ABT        EQU     0x17
Mode_UND        EQU     0x1B
Mode_SYS        EQU     0x1F

I_Bit           EQU     0x80            ; when I bit is set, IRQ is disabled
F_Bit           EQU     0x40            ; when F bit is set, FIQ is disabled

;  Memory addresses for standard GPIO definitions
IO0PIN		    EQU     0xE0028000
IO0SET		    EQU     0xE0028004
IO0DIR		    EQU     0xE0028008
IO0CLR		    EQU     0xE002800C
;  Memory addresses for Timer/Counter 
T1TCR			EQU	 	0xE0008004
T1CTCR			EQU	  	0xE0008070
T1PR			EQU	 	0xE000800C 

T1MCR			EQU	   	0xE0008014
T1EMR 			EQU	  	0xE000803C 


;  Memory addresses for Pulse Width Modulation (PWM)
PWM_TCR         EQU     0xE0014004      ; PWM_TCR Timer Control Register
PWM_PR          EQU     0xE001400C      ; PWM_PR Prescaler Register
PWM_MCR         EQU     0xE0014014      ; PWM_MCR Match Control Register
PWM_MR0         EQU     0xE0014018      ; PWM_MR0 Match Register 0 (sets pulse period)
PWM_MR4         EQU     0xE0014040      ; PWM_MR4 Match Register 4 (sets pulse length)
PWM_MR6         EQU     0xE0014048      ; PWM_MR6 Match Register 6 (sets pulse length)
PWM_PCR         EQU     0xE001404C      ; PWM_CR Control Register
PWM_LER         EQU     0xE0014050      ; PWM_LER Latch Enable Register

PINSEL0         EQU     0xE002C000      ; Pin connect block - port 0
PINSEL1         EQU     0xE002C004      ; Pin connect block - port 1

;  Stack size definitions
UND_Stack_Size  EQU     0x00000000
SVC_Stack_Size  EQU     0x00000008
ABT_Stack_Size  EQU     0x00000000
FIQ_Stack_Size  EQU     0x00000000
IRQ_Stack_Size  EQU     0x00000080
USR_Stack_Size  EQU     0x00000400

ISR_Stack_Size  EQU     (UND_Stack_Size + SVC_Stack_Size + ABT_Stack_Size + \
                         FIQ_Stack_Size + IRQ_Stack_Size)

                AREA    STACK, NOINIT, READWRITE, ALIGN=3

Stack_Mem       SPACE   USR_Stack_Size
__initial_sp    SPACE   ISR_Stack_Size
Stack_Top


; Area Definition and Entry Point
;  Startup Code must be linked first at Address at which it expects to run.

                AREA    RESET, CODE, READONLY
                ARM


; Exception Vectors
;  Mapped to Address 0.
;  Absolute addressing mode must be used.
;  Dummy Handlers are implemented as infinite loops which can be modified.

Vectors         LDR     PC, Reset_Addr         
                LDR     PC, Undef_Addr
                LDR     PC, SWI_Addr
                LDR     PC, PAbt_Addr
                LDR     PC, DAbt_Addr
                NOP                            ; Reserved Vector 
;               LDR     PC, IRQ_Addr
                LDR     PC, [PC, #-0x0FF0]     ; Vector from VicVectAddr
                LDR     PC, FIQ_Addr

Reset_Addr      DCD     Reset_Handler
Undef_Addr      DCD     Undef_Handler
SWI_Addr        DCD     SWI_Handler
PAbt_Addr       DCD     PAbt_Handler
DAbt_Addr       DCD     DAbt_Handler
                DCD     0                      ; Reserved Address 
IRQ_Addr        DCD     IRQ_Handler
FIQ_Addr        DCD     FIQ_Handler

Undef_Handler   B       Undef_Handler
SWI_Handler     B       SWI_Handler
PAbt_Handler    B       PAbt_Handler
DAbt_Handler    B       DAbt_Handler
IRQ_Handler     B       IRQ_Handler
FIQ_Handler     B       FIQ_Handler

; Reset Handler

                EXPORT  Reset_Handler
Reset_Handler   

; Setup Stack for each mode

                LDR     R0, =Stack_Top

;  Enter Undefined Instruction Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_UND:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #UND_Stack_Size

;  Enter Abort Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_ABT:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #ABT_Stack_Size

;  Enter FIQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_FIQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #FIQ_Stack_Size

;  Enter IRQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_IRQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #IRQ_Stack_Size

;  Enter Supervisor Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_SVC:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #SVC_Stack_Size

;  Enter User Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_USR

                MOV     SP, R0
                SUB     SL, SP, #USR_Stack_Size


; User program code goes here

main
				BL   pwm_init
				mov r0, #3
				ldr r1, =1600
				mov r2, r1
				bl pwm_update
stop			b stop


;*****************************************************************************
;    Pulse width modulator initialization routine.
;          pulse period = 20ms;  initial pulse length = 1.5ms
;          (values shown are for controlling model plane servos)
;    Inputs: none
;    Returned values: none
;    Uses registers r0, r1
;
;    Calling method:   BL   pwm_init
;                                                   LDA   rev 1.0  12/01/10
;													Rob Frohne rev 1.1 12/3/13
;*****************************************************************************
; Stepper motor connections on the Board of Education are from page 24 of the board 
; Users Guide.  A stepper motor operation is explained at:
; http://www.haydonkerk.com/Resources/StepperMotorTheory/tabid/192/Default.aspx
;
; PWM is explained in Chapter 16 (page 253 and following) of the reference manual.
; Note the registers in the reference manual are labeled without the _, i.e. 
; 	PWMPR instead of PWM_PR.

pwm_init		STMFD	sp!,{r14}		; save link register on the stack

		        LDR     r0,=PWM_PR
				LDR     r1,=2			; prescaler = 2 divides PCLK by 3
                STR     r1,[r0]         ; load prescaler
                                        ; PCLK rate is 1 MHZ (1 uSEC period) after division.
                LDR     r0,=PWM_MCR		; PWMMCR PWM Match Control Register. 
										; The PWMMCR is used to control if an 

										; interrupt is generated and if the PWMTC 
										; is reset when a Match occurs.  See page 261 of the manual.
				LDR     r1,=0x02        ; bit 1 is set, others are zero
				STR     r1,[r0]         ; load PWM_MCR: PWM_TC resets when PWM_TC=PWM_MR0

                LDR     r0,=PWM_MR0
				LDR     r1,=20000       ; count 20,000 1uSEC intervals = 20 milli secs
				STR     r1,[r0]         ; load match register 0. sets pulse period.  Page 261.

				LDR     r0,=PWM_MR4		
                LDR     r1,=1500		; initial pulse width = 1.5 milli secs
				STR     r1,[r0]         ; load match register 4.  Page 261
				LDR     r0,=PWM_MR6		
				LDR     r1,=1500		; initial pulse width
				STR     r1,[r0]			; load match register 6

	            LDR     r0,=PWM_LER
				LDR     r1,=0x51
				STR     r1,[r0]         ; Enable latch registers 0, 4, & 6

                LDR     r0,=PWM_PCR
				LDR     r1,=0x5000      ; bits 12 & 14 set
				STR     r1,[r0]         ; load PWM_CR: enables PWM4 and PWM6 outputs

                LDR     r0,=PWM_TCR
				LDR     r1,=0x09        ; bits 3,1,0 set
				STR     r1,[r0]         ; load PWM_TCR enable PWM counter & prescaler

                LDR     r0,=PINSEL0
                LDR     r1,=0xA0000     ; bits 19 & 17 set.  selects output PWM 6 & 4
				STR     r1,[r0]		    ; Enable PWM6 & PWM4 outputs

end_pwm_init	LDMFD	sp!,{pc}		; Return from subroutine  pwm_init


;*****************************************************************************
;   Pulse width modulator update routine
;	Inputs:  r0 = command
;                   1 = update PWM channel 4
;                   2 = update PWM channel 6
;                   3 = update both channel 4 and 6
;            r1 = new pulse width (# of microseconds) for PWM channel 4
;            r2 = new pulse width (# of microseconds) for PWM channel 6
;   Returned values: none
;   Uses registers r0, r1, r2, r3
;
;   Calling method:  first put values in r0, r1, r2 as appropriate
;                    BL pwm_update
;                                                   LDA    rev 2.0  12/01/11
;*****************************************************************************

pwm_update		STMFD	sp!,{r14}		; r0 specifies channels to update 

load_pwm4		CMP		r0,#1			; 1 = load PWM chan 4
				BNE		load_pwm6
				LDR     r3,=PWM_MR4
				STR     r1,[r3]         ; load match register 4

load_pwm6		CMP		r0,#2			; 2 = load PWM chan 6
				BNE		load_both
				LDR     r3,=PWM_MR6
				STR     r2,[r3]			; load match register 6

load_both		CMP		r0,#3
				BNE		pwm_reg_update
				LDR		r3,=PWM_MR4
				STR		r1,[r3]
				LDR		r3,=PWM_MR6
				STR		r2,[r3]

pwm_reg_update	CMP		r0,#1			; check for just pwm 4 update
				MOVEQ	r1,#0x10
				CMP		r0,#2			; check for just pwm 6 update
				MOVEQ	r1,#0x40
				CMP		r0,#3			; check for pwm 4 & 6 update
				MOVEQ	r1,#0x50

				LDR		r3,=PWM_LER
				STR		r1,[r3]			; enable latch registers

end_pwm_update	LDMFD	sp!,{pc}		; Return from subroutine  pwm_update

; User data area definition follows

                AREA  appdata, DATA, NOINIT, READWRITE

                END

  • Stepper Motor on the Embedded Artists Board of Education

;---------------------------------------------------------------------------
;
;   Programmer  : Larry Aamodt
;				: Modifications for propeller drive: Rob Frohne
;
;   File name  	: shell_2148.s 
;   Class       : CPTR-215
;   Language    : ARM assembly
;   Assembler   : Keil
;   Target MCU	: NXP LPC-2148 on Embedded Artists board
;   Date Written: 11/30/09  
;    change history:  11/30/09  LDA  Updated with hardware start-up
;    		      12/03/09  LDA  PWM register definitions added 
;   Description	: 
;
;   Inputs      :
;   
;   Outputs     :
;
;   Special     :  
;  requirements
;   
;
; 	NOTES: 
;
; 
;
;---------------------------------------------------------------------------

; Put application program definitions (i.e. equates) here:


; Standard definitions of Mode bits and Interrupt (I & F) flags in PSRs

Mode_USR        EQU     0x10
Mode_FIQ        EQU     0x11
Mode_IRQ        EQU     0x12
Mode_SVC        EQU     0x13
Mode_ABT        EQU     0x17
Mode_UND        EQU     0x1B
Mode_SYS        EQU     0x1F

I_Bit           EQU     0x80            ; when I bit is set, IRQ is disabled
F_Bit           EQU     0x40            ; when F bit is set, FIQ is disabled

;  Memory addresses for standard GPIO definitions
IO0PIN		    EQU     0xE0028000
IO0SET		    EQU     0xE0028004
IO0DIR		    EQU     0xE0028008
IO0CLR		    EQU     0xE002800C

;  Timer addresses
T0_TCR_ADDR		EQU		0xE0004004
T0_PR_ADDR		EQU		0xE000400C
T0_MCR_ADDR		EQU		0xE0004014
T0_MR0_ADDR		EQU		0xE0004018

;  Memory addresses for Pulse Width Modulation (PWM)
PWM_TCR         EQU     0xE0014004      ; PWM_TCR Timer Control Register
PWM_PR          EQU     0xE001400C      ; PWM_PR Prescaler Register
PWM_MCR         EQU     0xE0014014      ; PWM_MCR Match Control Register
PWM_MR0         EQU     0xE0014018      ; PWM_MR0 Match Register 0 (sets pulse period)
PWM_MR4         EQU     0xE0014040      ; PWM_MR4 Match Register 4 (sets pulse length)
PWM_MR6         EQU     0xE0014048      ; PWM_MR6 Match Register 6 (sets pulse length)
PWM_PCR         EQU     0xE001404C      ; PWM_CR Control Register
PWM_LER         EQU     0xE0014050      ; PWM_LER Latch Enable Register

PINSEL0         EQU     0xE002C000      ; Pin connect block - port 0
PINSEL1         EQU     0xE002C004      ; Pin connect block - port 1

;  Stack size definitions
UND_Stack_Size  EQU     0x00000000
SVC_Stack_Size  EQU     0x00000008
ABT_Stack_Size  EQU     0x00000000
FIQ_Stack_Size  EQU     0x00000000
IRQ_Stack_Size  EQU     0x00000080
USR_Stack_Size  EQU     0x00000400

ISR_Stack_Size  EQU     (UND_Stack_Size + SVC_Stack_Size + ABT_Stack_Size + \
                         FIQ_Stack_Size + IRQ_Stack_Size)

                AREA    STACK, NOINIT, READWRITE, ALIGN=3

Stack_Mem       SPACE   USR_Stack_Size
__initial_sp    SPACE   ISR_Stack_Size
Stack_Top


; Area Definition and Entry Point
;  Startup Code must be linked first at Address at which it expects to run.

                AREA    RESET, CODE, READONLY
                ARM


; Exception Vectors
;  Mapped to Address 0.
;  Absolute addressing mode must be used.
;  Dummy Handlers are implemented as infinite loops which can be modified.

Vectors         LDR     PC, Reset_Addr         
                LDR     PC, Undef_Addr
                LDR     PC, SWI_Addr
                LDR     PC, PAbt_Addr
                LDR     PC, DAbt_Addr
                NOP                            ; Reserved Vector 
;               LDR     PC, IRQ_Addr
                LDR     PC, [PC, #-0x0FF0]     ; Vector from VicVectAddr
                LDR     PC, FIQ_Addr

Reset_Addr      DCD     Reset_Handler
Undef_Addr      DCD     Undef_Handler
SWI_Addr        DCD     SWI_Handler
PAbt_Addr       DCD     PAbt_Handler
DAbt_Addr       DCD     DAbt_Handler
                DCD     0                      ; Reserved Address 
IRQ_Addr        DCD     IRQ_Handler
FIQ_Addr        DCD     FIQ_Handler

Undef_Handler   B       Undef_Handler
SWI_Handler     B       SWI_Handler
PAbt_Handler    B       PAbt_Handler
DAbt_Handler    B       DAbt_Handler
IRQ_Handler     B       IRQ_Handler
FIQ_Handler     B       FIQ_Handler

; Reset Handler

                EXPORT  Reset_Handler
Reset_Handler   

; Setup Stack for each mode

                LDR     R0, =Stack_Top

;  Enter Undefined Instruction Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_UND:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #UND_Stack_Size

;  Enter Abort Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_ABT:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #ABT_Stack_Size

;  Enter FIQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_FIQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #FIQ_Stack_Size

;  Enter IRQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_IRQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #IRQ_Stack_Size

;  Enter Supervisor Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_SVC:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #SVC_Stack_Size

;  Enter User Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_USR

                MOV     SP, R0
                SUB     SL, SP, #USR_Stack_Size


; User program code goes here

quarter_period EQU	250000 ; uS
main  				    
					BL init_propeller
					mov r1, #1	 ; for handy access
					mov r2, #0	  ; for handy access

					mov r0, r1, LSL #12		; turn one on
					mov r4, r2, LSL #21		; two still off
					orr r0, r4, r0 ; both on
					ldr r3,=IO0PIN
					str r0,[r3] 
					ldr r0,=quarter_period
					bl delay

					mov r0, r1, LSL #12
					mov r4, r1, LSL #21
					orr r0, r4, r0 ; both on
					ldr r3,=IO0PIN
					str r0,[r3] 
					ldr r0,=quarter_period
					bl delay

					mov r0, r2, LSL #12		; turn one off
					mov r4, r1, LSL #21		; two still on
					orr r0, r4, r0 ; both on
					ldr r3,=IO0PIN
					str r0,[r3] 
					ldr r0,=quarter_period
					bl delay

   					mov r0, r2, LSL #12		; turn one off
					mov r4, r2, LSL #21		; turn two off
					orr r0, r4, r0 ; both on
					ldr r3,=IO0PIN
					str r0,[r3] 
					ldr r0,=quarter_period
					bl delay
				
					b main 

; -----------------------------------------------------------------------------
;   Procedure init_propeller  Must be called before to initialize the propeller.
;							  Set up the counter T0 and GPIO P0.12 and P0.21 for output.
;                             No parameters required
; -----------------------------------------------------------------------------
init_propeller		STMFD	SP!,{LR,r0,r1,r2,r3,r4}

					LDR		r1,=T0_PR_ADDR			; Prescale register 
					MOV		r2,#2 					; prescale count value
					STR		r2,[r1]					; Prescaler will divide by 3  (1 uS period)

					LDR		r1,=T0_MCR_ADDR			; Match control register
					MOV		r2,#0x4					; bit 2 = one: Stop on MR0: the TC and PC 
													; will be stopped and TCR[0] will be set to 0 if 
													; MR0 matches the TC
					STR		r2,[r1]					; stop counter when match reached

					LDR		r0,=IO0DIR
				   	LDR		r4,[r0]			; read current Port 0 direction bits
					LDR		r3,=2101248  	; one's for pins to be set for output (2^12+2^21 = 2101248)
											; 2134016 = 2^12+2^21+2^15 (for debugging LED on P0.15
					ORR		r4,r4,r3		
					STR		r4,[r0]			; set propeller port bits to output without changing others.
					
					LDR		r0,=PINSEL0
				   	LDR		r4,[r0]			; read current Port 0 direction bits
					LDR		r3,=50331648  	; zero's for pins to be set for output (2^24+2^25 = 50331648)
					BIC		r4,r4,r3		;  
					STR		r4,[r0]			; set propeller port P0.12 to GPIO without changing others.

										
					LDR		r0,=PINSEL1
				   	LDR		r4,[r0]			; read current Port 0 direction bits
					LDR		r3,=3072  		; zero's for pins to be set for output (2^10+2^11 = 3072)
					BIC		r4,r4,r3		;  
					STR		r4,[r0]			; set propeller port P0.21 to GPIO without changing others.
				
end_init_propeller	LDMFD	SP!,{PC,r0,r1,r2,r3,r4}



; -----------------------------------------------------------------------------
;   Procedure  delay          microsecond delay using timer 0
;                               (12Mhz clock & VPB divide by 4 assumed)
;                             reg R0 must contain a delay value in uS
;                             Not interruptable (r14 not saved)
;							  assumes lcdReset has been called prior to delay
;                             r0, r1 not preserved
; -----------------------------------------------------------------------------

delay				STMFD	SP!,{LR,r0,r1}
					LDR		r1,=T0_MR0_ADDR			; Match register zero
					STR		r0,[r1]					; load match count per R0

;					ldr		r0,=0x8000
;					str		r0,[r5]					; turn on p0.15 led

					LDR		r1,=T0_TCR_ADDR			; Timer 0 Control Register
					MOV		r0,#2					; bit 1 = one
					STR		r0,[r1]					; Clear counter & prescaler 
					MOV		r0,#0
					STR		r0,[r1]

					MOV		r0,#1					; bit 0 = one
					STR		r0,[r1]					; Turn on counter

dloop				LDR     r0,[r1]					; Read TCR register
					ANDS	r0,r0,#1
					BNE		dloop

;					ldr		r0,=0x8000
;					str		r0,[r6]					; turn off p0.15 led

end_delay			LDMFD	SP!,{PC,r0,r1}			; Return

					END

  • Propeller Drive Using Interrupts (not polled)

;---------------------------------------------------------------------------
;
;   Shell Programmer  : Larry Aamodt, main: Rob Frohne
;				
;
;   File name  	: shell_2148.s 
;   Class       : CPTR-215
;   Language    : ARM assembly
;   Assembler   : Keil
;   Target MCU	: NXP LPC-2148 on Embedded Artists board
;   Date Written: 11/30/09  
;    change history:  11/30/09  LDA  Updated with hardware start-up
;    		      12/03/09  LDA  PWM register definitions added 
;   Description	: 
;
;   Inputs      :
;   
;   Outputs     :
;
;   Special     :  
;  requirements
;   
;
; 	NOTES: 
;
; 
;
;---------------------------------------------------------------------------

; Put application program definitions (i.e. equates) here:


; Standard definitions of Mode bits and Interrupt (I & F) flags in PSRs

Mode_USR        EQU     0x10
Mode_FIQ        EQU     0x11
Mode_IRQ        EQU     0x12
Mode_SVC        EQU     0x13
Mode_ABT        EQU     0x17
Mode_UND        EQU     0x1B
Mode_SYS        EQU     0x1F

I_Bit           EQU     0x80            ; when I bit is set, IRQ is disabled
F_Bit           EQU     0x40            ; when F bit is set, FIQ is disabled

;  Memory addresses for standard GPIO definitions
IO0PIN		    EQU     0xE0028000
IO0SET		    EQU     0xE0028004
IO0DIR		    EQU     0xE0028008
IO0CLR		    EQU     0xE002800C

; Vector Interrupt Controller Addresses
VICIntSelect		EQU 0xFFFFF00C
VICVectAddr4		EQU	0xFFFFF110
VICVectCntl4		EQU	0xFFFFF210
VICIntEnable		EQU	0xFFFFF010
VICVectAddr			EQU 0xFFFFF030


;  Timer addresses
T0PC				EQU	0xE0004010  ; Timer 0 Prescale counter
T0IR				EQU	0xE0004000	; Timer 0 Interrupt Register
T0_TCR_ADDR		EQU		0xE0004004
T0_PR_ADDR		EQU		0xE000400C
T0_MCR_ADDR		EQU		0xE0004014
T0_MR0_ADDR		EQU		0xE0004018

;  Memory addresses for Pulse Width Modulation (PWM)
PWM_TCR         EQU     0xE0014004      ; PWM_TCR Timer Control Register
PWM_PR          EQU     0xE001400C      ; PWM_PR Prescaler Register
PWM_MCR         EQU     0xE0014014      ; PWM_MCR Match Control Register
PWM_MR0         EQU     0xE0014018      ; PWM_MR0 Match Register 0 (sets pulse period)
PWM_MR4         EQU     0xE0014040      ; PWM_MR4 Match Register 4 (sets pulse length)
PWM_MR6         EQU     0xE0014048      ; PWM_MR6 Match Register 6 (sets pulse length)
PWM_PCR         EQU     0xE001404C      ; PWM_CR Control Register
PWM_LER         EQU     0xE0014050      ; PWM_LER Latch Enable Register

PINSEL0         EQU     0xE002C000      ; Pin connect block - port 0
PINSEL1         EQU     0xE002C004      ; Pin connect block - port 1

;  Stack size definitions
UND_Stack_Size  EQU     0x00000000
SVC_Stack_Size  EQU     0x00000008
ABT_Stack_Size  EQU     0x00000000
FIQ_Stack_Size  EQU     0x00000000
IRQ_Stack_Size  EQU     0x00000080
USR_Stack_Size  EQU     0x00000400

ISR_Stack_Size  EQU     (UND_Stack_Size + SVC_Stack_Size + ABT_Stack_Size + \
                         FIQ_Stack_Size + IRQ_Stack_Size)

                AREA    STACK, NOINIT, READWRITE, ALIGN=3

Stack_Mem       SPACE   USR_Stack_Size
__initial_sp    SPACE   ISR_Stack_Size
Stack_Top


; Area Definition and Entry Point
;  Startup Code must be linked first at Address at which it expects to run.

                AREA    RESET, CODE, READONLY
                ARM


; Exception Vectors
;  Mapped to Address 0.
;  Absolute addressing mode must be used.
;  Dummy Handlers are implemented as infinite loops which can be modified.

Vectors         LDR     PC, Reset_Addr         
                LDR     PC, Undef_Addr
                LDR     PC, SWI_Addr
                LDR     PC, PAbt_Addr
                LDR     PC, DAbt_Addr
                NOP                            ; Reserved Vector 
;                LDR     PC, IRQ_Addr
                LDR     PC, [PC, #-0x0FF0]     ; Vector from VicVectAddr
                LDR     PC, FIQ_Addr

Reset_Addr      DCD     Reset_Handler
Undef_Addr      DCD     Undef_Handler
SWI_Addr        DCD     SWI_Handler
PAbt_Addr       DCD     PAbt_Handler
DAbt_Addr       DCD     DAbt_Handler
                DCD     0                      ; Reserved Address 
IRQ_Addr        DCD     IRQ_Handler
FIQ_Addr        DCD     FIQ_Handler

; Exception Handlers
Undef_Handler   B       Undef_Handler
SWI_Handler     B       SWI_Handler
PAbt_Handler    B       PAbt_Handler
DAbt_Handler    B       DAbt_Handler
IRQ_Handler     B       IRQ_Handler
FIQ_Handler     B       FIQ_Handler

; Reset Handler

                EXPORT  Reset_Handler
Reset_Handler   

; Setup Stack for each mode

                LDR     R0, =Stack_Top

;  Enter Undefined Instruction Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_UND:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #UND_Stack_Size

;  Enter Abort Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_ABT:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #ABT_Stack_Size

;  Enter FIQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_FIQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #FIQ_Stack_Size

;  Enter IRQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_IRQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #IRQ_Stack_Size

;  Enter Supervisor Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_SVC:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #SVC_Stack_Size

;  Enter User Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_USR
                MOV     SP, R0
                SUB     SL, SP, #USR_Stack_Size

step_time_uS EQU	250000 ; uS between steps of the propeller motor.

main 				BL init_propeller	 ; Initialize GPIO and IRQ, and Timer 0.

					LDR r0,=step1
					LDR r1,=NextRoutine_Address
					STR r0,[r1]
					bl delay ; start the whole automated thing

do_nothing			b do_nothing	; because the ISR will do it all!

; -----------------------------------------------------------------------------
;   Step the motor routines.  These are called by the Timer0 ISR (timer0ISR)
; -----------------------------------------------------------------------------
 

step1				STMFD	SP!,{LR,r0-r12}
					mov r1, #1	 ; for handy access
					mov r2, #0	  ; for handy access
					mov r0, r1, LSL #12		; turn one on
					mov r4, r2, LSL #21		; two still off
					orr r0, r4, r0 ; both on
					ldr r3,=IO0PIN
					str r0,[r3]
					LDR r0,=step2
					LDR r1,=NextRoutine_Address
					STR r0,[r1] 
					bl delay
					LDMFD	SP!,{PC,r0-r12}

step2				STMFD	SP!,{LR,r0-r12}
					mov r1, #1	 ; for handy access
					mov r2, #0	  ; for handy access
					mov r0, r1, LSL #12
					mov r4, r1, LSL #21
					orr r0, r4, r0 ; both on
					ldr r3,=IO0PIN
					str r0,[r3]
					LDR r0,=step3
					LDR r1,=NextRoutine_Address
					STR r0,[r1] 
					bl delay
					LDMFD	SP!,{PC,r0-r12}

step3				STMFD	SP!,{LR,r0-r12}
					mov r1, #1	 ; for handy access
					mov r2, #0	  ; for handy access
					mov r0, r2, LSL #12		; turn one off
					mov r4, r1, LSL #21		; two still on
					orr r0, r4, r0 ; both on
					ldr r3,=IO0PIN
					str r0,[r3]
					LDR r0,=step4
					LDR r1,=NextRoutine_Address
					STR r0,[r1] 
					bl delay
					LDMFD	SP!,{PC,r0-r12}

step4				STMFD	SP!,{LR,r0-r12}
					mov r1, #1	 ; for handy access
					mov r2, #0	  ; for handy access
					mov r0, r2, LSL #12		; turn one off
					mov r4, r2, LSL #21		; turn two off
					orr r0, r4, r0 ; both on
					ldr r3,=IO0PIN
					str r0,[r3]
					LDR r0,=step1
					LDR r1,=NextRoutine_Address
					STR r0,[r1] 
					bl delay				
					LDMFD	SP!,{PC,r0-r12} 

; -----------------------------------------------------------------------------
;   Procedure init_propeller  Must be called before to initialize the propeller.
;							  Set up GPIO P0.12 and P0.21 for output.
;							  Set up timer 0 and interrupts for IRQ (low priority)
;                             No parameters required
; -----------------------------------------------------------------------------

init_propeller		STMFD	SP!,{LR,r0,r1,r2,r3,r4}
										LDR		r1,=T0_PR_ADDR			; Prescale register 
					MOV		r2,#2 					; prescale count value
					STR		r2,[r1]					; Prescaler will divide by 3  (1 uS period

;  T0MCR = 0x00000003;                           	//reset counter and generate IRQ on MR0 match

					LDR		r1,=T0_MCR_ADDR			; Match control register
					MOV		r2,#0x3					; bit 2 = one: Stop on MR0: the TC and PC : bit 1 = 1 gives interrupt
													; will be stopped and TCR[0] will be set to 0 if 
													; MR0 matches the TC
					STR		r2,[r1]					; stop counter when match reached

;	VICIntSelect &= ~0x10;           //Timer0 interrupt is assigned to IRQ (not FIQ)
					LDR		r1,=VICIntSelect
					MOV 	r0,#~0x10
					STR		r0,[r1]

;	VICVectAddr4  = (tU32)timer0ISR; //register ISR address
					LDR		r1,=VICVectAddr4
					LDR 	r0,=timer0ISR
					STR		r0,[r1]

;	VICVectCntl4  = 0x24;            //enable vector interrupt for timer0
					LDR		r1,=VICVectCntl4
					MOV 	r0,#0x24
					STR		r0,[r1]

;	VICIntEnable  = 0x10;            //enable timer0 interrupt
					LDR		r1,=VICIntEnable
					MOV 	r0,#0x10
					STR		r0,[r1]		

					LDR		r0,=IO0DIR
				   	LDR		r4,[r0]			; read current Port 0 direction bits
					LDR		r3,=2101248  	; one's for pins to be set for output (2^12+2^21 = 2101248)
											; 2134016 = 2^12+2^21+2^15 (for debugging LED on P0.15
					ORR		r4,r4,r3		
					STR		r4,[r0]			; set propeller port bits to output without changing others					

					LDR		r0,=PINSEL0
				   	LDR		r4,[r0]			; read current Port 0 direction bits
					LDR		r3,=50331648  	; zero's for pins to be set for output (2^24+2^25 = 50331648)
					BIC		r4,r4,r3		;  
					STR		r4,[r0]			; set propeller port P0.12 to GPIO without changing others.										

					LDR		r0,=PINSEL1
				   	LDR		r4,[r0]			; read current Port 0 direction bits
					LDR		r3,=3072  		; zero's for pins to be set for output (2^10+2^11 = 3072)
					BIC		r4,r4,r3		;  
					STR		r4,[r0]			; set propeller port P0.21 to GPIO without changing others.				

end_init_propeller	LDMFD	SP!,{PC,r0,r1,r2,r3,r4}

; -----------------------------------------------------------------------------
;  			Timer 0 Interrupt Service Routine  timer0ISR
; 			Some comments are C equivalents.
; -----------------------------------------------------------------------------

timer0ISR		 	SUB LR,LR,#4	 ; Update the LR
					STMFD SP!, {r0-r12,LR}	  ; Store registers (including LR)

;  T0IR        = 0xff;        //reset all IRQ flags
					LDR		r1,=T0IR
					MOV 	r0,#~0xff
					STR		r0,[r1]

;  VICVectAddr = 0x00;        //dummy write to VIC to signal end of interrupt
					LDR		r1,=VICVectAddr
					MOV 	r0,#~0x00
					STR		r0,[r1]

; Here we will branch to the appropriate next step routine.
					LDR r0,=NextRoutine_Address
					push {r14}  ; save LR for this return.
					ldr r14,=end_timer0ISR  ; load the LR because we are using an LDR PC below.
					ldr PC,[r0] ; branch to the subroutine pointed to by NextRoutine_Address
end_timer0ISR		pop {r14}	; restore the LR for this return.
					LDMFD SP!, {r0-r12,PC}^  			; Return from ISR

; -----------------------------------------------------------------------------
;   Procedure  delay          microsecond delay using timer 0
;                               (12Mhz clock & VPB divide by 4 assumed)
;                  				Delay is set by step_time_uS
; -----------------------------------------------------------------------------

delay				STMFD	SP!,{LR,r0,r1}


;  T0PC  = 0x00000000;    Didn't do this yet.  Unnecessary?                       //no prescale of clock

				;	LDR		r1,=T0PC
				;	MOV 	r0,#0x00000000
				;	STR		r0,[r1]

;  T0IR  = 0x000000ff;                           //reset all flags before enable IRQs

					LDR		r1,=T0IR
					MOV 	r0,#0x000000ff
					STR		r0,[r1]

;  T0MR0 = delayInMs *                           //calculate no of timer ticks
;         ((CRYSTAL_FREQUENCY * PLL_FACTOR) / (1000 * VPBDIV_FACTOR));
					LDR		r1,=T0_MR0_ADDR			; Match register zero
					LDR		r0,=step_time_uS
					STR		r0,[r1]					; load match count from step_time_uS

;  T0TCR = 0x00000002;                           //disable and reset Timer0
					LDR		r1,=T0_TCR_ADDR			; Timer 0 Control Register
					MOV		r0,#2					; bit 1 = one
;  T0TCR = 0x00000001;                           //start Timer0
					STR		r0,[r1]					; Clear counter & prescaler 
					MOV		r0,#0
					STR		r0,[r1]

					MOV		r0,#1					; bit 0 = one
					STR		r0,[r1]					; Turn on counter

end_delay			LDMFD	SP!,{PC,r0,r1}			; Return

                	AREA Thedata, DATA, READWRITE
					ALIGN
NextRoutine_Address SPACE 4	 ; This holds the address of the next step subroutine.

					END