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I am trying to interpret the assembly code for the TI MSP 430 below. As I step through the lines in my debugger, the subroutine "beep02" continues to loop for an amount of time of which I don't know the origin, and then suddenly it jumps into the "WDT_ISR" subroutine.

My assumption is that somehow that watchdog interrupt service is being called when 'the dog barks' and will take the program from the normally functioning code thats in a loop and advance at to the WDT_ISR. Is this correct?

        .title  "morse.asm"
;     Project:  morse.asm
;      Author:  Spencer Gardner
; Description:  Outputs a message in Morse Code using a LED and a transducer
;               (speaker).  The watchdog is configured as an interval timer.
;               The watchdog interrupt service routine (ISR) toggles the green
;               LED every second and pulse width modulates (PWM) the speaker
;               such that a tone is produced.
;   Revisions:
;              RBX430-1                                    eZ430 Rev C
;              OPTION A                                     OPTION B
;           .------------.                               .------------.
;     SW1-->|P1.0^   P3.0|-->LCD_A0         (RED) LED<--|P1.0     P3.0|-->LCD_RST
;     SW2-->|P1.1^   P3.1|<->SDA          (GREEN) LED<--|P1.1     P3.1|<->SDA
;     SW3-->|P1.2^   P3.2|-->SCL                   NC-->|P1.2     P3.2|-->SCL
;     SW4-->|P1.3^   P3.3|-->LCD_RW                NC-->|P1.3     P3.3|-->LED_3 (Y)
;    INT1-->|P1.4    P3.4|-->LED_5 (GREEN)         NC-->|P1.4     P3.4|<--NC
;    INTA-->|P1.5    P3.5|<--RX                    NC-->|P1.5     P3.5|<--NC
;    SVO1<--|P1.6    P3.6|<--RPOT                  NC-->|P1.6     P3.6|<--NC
;    SVO2<--|P1.7    P3.7|<--LPOT                  NC-->|P1.7     P3.7|<--NC
;           |            |                              |             |
;  LCD_D0<->|P2.0    P4.0|-->LED_1 (G)           SW_1-->|P2.0^    P4.0|<--NC
;  LCD_D1<->|P2.1    P4.1|-->LED_2 (O)           SW_2-->|P2.1^    P4.1|<--NC
;  LCD_D2<->|P2.2    P4.2|-->LED_3 (Y)           SW_3-->|P2.2^    P4.2|<--NC
;  LCD_D3<->|P2.3    P4.3|-->LED_4 (R)           SW_4-->|P2.3^    P4.3|<--RPOT
;  LCD_D4<->|P2.4    P4.4|-->LCD_BL            LCD_BL<--|P2.4     P4.4|<--LPOT
;  LCD_D5<->|P2.5    P4.5|-->SPEAKER               NC-->|P2.5     P4.5|-->SPEAKER
;  LCD_D6<->|P2.6    P4.6|-->LED_6 (RED)    (G) LED_1<--|P2.6     P4.6|-->LED_4 (R)
;  LCD_D7<->|P2.7    P4.7|-->LCD_E          (O) LED_2<--|P2.7     P4.7|<--NC
;           .------------.                               .------------.
            .cdecls C,LIST,"msp430.h"       ; include c header

;   System equates
myCLOCK     .equ    1200000                 ; 1.2 Mhz clock
WDT_CTL     .equ    WDT_MDLY_0_5            ; WD configuration (Timer, SMCLK, 0.5 ms)
WDT_CPI     .equ    500                     ; WDT Clocks Per Interrupt (@1 Mhz)
WDT_IPS     .equ    myCLOCK/WDT_CPI         ; WDT Interrupts Per Second
STACK       .equ    0x0600                  ; top of stack

;   External references
            .ref    numbers                 ; codes for 0-9
            .ref    letters                 ; codes for A-Z

;  numbers--->N0$--->DASH,DASH,DASH,DASH,DASH,END      ; 0
;             N1$--->DOT,DASH,DASH,DASH,DASH,END       ; 1
;             ...
;             N9$--->DASH,DASH,DASH,DASH,DOT,END       ; 9
;  letters--->A$---->DOT,DASH,END                      ; A
;             B$---->DASH,DOT,DOT,DOT,END              ; B
;             ...
;             Z$---->DASH,DASH,DOT,DOT,END             ; Z

;   Morse code is composed of dashes and dots, or phonetically, "dits" and "dahs".
;   There is no symbol for a space in Morse, though there are rules when writing them.

;   1. One dash is equal to three dots
;   2. The space between parts of the letter is equal to one dot
;   3. The space between two letters is equal to three dots
;   4. The space between two words is equal to seven dots.

;   5 WPM = 60 sec / (5 * 50) elements = 240 milliseconds per element.
;   element = (WDT_IPS * 6 / WPM) / 5

;   Morse Code equates
ELEMENT     .equ    WDT_IPS*240/1000

;   Global variables                        ; RAM section
            .bss    beep_cnt,2              ; beeper flag
            .bss    delay_cnt,2             ; delay flag

;   Program section
            .text                           ; program section
message:    .string "HELLO CS 124 WORLD"                 ; PARIS message
            .byte   0
            .align  2                       ; align on word boundary

RESET:      mov.w   #STACK,SP               ; initialize stack pointer
            mov.w   #WDT_CTL,&WDTCTL        ; set WD timer interval
            mov.b   #WDTIE,&IE1             ; enable WDT interrupt
            bis.b   #0x20,&P4DIR            ; set P4.5 as output (speaker)
            clr.w   beep_cnt                ; clear counters
            clr.w   delay_cnt
            bis.w   #GIE,SR                 ; enable interrupts

;   output 'A' in morse code
loop:       mov.w   #ELEMENT,r15            ; output DOT
            call    #beep
            mov.w   #ELEMENT,r15            ; delay 1 element
            call    #delay

            mov.w   #ELEMENT*3,r15          ; output DASH
            call    #beep
            mov.w   #ELEMENT,r15            ; delay 1 element
            call    #delay

            mov.w   #ELEMENT*3,r15          ; output DASH
            call    #beep
            mov.w   #ELEMENT,r15            ; delay 1 element
            call    #delay

            mov.w   #ELEMENT*7,r15          ; output space
            call    #delay                  ; delay
            jmp     loop                    ; repeat

;   beep r15 ticks of the watchdog timer
beep:       mov.w   r15,beep_cnt            ; start beep

beep02:     tst.w   beep_cnt                ; beep finished?
              jne   beep02                  ; n
            ret                             ; y

;   delay r15 ticks of the watchdog timer
delay:      mov.w   r15,delay_cnt           ; start delay

delay02:    tst.w   delay_cnt               ; delay done?
              jne   delay02                 ; n
            ret                             ; y

;   Watchdog Timer interrupt service routine
WDT_ISR:    tst.w   beep_cnt                ; beep on?
              jeq   WDT_02                  ; n
            dec.w   beep_cnt                ; y, decrement count
            xor.b   #0x20,&P4OUT            ; beep using 50% PWM

WDT_02:     tst.w   delay_cnt               ; delay?
              jeq   WDT_10                  ; n
            dec.w   delay_cnt               ; y, decrement count

WDT_10:     reti                            ; return from interrupt

;           Interrupt Vectors
            .sect   ".int10"                ; Watchdog Vector
            .word   WDT_ISR                 ; Watchdog ISR

            .sect   ".reset"                ; PUC Vector
            .word   RESET                   ; RESET ISR
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1 Answer 1

Not sure I understand the question correctly, but yes, interrupts of course interrupt the normal program flow, hence the name. When a particular interrupt is triggered, the processor saves the current PC and SR on the stack so it can later return to whatever it was doing. Then it fetches a vector from a predefined address and continues execution there. Your code has the vector table at the end, containing an entry that specifies you want WDT_ISR invoked for watchdog interrupts. That routine increments the counters then ends with an IRET instruction, so the processor reloads the saved PC and SR and continues execution of the main program.

As for the interval, the initialization code sets that up to occur every 500 microseconds, then the beep/delay just waits for the appopriate number of interrupts to happen.

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