SPRUII0F May 2019 – June 2024 TMS320F28384D , TMS320F28384D-Q1 , TMS320F28384S , TMS320F28384S-Q1 , TMS320F28386D , TMS320F28386D-Q1 , TMS320F28386S , TMS320F28386S-Q1 , TMS320F28388D , TMS320F28388S
Load MAR1 with 16-bit Value
MARx | CLA auxiliary register MAR0 or MAR1 |
mem16 | 16-bit destination memory accessed using one of the available addressing modes |
LSW: mmmm mmmm mmmm mmmm (Opcode for MMOV16 MAR0, mem16)
MSW: 0111 0110 0000 addr
LSW: mmmm mmmm mmmm mmmm (Opcode for MMOV16 MAR1, mem16)
MSW: 0111 0110 0100 addr
Load MAR0 or MAR1 with the 16-bit value pointed to by mem16. Refer to the Pipeline section for important information regarding this instruction.
MAR1 = [mem16];
No flags MSTF flags are affected.
Flag | TF | ZF | NF | LUF | LVF |
---|---|---|---|---|---|
Modified | No | No | No | No | No |
This is a single-cycle instruction. The load of MAR0 or MAR1 occurs in the EXE phase of the pipeline. Any post increment of MAR0 or MAR1 using indirect addressing occurs in the D2 phase of the pipeline. Therefore, the following applies when loading the auxiliary registers:
The two instructions following MMOV16 use MAR0 or MAR1 before the update occurs. Thus, these two instructions use the old value of MAR0 or MAR1.
Loading of an auxiliary register occurs in the EXE phase while updates due to post-increment addressing occur in the D2 phase. Thus, I3 cannot use the auxiliary register or there is a conflict. In the case of a conflict, the update due to address-mode post increment, the auxiliary register is not updated with #_X.
Starting with the 4th instruction, MAR0 or MAR1 is the new value loaded with MMOV16.
; Assume MAR0 is 50 and @_X is 20
MMOV16 MAR0, @_X ; Load MAR0 with the contents of X (20)
<Instruction 1> ; I1 Uses the old value of MAR0 (50)
<Instruction 2> ; I2 Uses the old value of MAR0 (50)
<Instruction 3> ; I3 Cannot use MAR0
<Instruction 4> ; I4 Uses the new value of MAR0 (20)
<Instruction 5> ; I5
....
Instruction | F1 | F2 | D1 | D2 | R1 | R2 | E | W |
---|---|---|---|---|---|---|---|---|
MMOV16 MAR0, @_X | MMOV16 | |||||||
I1 | I1 | MMOV16 | ||||||
I2 | I2 | I1 | MMOV16 | |||||
I3 | I3 | I2 | I1 | MMOV16 | ||||
I4 | I4 | I3 | I2 | I1 | MMOV16 | |||
I5 | I5 | I4 | I3 | I2 | I1 | MMOV16 | ||
I6 | I6 | I5 | I4 | I3 | I2 | I1 | MMOV16 |
; This task logs the last NUM_DATA_POINTS
; ADCRESULT1 values in the array VoltageCLA
;
; When the last element in the array has been
; filled, the task goes back to the
; the first element.
;
; Before starting the ADC conversions, force
; Task 8 to initialize the ConversionCount to zero
;
; The ADC is set to sample (acquire) for 15 SYSCLK cycles
; or 75ns. After the capacitor has captured the analog
; value, the ADC triggers this task early.
; It takes 10.5 ADCCLKs to complete a conversion,
; the ADCCLK being SYSCLK/4
; T_sys = 1/200MHz = 5ns
; T_adc = 4*T_sys = 20ns
; The ADC takes 10.5 * 4 or 42 SYSCLK cycles to complete
; a conversion. The ADC result register can be read on the
; 36th instruction after the task begins.
;
_Cla1Task2:
.asg 0, N
.loop
MNOP
;I1 - I28 Wait till I36 to read result
.eval N + 1, N
.break N = 28
.endloop
MMOVZ16 MR0, @_ConversionCount ;I29 Current Conversion
MMOV16 MAR1, MR0, #_VoltageCLA ;I30 Next array location
MUI16TOF32 MR0, MR0 ;I31 Convert count to float32
MADDF32 MR0, MR0, #1.0 ;I32 Add 1 to conversion count
MCMPF32 MR0, #NUM_DATA_POINTS.0 ;I33 Compare count to max
MF32TOUI16 MR0, MR0 ;I34 Convert count to Uint16
MNOP ;I35 Wait until I36 to read result
MMOVZ16 MR2, @_AdcaResultRegs.ADCRESULT1 ;I36 Read ADCRESULT1
MMOV16 *MAR1, MR2 ; Store ADCRESULT1
MBCNDD _RestartCount, GEQ ; If count >= NUM_DATA_POINTS
MMOVIZ MR1, #0.0 ; Always executed: MR1=0
MNOP
MNOP
MMOV16 @_ConversionCount, MR0 ; If branch not taken
MSTOP ; store current count
_RestartCount
MMOV16 @_ConversionCount, MR1 ; If branch taken, restart count
MSTOP ; end of task
; This task initializes the ConversionCount
; to zero
;
_Cla1Task8:
MMOVIZ MR0, #0.0
MMOV16 @_ConversionCount, MR0
MSTOP
_ClaT8End: