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ME 4447/6405

ME 4447/6405. Microprocessor Control of Manufacturing Systems and Introduction to Mechatronics Instructor: Professor Charles Ume Lecture #11. Homework Set #1 Solution. 1. Write an assembly language program to clear the usable internal RAM in the MC9S12C32 [$0800 to $0DFF]

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ME 4447/6405

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  1. ME 4447/6405 Microprocessor Control of Manufacturing Systems and Introduction to Mechatronics Instructor: Professor Charles Ume Lecture #11

  2. Homework Set #1 Solution 1. Write an assembly language program to clear the usable internal RAM in the MC9S12C32 [$0800 to $0DFF] Solution: Clear Locations $0800 - $0DFF. ORG $1000 LDX #$0800 LOOP CLR $00,X INX CPX #$0E00 BNE LOOP SWI END (NOTE: You should hand-assemble this program.)

  3. Homework Set #1 Solution 2. Write a program to add even/odd numbers located in addresses $0000 through $00FE. Solution: (for adding odd numbers) ORG $1000 LDY #$0000 1000 CD 0000 LDX #$0000 1003 CE 0000 IND LDAA #$FF 1006 86 FF LDAB $00,X 1008 E6 00 BITB #$01 100A C5 01 BEQ EVEN 100C 27 02 ABY 100E 19 ED EVEN INX 1010 08 STX $2000 1011 7E 2000 EORA $2001 1014 B8 2001 BNE IND 1017 26 ED SWI 1019 3F END 0000 0011 0000 0001 0000 0001 OR DECA 4A If you use this, then IND should be moved down to the next line 1st Time $2001: 0000 0001 Acc A: 1111 1111 1111 1110

  4. 2. Write a program to add even/odd numbers located in addresses $0800 through $0900. Solution: (for adding odd numbers) ORG $1000 LDY #$0000 1000 CD 0000 LDX #$0800 1003 CE 0800 IND LDAB $00,X 1006 E6 00 BITB #$01 1008 C5 01 BEQ EVEN 100A 27 02 ABY 100C 19 ED EVEN INX 100E 08 CPX #$0901 100F 8E 0901 BNE IND 1012 26 ED SWI 1014 3F END Homework Set #1 Solution

  5. Homework Set #2 Solution Write an assembly language program to find the largest signed number in a list of numbers stored in address $0020 thru $0029, and store it in $2000. Repeat for unsigned number. FIRST EQU $0020 LAST EQU $002A ANSWR EQU $2000 ORG $1000 LDX #FIRST LDAA FIRST STAA ANSWR INX Goes with DECB. If DECB is removed, then LDAB #$0A LDAB must be removed NUB LDAA $00,X CMPA ANSWR (A - ANSWR) BLE NEXT; (signed)* *(Branches if 2's complement number in register A is less than or OR equal to the 2's complement number represented by ANSWR)BLS NEXT; (unsigned)** **(Branch if lower or same, i.e, Branch if register A was lower or same as ANSWR) STAA ANSWR NEXT INX CPX #LASTORDECB BNE NUB SWI END

  6. Homework Set #2 Solution Continued Signed Example: #$3F (positive) #$F4 (negative) Convert Numbers to Decimal: #$F4 = %11110100 1's Comp #$0B = %00001011 2's Comp #$0C = %00001100 #$F4 = -1210 #$3F = %00111111 #$3F = 6310 #$3F is larger than #$F4 since 6310 is larger than -1210 Un-Signed Example: #$3F (positive) #$F4 (positive) Convert Numbers to Decimal: #$F4 = %11110100 #$F4 = 24410 #$3F = %00111111 #$3F = 6310 #$F4 is larger than #$3F since 24410 is larger than 6310

  7. Homework Set #3 Solution 1. Write a subroutine to save the first 5 odd (8-bit) numbers pointed to by the x-register (passed in) onto the stack. Solution: SUB1 LDAA #$05 PULY NEXT BRSET $00,X #$01 ODD INX BRA NEXT ODD LDAB $00,X PSHB INX DECA BNE NEXT PSHY RTS Note: For subroutine to execute in main program, a BSR or JSR command must be used in main program.

  8. Homework Set #3 solution 2. Write a program to output a square wave thru port S pin The output can be observed on the scope, and the period T of the wave should be measured. More than one period wave should be generated. The machine cycle time of the MC9S12C32 should be estimated. Draw the square wave.

  9. Homework Solution Cont’d Solution: ORG $2000 FCB $XX FCB $04 ORG $1000 LDAA #$04 STAA $024A LDAB #$04 CYCLE LDAA $2001 3 STAA $0248 3 EORA #$04 1 STAA $2001 3 LDAA $2000 3 NEXT DECA 1 BNE NEXT 3/1 DECB 1 BEQ EXIT 3/1 JMP CYCLE 3 EXIT SWI END Address Opcode Postbyte Operand 1000 86 04 1002 7A 024A 1005 C6 04 1007 B6 2001 100A 7A 0248 100D 88 04 100F 7A 2001 1012 B6 2000 1015 43 1016 26 FD 1018 53 1019 27 03 101B 06 1007 101E 3F Configures PS2 as output. Helps us to output two periods. Outputs signal from PS2 Switch $2001(toggle) Delay (Note: BNE and BEQ take 3 machine cycles to execute if the branch is taken and one machine cycle if it is not taken) T/2=Machine Cycle Time*[3+3+1+3+3+COUNT*(1)+(COUNT-1)*3+1+1+3] (Note: Count = #$XX)

  10. ASCII Character Codes

  11. ASCII – American Standard Code for Information Interchange ASCII assigns a hexadecimal ‘code’ to individual characters Examples: Character ASCII ‘A $41 ‘E $45 ‘e $65 (Note: Different codes for lower and upper case) ‘1 $31 BS $08 (Note: BS is Backspace. ) A microcontroller must send these codes to a display terminal in order for the terminal to display these characters. ASCII Character Codes

  12. ASCII Character Codes (continued) • Hex to ASCII Conversion table from Programming Reference Guide Page 58

  13. An array of characters is called a string Example: character array String ASCII Representation ‘H ‘e ‘l ‘l ‘o “Hello” $48 $65 $6C $6C $6F ASCII Character Codes (Note: Character ASCII ‘H $48 ‘e $65 ‘l $6C ‘o $6F )

  14. Assembly Directives

  15. Assembly Control ORG, END Symbol Definition EQU Data Definition/Storage Allocation FCC, FCB, FDB, RMB, ZMB, BSZ, FILL Listing Control PAGE, OPT Assembly Directive Types

  16. Assembly Control

  17. ORG : Store translated machine language instructions in sequence starting at given address for any mnemonic instructions that follow END: Stop translating mnemonics instructions until another ORG is encountered (Note: These were already discussed in Lecture 7) ORG and END

  18. Symbol Definition

  19. EQU EQU lets you refer to a number or an address as a variable name. Example: VALA EQU $10 *LABEL VALA USED TO REFER TO $10 ORG $1000 LDAA #VALA *LOAD HEX NUMBER $10 IN ACCUMULATOR A LDAB VALA *LOAD CONTENT OF MEMORY LOCATION $10 *IN ACC. B SWI END Same As: VALA EQU $10 *LABEL VALA USED TO REFER TO $10 ORG $1000 LDAA #$10 *LOAD HEX NUMBER $10 IN ACCUMULATOR A LDAB $10 *LOAD CONTENT OF MEMORY *LOCATION $10 IN ACC. B SWI END

  20. Data Definition/Storage Allocation

  21. FCC FCC – Form Constant Character string FCC stores ASCII characters into consecutive bytes of memory. Any printable ASCII characters can be contained in the string. String is specified between two identical delimiters, which can be any printable ASCII character. First non-blank character after the string is used as a delimiter.

  22. FCC Cont’d Result Operand Prebyte Opcode Example: ORG $0400 FCC “12345” Address 31 $0400 32 $0401 33 $0402 34 $0403 35 $0404

  23. FCB FCB – Form Constant Byte FCB has one or more operands. Value of each operand is truncated to eight bits, and is stored in single byte of object program. Operand may be a numeric constant, character constant, a symbol or an expression. Multiple operands are separated by commas, and are stored in successive memory bytes.

  24. FCB Cont’d Example: VALA EQU $10 ORG $0400 FCB $34,’A, $28AC, $0A ,VALA Result Operand Prebyte Opcode Address 34 $0400 41 $0401 AC $0402 0A $0403 $0404 10

  25. FDB FDB – Form Constant Double Byte FDB stores a double (two byte) word. May have one or more operands separated by commas. Operand may be a numeric constant, a character constant, a symbol, or an expression.

  26. FDB Cont’d Example: ORG $0400 FDB $1234,’&,’G Result Operand Prebyte Opcode Address 12 $0400 34 $0401 00 $0402 26 $0403 00 $0404 47 $0405 Note: ASCII value for & is $26 ASCII value for G is $47

  27. RMB RMB – Reserve Memory Byte RMB saves a place in memory for a number. Example: ORG $0400 XVAR RMB 2 *TWO MEMORY *LOCATIONS $0400 *and $0401 ARE *RESERVED FOR XVAR ORG $1000 LDD #$FFAA STD XVAR SWI END Result Prebyte Opcode Operand Address FF $0400 AA $0401

  28. Question a student asked: What happens if you change the previous example to "XVAR RMB 3" instead of "XVAR RMB 2" ? What happens to the 3rd reserved byte when a 2 byte number is stored in XVAR? Answer: Remains unchanged Modified Program: ORG $0400 XVAR RMB 3 ORG $1000 LDD #$FFAA STD XVAR SWI END

  29. ZMB, BSZ ZMB – Zero Memory Byte and BSZ – Block Storage of Zero These directives fill a given number of memory locations with zero. Causes assembler to allocate a block of memory bytes, and each memory byte is assigned a value of zero. Both directives do the same thing. Number of bytes allocated is given in the operand field. Result Example: ORG $0400 ZMB #$02 BSZ #$02 Prebyte Opcode Operand Address 00 $00 $01 00 00 $02 $03 00

  30. FILL Fill given number of memory locations with any number. (Note: Fill uses one byte. If two bytes are specified, then it will truncate it and use LS Byte.) Example: ORG $0400 FILL #$FF, #$02 Result Prebyte Opcode Operand Address $00 FF FF $01

  31. Question a student asked: What happens when the previous example is changed to "FILL #$9ABC, #$02" instead of "FILL #$FF,#$02"? What happens if you fill memory with a 2 byte number? Answer: FILL will just use the LS Byte Modified Example: ORG $0400 FILL #$9ABC,#$02 END (Note: There is no ”go 1000” on the screen since these are just assembly directives and not a program)

  32. Listing Control

  33. PAGE PAGE The PAGE directive causes a page break in the list file. If no source listing is being produced, the PAGE directive will have no effect. The directive is not printed on the source listing.

  34. OPT OPT Allows for various options in assembly of a program, including generating a listing and counting instruction cycles. Options: nol-no output listing (default) l-do an output listing noc-no cycle number count (default) c-turn on cycle count using zero initial value contc-turn cycle count on, begin with last value cre-create a cross reference table (default anyway) RMB s-create a symbol table (default anyway) EQU Example: OPT l – Print source listing from this point

  35. Homework 3 Solution Write a subroutine to save the first 5 odd (8-bit) numbers pointed to by the x-register (passed in) onto the stack. Solution: SUB1 LDAA #$05 PULY NEXT BRSET $00,X #$01 ODD INX BRA NEXT ODD LDAB $00,X PSHB INX DECA BNE NEXT PSHY RTS Note: For subroutine to execute in main program, a BSR or JSR command must be used in main program.

  36. Homework 4 solution Write a program to output a square wave thru port S pin 2. The output can be observed on the scope, and the period T of the wave should be measured. More than one period wave should be generated. The machine cycle time of the MC9S12C32 should be estimated. Draw the square wave.

  37. Homework 4 Solution Cont’d Solution: ORG $2000 FCB $XX FCB $04 ORG $1000 LDAA #$04 STAA $024A LDAB #$04 CYCLE LDAA $2001 3 STAA $0248 3 EORA #$04 1 STAA $2001 3 LDAA $2000 3 NEXT DECA 1 BNE NEXT 3/1 DECB 1 BEQ EXIT 3/1 JMP CYCLE 3 EXIT SWI END Address Opcode Postbyte Operand 1000 86 04 1002 7A 024A 1005 C6 04 1007 B6 2001 100A 7A 0248 100D 88 04 100F 7A 2001 1012 B6 2000 1015 43 1016 26 FD 1018 53 1019 27 03 101B 06 1007 101E 3F Configures PS2 as output. Helps us to output two periods. Outputs signal from PS2 Switch $2001(toggle) Delay (Note: BNE and BEQ take 3 machine cycles to execute if the branch is taken and one machine cycle if it is not taken) T/2=Machine Cycle Time*[3+3+1+3+3+COUNT*(1)+(COUNT-1)*3+1+1+3] (Note: Count = #$XX)

  38. QUESTIONS???

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