From 7f59fd16534fc4fe417640130c415107008a638c Mon Sep 17 00:00:00 2001 From: Aleksey Veresov Date: Tue, 16 Feb 2021 13:11:37 +0300 Subject: Now Machine is in Emulator which is a monad. =) --- spec/MC68000UM.txt | 10789 ++++++++++++++++++++++++++ spec/opcodes.svg | 20838 +++++++++++++++++++++++++++++++++++++++++++++++++++ 2 files changed, 31627 insertions(+) create mode 100644 spec/MC68000UM.txt create mode 100644 spec/opcodes.svg (limited to 'spec') diff --git a/spec/MC68000UM.txt b/spec/MC68000UM.txt new file mode 100644 index 0000000..f1f479a --- /dev/null +++ b/spec/MC68000UM.txt @@ -0,0 +1,10789 @@ + Freescale Semiconductor, Inc. + + + + + µ MOTOROLA + + M68000 + 8-/16-/32-Bit + Microprocessors User’s Manual +Freescale Semiconductor, Inc... + + + + + Ninth Edition + + + + + Motorola reserves the right to make changes without further notice to any products herein. Motorola makes no warranty, representation or guarantee regarding + the suitability of its products for any particular purpose, nor does Motorola assume any liability arising out of the application or use of any product or circuit, and + specifically disclaims any and all liability, including without limitation consequential or incidental damages. "Typical" parameters can and do vary in different + applications. All operating parameters, including "Typicals" must be validated for each customer application by customer's technical experts. Motorola does not + convey any license under its patent rights nor the rights of others. Motorola products are not designed, intended, or authorized for use as components in systems + intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the Motorola + product could create a situation where personal injury or death may occur. Should Buyer purchase or use Motorola products for any such unintended or + unauthorized application, Buyer shall indemnify and hold Motorola and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, + costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such + unintended or unauthorized use, even if such claim alleges that Motorola was negligent regarding the design or manufacture of the part. Motorola and µ are + registered trademarks of Motorola, Inc. Motorola, Inc. is an Equal Opportunity/Affirmative Action Employer. + + + ©MOTOROLA INC., 1993 + + + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + + + + TABLE OF CONTENTS + Paragraph Page + Number Title Number + + Section 1 + Overview + 1.1 MC68000..................................................................................................... 1-1 +Freescale Semiconductor, Inc... + + + + + 1.2 MC68008..................................................................................................... 1-2 + 1.3 MC68010..................................................................................................... 1-2 + 1.4 MC68HC000................................................................................................ 1-2 + 1.5 MC68HC001................................................................................................ 1-3 + 1.6 MC68EC000 ................................................................................................ 1-3 + + Section 2 + Introduction + 2.1 Programmer's Model ................................................................................... 2-1 + 2.1.1 User's Programmer's Model .................................................................... 2-1 + 2.1.2 Supervisor Programmer's Model ............................................................. 2-2 + 2.1.3 Status Register ........................................................................................ 2-3 + 2.2 Data Types and Addressing Modes ............................................................ 2-3 + 2.3 Data Organization In Registers ................................................................... 2-5 + 2.3.1 Data Registers ......................................................................................... 2-5 + 2.3.2 Address Registers ................................................................................... 2-6 + 2.4 Data Organization In Memory ..................................................................... 2-6 + 2.5 Instruction Set Summary ............................................................................. 2-8 + + Section 3 + Signal Description + 3.1 Address Bus ................................................................................................ 3-3 + 3.2 Data Bus...................................................................................................... 3-4 + 3.3 Asynchronous Bus Control.......................................................................... 3-4 + 3.4 Bus Arbitration Control ................................................................................ 3-5 + 3.5 Interrupt Control .......................................................................................... 3-6 + 3.6 System Control............................................................................................ 3-7 + 3.7 M6800 Peripheral Control ........................................................................... 3-8 + 3.8 Processor Function Codes .......................................................................... 3-8 + 3.9 Clock ........................................................................................................... 3-9 + 3.10 Power Supply .............................................................................................. 3-9 + 3.11 Signal Summary ......................................................................................... 3-10 + + + MOTOROLA M68000 USER’S MANUAL vii + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + TABLE OF CONTENTS (Continued) + Paragraph Page + Number Title Number + + Section 4 + 8-Bit Bus Operations + 4.1 Data Transfer Operations............................................................................. 4-1 + 4.1.1 Read Operations ...................................................................................... 4-1 + 4.1.2 Write Cycle ............................................................................................... 4-3 + 4.1.3 Read-Modify-Write Cycle.......................................................................... 4-5 + 4.2 Other Bus Operations............................................................................... 4-8 + + Section 5 +Freescale Semiconductor, Inc... + + + + + 16-Bit Bus Operations + 5.1 Data Transfer Operations............................................................................ 5-1 + 5.1.1 Read Operations ..................................................................................... 5-1 + 5.1.2 Write Cycle .............................................................................................. 5-4 + 5.1.3 Read-Modify-Write Cycle......................................................................... 5-7 + 5.1.4 CPU Space Cycle.................................................................................... 5-9 + 5.2 Bus Arbitration .......................................................................................... 5-11 + 5.2.1 Requesting The Bus .............................................................................. 5-14 + 5.2.2 Receiving The Bus Grant ...................................................................... 5-15 + 5.2.3 Acknowledgment of Mastership (3-Wire Arbitration Only)..................... 5-15 + 5.3 Bus Arbitration Control .............................................................................. 5-15 + 5.4 Bus Error and Halt Operation .................................................................... 5-23 + 5.4.1 Bus Error Operation .............................................................................. 5-24 + 5.4.2 Retrying The Bus Cycle......................................................................... 5-26 + 5.4.3 Halt Operation ....................................................................................... 5-27 + 5.4.4 Double Bus Fault ................................................................................... 5-28 + 5.5 Reset Operation ........................................................................................ 5-29 + 5.6 The Relationship of DTACK, BERR, and HALT ......................................... 5-30 + 5.7 Asynchronous Operation .......................................................................... 5-32 + 5.8 Synchronous Operation ............................................................................ 5-35 + + Section 6 + Exception Processing + 6.1 Privilege Modes............................................................................................ 6-1 + 6.1.1 Supervisor Mode ...................................................................................... 6-2 + 6.1.2 User Mode ................................................................................................ 6-2 + 6.1.3 Privilege Mode Changes .......................................................................... 6-2 + 6.1.4 Reference Classification........................................................................... 6-3 + 6.2 Exception Processing................................................................................... 6-4 + 6.2.1 Exception Vectors .................................................................................... 6-4 + 6.2.2 Kinds Of Exceptions ................................................................................. 6-5 + 6.2.3 Multiple Exceptions................................................................................... 6-8 + + + viii M68000 USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + TABLE OF CONTENTS (Continued) + Paragraph Page + Number Title Number + + Section 6 + Exception Processing + 6.2.4 Exception Stack Frames.......................................................................... 6-9 + 6.2.5 Exception Processing Sequence ............................................................ 6-11 + 6.3 Processing of Specific Exceptions ............................................................. 6-11 + 6.3.1 Reset ...................................................................................................... 6-11 + 6.3.2 Interrupts ................................................................................................ 6-12 + 6.3.3 Uninitialized Interrupt .............................................................................. 6-13 +Freescale Semiconductor, Inc... + + + + + 6.3.4 Spurious Interrupt ................................................................................... 6-13 + 6.3.5 Instruction Traps ..................................................................................... 6-13 + 6.3.6 Illegal and Unimplemented Instructions .................................................. 6-14 + 6.3.7 Privilege Violations ................................................................................. 6-15 + 6.3.8 Tracing .................................................................................................... 6-15 + 6.3.9 Bus Errors ............................................................................................... 6-16 + 6.3.9.1 Bus Error ............................................................................................. 6-16 + 6.3.9.2 Bus Error (MC68010) .......................................................................... 6-17 + 6.3.10 Address Error ......................................................................................... 6-19 + 6.4 Return From Exception (MC68010) ........................................................... 6-20 + + + Section 7 + 8-Bit Instruction Timing + 7.1 Operand Effective Address Calculation Times............................................ 7-1 + 7.2 Move Instruction Execution Times .............................................................. 7-2 + 7.3 Standard Instruction Execution Times......................................................... 7-3 + 7.4 Immediate Instruction Execution Times ...................................................... 7-4 + 7.5 Single Operand Instruction Execution Times .............................................. 7-5 + 7.6 Shift/Rotate Instruction Execution Times .................................................... 7-6 + 7.7 Bit Manipulation Instruction Execution Times ............................................. 7-7 + 7.8 Conditional Instruction Execution Times ..................................................... 7-7 + 7.9 JMP, JSR, LEA, PEA, and MOVEM Instruction Execution Times............... 7-8 + 7.10 Multiprecision Instruction Execution Times ................................................. 7-8 + 7.11 Miscellaneous Instruction Execution Times ................................................ 7-9 + 7.12 Exception Processing Instruction Execution Times ................................... 7-10 + + + + + MOTOROLA M68000 USER’S MANUAL ix + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + TABLE OF CONTENTS (Continued) + Paragraph Page + Number Title Number + + Section 8 + 16-Bit Instruction Timing + 8.1 Operand Effective Address Calculation Times ........................................... 8-1 + 8.2 Move Instruction Execution Times .............................................................. 8-2 + 8.3 Standard Instruction Execution Times ........................................................ 8-3 + 8.4 Immediate Instruction Execution Times ...................................................... 8-4 + 8.5 Single Operand Instruction Execution Times .............................................. 8-5 + 8.6 Shift/Rotate Instruction Execution Times .................................................... 8-6 +Freescale Semiconductor, Inc... + + + + + 8.7 Bit Manipulation Instruction Execution Times ............................................. 8-7 + 8.8 Conditional Instruction Execution Times ..................................................... 8-7 + 8.9 JMP, JSR, LEA, PEA, and MOVEM Instruction Execution Times .............. 8-8 + 8.10 Multiprecision Instruction Execution Times ................................................. 8-8 + 8.11 Miscellaneous Instruction Execution Times ................................................ 8-9 + 8.12 Exception Processing Instruction Execution Times .................................. 8-10 + + + Section 9 + MC68010 Instruction Timing + 9.1 Operand Effective Address Calculation Times ........................................... 9-2 + 9.2 Move Instruction Execution Times .............................................................. 9-2 + 9.3 Standard Instruction Execution Times ........................................................ 9-4 + 9.4 Immediate Instruction Execution Times ...................................................... 9-6 + 9.5 Single Operand Instruction Execution Times .............................................. 9-6 + 9.6 Shift/Rotate Instruction Execution Times .................................................... 9-8 + 9.7 Bit Manipulation Instruction Execution Times ............................................. 9-9 + 9.8 Conditional Instruction Execution Times ..................................................... 9-9 + 9.9 JMP, JSR, LEA, PEA, and MOVEM Instruction Execution Times ............ 9-10 + 9.10 Multiprecision Instruction Execution Times ............................................... 9-11 + 9.11 Miscellaneous Instruction Execution Times .............................................. 9-11 + 9.12 Exception Processing Instruction Execution Times .................................. 9-13 + + + Section 10 + Electrical and Thermal Characteristics + 10.1 Maximum Ratings ..................................................................................... 10-1 + 10.2 Thermal Characteristics ............................................................................ 10-1 + 10.3 Power Considerations ............................................................................... 10-2 + 10.4 CMOS Considerations .............................................................................. 10-4 + 10.5 AC Electrical Specifications Definitions..................................................... 10-5 + 10.6 MC68000/68008/68010 DC Electrical Characteristics .............................. 10-7 + 10.7 DC Electrical Characteristics .................................................................... 10-8 + 10.8 AC Electrical Specifications—Clock Timing .............................................. 10-8 + + x M68000 USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + TABLE OF CONTENTS (Continued) + Paragraph Page + Number Title Number + + Section 10 + Electrical and Thermal Characteristics + 10.9 MC68008 AC Electrical Specifications—Clock Timing ............................. 10-9 + 10.10 AC Electrical Specifications—Read and Write Cycles ............................ 10-10 + 10.11 AC Electrical Specifications—MC68000 To M6800 Peripheral............... 10-15 + 10.12 AC Electrical Specifications—Bus Arbitration .........................................10-17 + 10.13 MC68EC000 DC Electrical Spec ifications.............................................. 10-23 + 10.14 MC68EC000 AC Electrical Specifications—Read and Write .................. 10-24 +Freescale Semiconductor, Inc... + + + + + 10.15 MC68EC000 AC Electrical Specifications—Bus Arbitration .................... 10-28 + + + Section 11 + Ordering Information and Mechanical Data + 11.1 Pin Assignments........................................................................................ 11-1 + 11.2 Package Dimensions ................................................................................ 11-7 + + + Appendix A + MC68010 Loop Mode Operation + + + Appendix B + M6800 Peripheral Interface + B.1 Data Transfer Operation............................................................................. B-1 + B.2 Interrupt Interface Operation ...................................................................... B-4 + + + + + MOTOROLA M68000 USER’S MANUAL xi + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + + + + LIST OF ILLUSTRATIONS + Figure Page + Number Title Number + + 2-1 User Programmer's Model ................................................................................... 2-2 + 2-2 Supervisor Programmer's Model Supplement ..................................................... 2-2 + 2-3 Supervisor Programmer's Model Supplement (MC68010) .................................. 2-3 + 2-4 Status Register .................................................................................................... 2-3 +Freescale Semiconductor, Inc... + + + + + 2-5 Word Organization In Memory ............................................................................. 2-6 + 2-6 Data Organization In Memory .............................................................................. 2-7 + 2-7 Memory Data Organization (MC68008) ............................................................... 2-3 + + 3-1 Input and Output Signals (MC68000, MC68HC000, MC68010) .......................... 3-1 + 3-2 Input and Output Signals ( MC68HC001) ............................................................ 3-2 + 3-3 Input and Output Signals (MC68EC000) ............................................................. 3-2 + 3-4 Input and Output Signals (MC68008 48-Pin Version) .......................................... 3-3 + 3-5 Input and Output Signals (MC68008 52-Pin Version) .......................................... 3-3 + + 4-1 Byte Read-Cycle Flowchart.................................................................................. 4-2 + 4-2 Read and Write-Cycle Timing Diagram................................................................ 4-2 + 4-3 Byte Write-Cycle Flowchart .................................................................................. 4-4 + 4-4 Write-Cycle Timing Diagram ................................................................................ 4-4 + 4-5 Read-Modify-Write Cycle Flowchart .................................................................... 4-6 + 4-6 Read-Modify-Write Cycle Timing Diagram........................................................... 4-7 + + 5-1 Word Read-Cycle Flowchart ................................................................................ 5-2 + 5-2 Byte Read-Cycle Flowchart.................................................................................. 5-2 + 5-3 Read and Write-Cycle Timing Diagram................................................................ 5-3 + 5-4 Word and Byte Read-Cycle Timing Diagram ....................................................... 5-3 + 5-5 Word Write-Cycle Flowchart ................................................................................ 5-5 + 5-6 Byte Write-Cycle Flowchart .................................................................................. 5-5 + 5-7 Word and Byte Write-Cycle Timing Diagram ....................................................... 5-6 + 5-8 Read-Modify-Write Cycle Flowchart .................................................................... 5-7 + 5-9 Read-Modify-Write Cycle Timing Diagram........................................................... 5-8 + 5-10 CPU Space Address Encoding ............................................................................ 5-9 + 5-11 Interrupt Acknowledge Cycle Timing Diagram ................................................... 5-10 + 5-12 Breakpoint Acknowledge Cycle Timing Diagram ............................................... 5-11 + 5-13 3-Wire Bus Arbitration Flowchart + (NA to 48-Pin MC68008 and MC68EC000 ........................................................ 5-12 + 5-14 2-Wire Bus Arbitration Cycle Flowchart ............................................................. 5-13 + + + + xii M68000 USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + LIST OF ILLUSTRATIONS (Continued) + Figure Page + Number Title Number + + 5-15 3-Wire Bus Arbitration Timing Diagram + (NA to 48-Pin MC68008 and MC68EC000 ........................................................ 5-13 + 5-16 2-Wire Bus Arbitration Timing Diagram.............................................................. 5-14 + 5-17 External Asynchronous Signal Synchronization ................................................. 5-16 + 5-18 Bus Arbitration Unit State Diagrams................................................................... 5-17 + 5-19 3-Wire Bus Arbitration Timing Diagram—Processor Active ...............................5-18 + 5-20 3-Wire Bus Arbitration Timing Diagram—Bus Active ......................................... 5-19 + 5-21 3-Wire Bus Arbitration Timing Diagram—Special Case ................................ ..... 5-20 + 5-22 2-Wire Bus Arbitration Timing Diagram—Processor Active ...............................5-21 +Freescale Semiconductor, Inc... + + + + + 5-23 2-Wire Bus Arbitration Timing Diagram—Bus Active ......................................... 5-22 + 5-24 2-Wire Bus Arbitration Timing Diagram—Special Case ................................ ..... 5-23 + 5-25 Bus Error Timing Diagram ..................................................................................5-24 + 5-26 Delayed Bus Error Timing Diagram (MC68010)................................................. 5-25 + 5-27 Retry Bus Cycle Timing Diagram ....................................................................... 5-26 + 5-28 Delayed Retry Bus Cycle Timing Diagram ......................................................... 5-27 + 5-29 Halt Operation Timing Diagram.......................................................................... 5-28 + 5-30 Reset Operation Timing Diagram....................................................................... 5-29 + 5-31 Fully Asynchronous Read Cycle ........................................................................ 5-32 + 5-32 Fully Asynchronous Write Cycle......................................................................... 5-33 + 5-33 Pseudo-Asynchronous Read Cycle ................................................................... 5-34 + 5-34 Pseudo-Asynchronous Write Cycle.................................................................... 5-35 + 5-35 Synchronous Read Cycle................................................................................... 5-37 + 5-36 Synchronous Write Cycle ................................................................................... 5-38 + 5-37 Input Synchronizers ........................................................................................... 5-38 + + 6-1 Exception Vector Format...................................................................................... 6-4 + 6-2 Peripheral Vector Number Format ....................................................................... 6-5 + 6-3 Address Translated from 8-Bit Vector Number ................................................... 6-5 + 6-4 Exception Vector Address Calculation (MC68010) .............................................. 6-5 + 6-5 Group 1 and 2 Exception Stack Frame .............................................................. 6-10 + 6-6 MC68010 Stack Frame ...................................................................................... 6-10 + 6-7 Supervisor Stack Order for Bus or Address Error Exception ............................. 6-17 + 6-8 Exception Stack Order (Bus and Address Error) ............................................... 6-18 + 6-9 Special Status Word Format .............................................................................. 6-19 + + 10-1 MC68000 Power Dissipation (P D) vs Ambient Temperature (TA) ..................... 10-3 + 10-2 Drive Levels and Test Points for AC Specifications ........................................... 10-6 + 10-3 Clock Input Timing Diagram ............................................................................... 10-9 + 10-4 Read Cycle Timing Diagram ............................................................................ 10-13 + 10-5 Write Cycle Timing Diagram............................................................................. 10-14 + 10-6 MC68000 to M6800 Peripheral Timing Diagram (Best Case) .......................... 10-16 + + + + MOTOROLA M68000 USER’S MANUAL xiii + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + LIST OF ILLUSTRATIONS (Concluded) + Figure Page + Number Title Number + + 10-7 Bus Arbitration Timing...................................................................................... 10-18 + 10-8 Bus Arbitration Timing...................................................................................... 10-19 + 10-9 Bus Arbitration Timing—Idle Bus Case ............................................................ 10-20 + 10-10 Bus Arbitration Timing—Active Bus Case........................................................ 10-21 + 10-11 Bus Arbitration Timing—Multiple Bus Request ................................................ 10-22 + 10-12 MC68EC000 Read Cycle Timing Diagram ...................................................... 10-26 + 10-13 MC68EC000 Write Cycle Timing Diagram....................................................... 10-27 + 10-14 MC68EC000 Bus Arbitration Timing Diagram ................................................. 10-29 +Freescale Semiconductor, Inc... + + + + + 11-1 64-Pin Dual In Line ............................................................................................ 11-2 + 11-2 68-Lead Pin Grid Array ...................................................................................... 11-3 + 11-3 68-Lead Quad Pack ........................................................................................... 11-4 + 11-4 52-Lead Quad Pack ........................................................................................... 11-5 + 11-5 48-Pin Dual In Line ............................................................................................ 11-6 + 11-6 64-Lead Quad Flat Pack .................................................................................... 11-7 + 11-7 Case 740-03—L Suffix ....................................................................................... 11-8 + 11-8 Case 767-02—P Suffix ...................................................................................... 11-9 + 11-9 Case 746-01—LC Suffix .................................................................................. 11-10 + 11-10 Case — Suffix ...................................................................................................... 11- + 11-11 Case 765A-05—RC Suffix ............................................................................... 11-12 + 11-12 Case 778-02—FN Suffix .................................................................................. 11-13 + 11-13 Case 779-02—FN Suffix .................................................................................. 11-14 + 11-14 Case 847-01—FC Suffix .................................................................................. 11-15 + 11-15 Case 840B-01—FU Suffix................................................................................ 11-16 + + A-1 DBcc Loop Mode Program Example................................................................... A-1 + + B-1 M6800 Data Transfer Flowchart ......................................................................... B-1 + B-2 Example External VMA Circuit ............................................................................ B-2 + B-3 External VMA Timing .......................................................................................... B-2 + B-4 M6800 Peripheral Timing—Best Case................................................................ B-3 + B-5 M6800 Peripheral Timing—Worst Case ............................................................. B-3 + B-6 Autovector Operation Timing Diagram................................................................ B-5 + + + + + xiv M68000 USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + + + + LIST OF TABLES + Table Page + Number Title Number + + 2-1 Data Addressing Modes ....................................................................................... 2-4 + + 2-2 Instruction Set Summary .................................................................................... 2-11 +Freescale Semiconductor, Inc... + + + + + 3-1 Data Strobe Control of Data Bus.......................................................................... 3-5 + 3-2 Data Strobe Control of Data Bus (MC68008)....................................................... 3-5 + 3-3 Function Code Output .......................................................................................... 3-9 + 3-4 Signal Summary ................................................................................................. 3-10 + + 5-1 DTACK, BERR, and HALT Assertion Results ..................................................... 5-31 + + 6-1 Reference Classification....................................................................................... 6-3 + 6-2 Exception Vector Assignment .............................................................................. 6-7 + 6-3 Exception Grouping and Priority........................................................................... 6-9 + 6-4 MC68010 Format Code...................................................................................... 6-11 + + 7-1 Effective Address Calculation Times.................................................................... 7-2 + 7-2 Move Byte Instruction Execution Times ............................................................... 7-2 + 7-3 Move Word Instruction Execution Times.............................................................. 7-3 + 7-4 Move Long Instruction Execution Times .............................................................. 7-3 + 7-5 Standard Instruction Execution Times.................................................................. 7-4 + 7-6 Immediate Instruction Execution Times ............................................................... 7-5 + 7-7 Single Operand Instruction Execution Times ....................................................... 7-6 + 7-8 Shift/Rotate Instruction Execution Times ............................................................. 7-6 + 7-9 Bit Manipulation Instruction Execution Times ...................................................... 7-7 + 7-10 Conditional Instruction Execution Times .............................................................. 7-7 + 7-11 JMP, JSR, LEA, PEA, and MOVEM Instruction Execution Times........................ 7-8 + 7-12 Multiprecision Instruction Execution Times .......................................................... 7-9 + 7-13 Miscellaneous Instruction Execution Times ....................................................... 7-10 + 7-14 Move Peripheral Instruction Execution Times .................................................... 7-10 + 7-15 Exception Processing Instruction Execution Times ........................................... 7-11 + + 8-1 Effective Address Calculation Times.................................................................... 8-2 + 8-2 Move Byte Instruction Execution Times ............................................................... 8-2 + 8-3 Move Word Instruction Execution Times.............................................................. 8-3 + 8-4 Move Long Instruction Execution Times .............................................................. 8-3 + + + + MOTOROLA M68000 USER’S MANUAL xv + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + LIST OF TABLES (Concluded) + Table Page + Number Title Number + + 8-5 Standard Instruction Execution Times ................................................................. 8-4 + 8-6 Immediate Instruction Execution Times ............................................................... 8-5 + 8-7 Single Operand Instruction Execution Times ....................................................... 8-6 + 8-8 Shift/Rotate Instruction Execution Times ............................................................. 8-6 + 8-9 Bit Manipulation Instruction Execution Times ...................................................... 8-7 + 8-10 Conditional Instruction Execution Times .............................................................. 8-7 + 8-11 JMP, JSR, LEA, PEA, and MOVEM Instruction Execution Times ....................... 8-8 + 8-12 Multiprecision Instruction Execution Times .......................................................... 8-9 + 8-13 Miscellaneous Instruction Execution Times ....................................................... 8-10 +Freescale Semiconductor, Inc... + + + + + 8-14 Move Peripheral Instruction Execution Times.................................................... 8-10 + 8-15 Exception Processing Instruction Execution Times ........................................... 8-11 + + 9-1 Effective Address Calculation Times ................................................................... 9-2 + 9-2 Move Byte and Word Instruction Execution Times .............................................. 9-3 + 9-3 Move Byte and Word Instruction Loop Mode Execution Times ........................... 9-3 + 9-4 Move Long Instruction Execution Times .............................................................. 9-4 + 9-5 Move Long Instruction Loop Mode Execution Times ........................................... 9-4 + 9-6 Standard Instruction Execution Times ................................................................. 9-5 + 9-7 Standard Instruction Loop Mode Execution Times .............................................. 9-5 + 9-8 Immediate Instruction Execution Times ............................................................... 9-6 + 9-9 Single Operand Instruction Execution Times ....................................................... 9-7 + 9-10 Clear Instruction Execution Times ....................................................................... 9-7 + 9-11 Single Operand Instruction Loop Mode Execution Times .................................... 9-8 + 9-12 Shift/Rotate Instruction Execution Times ............................................................. 9-8 + 9-13 Shift/Rotate Instruction Loop Mode Execution Times .......................................... 9-9 + 9-14 Bit Manipulation Instruction Execution Times ...................................................... 9-9 + 9-15 Conditional Instruction Execution Times ............................................................ 9-10 + 9-16 JMP, JSR, LEA, PEA, and MOVEM Instruction Execution Times ..................... 9-10 + 9-17 Multiprecision Instruction Execution Times ........................................................ 9-11 + 9-18 Miscellaneous Instruction Execution Times ....................................................... 9-12 + 9-19 Exception Processing Instruction Execution Times ........................................... 9-13 + + 10-1 Power Dissipation and Junction Temperature vs Temperature + (θJC = θJA) ........................................................................................................ 10-4 + 10-2 Power Dissipation and Junction Temperature vs Temperature + (θJC = θJC ) ........................................................................................................ 10-4 + + A-1 MC68010 Loop Mode Instructions ...................................................................... A-3 + + + + + xvi M68000 USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + + + + SECTION 1 + OVERVIEW + This manual includes hardware details and programming information for the MC68000, + the MC68HC000, the MC68HC001, the MC68008, the MC68010, and the MC68EC000. + For ease of reading, the name M68000 MPUs will be used when referring to all + processors. Refer to M68000PM/AD, M68000 Programmer's Reference Manual, for + detailed information on the MC68000 instruction set. +Freescale Semiconductor, Inc... + + + + + The six microprocessors are very similar. They all contain the following features + + • 16 32-Bit Data and Address Registers + • 16-Mbyte Direct Addressing Range + • Program Counter + • 6 Powerful Instruction Types + • Operations on Five Main Data Types + • Memory-Mapped Input/Output (I/O) + • 14 Addressing Modes + The following processors contain additional features: + • MC68010 + —Virtual Memory/Machine Support + —High-Performance Looping Instructions + • MC68HC001/MC68EC000 + —Statically Selectable 8- or 16-Bit Data Bus + • MC68HC000/MC68EC000/MC68HC001 + —Low-Power + All the processors are basically the same with the exception of the MC68008. The + MC68008 differs from the others in that the data bus size is eight bits, and the address + range is smaller. The MC68010 has a few additional instructions and instructions that + operate differently than the corresponding instructions of the other devices. + + + + + MOTOROLA M68000 8-/16-/32-BIT MICROPROCESSORS USER’S MANUAL 1-1 + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + 1.1 MC68000 + The MC68000 is the first implementation of the M68000 16/-32 bit microprocessor + architecture. The MC68000 has a 16-bit data bus and 24-bit address bus while the full + architecture provides for 32-bit address and data buses. It is completely code-compatible + with the MC68008 8-bit data bus implementation of the M68000 and is upward code + compatible with the MC68010 virtual extensions and the MC68020 32-bit implementation + of the architecture. Any user-mode programs using the MC68000 instruction set will run + unchanged on the MC68008, MC68010, MC68020, MC68030, and MC68040. This is + possible because the user programming model is identical for all processors and the + instruction sets are proper subsets of the complete architecture. + + 1.2 MC68008 + The MC68008 is a member of the M68000 family of advanced microprocessors. This +Freescale Semiconductor, Inc... + + + + + device allows the design of cost-effective systems using 8-bit data buses while providing + the benefits of a 32-bit microprocessor architecture. The performance of the MC68008 is + greater than any 8-bit microprocessor and superior to several 16-bit microprocessors. + + The MC68008 is available as a 48-pin dual-in-line package (plastic or ceramic) and 52-pin + plastic leaded chip carrier. The additional four pins of the 52-pin package allow for + additional signals: A20, A21, BGACK, and IPL2. The 48-pin version supports a 20-bit + address that provides a 1-Mbyte address space; the 52-pin version supports a 22-bit + address that extends the address space to 4 Mbytes. The 48-pin MC68008 contains a + simple two-wire arbitration circuit; the 52-pin MC68008 contains a full three-wire MC68000 + bus arbitration control. Both versions are designed to work with daisy-chained networks, + priority encoded networks, or a combination of these techniques. + + A system implementation based on an 8-bit data bus reduces system cost in comparison + to 16-bit systems due to a more effective use of components and byte-wide memories and + peripherals. In addition, the nonmultiplexed address and data buses eliminate the need for + external demultiplexers, further simplifying the system. + + The large nonsegmented linear address space of the MC68008 allows large modular + programs to be developed and executed efficiently. A large linear address space allows + program segment sizes to be determined by the application rather than forcing the + designer to adopt an arbitrary segment size without regard to the application's individual + requirements. + + + 1.3 MC68010 + The MC68010 utilizes VLSI technology and is a fully implemented 16-bit microprocessor + with 32-bit registers, a rich basic instruction set, and versatile addressing modes. The + vector base register (VBR) allows the vector table to be dynamically relocated + + + + + 1-2 M68000 8-/16-/32-BIT MICROPROCESSORS USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + 1.4 MC68HC000 + The primary benefit of the MC68HC000 is reduced power consumption. The device + dissipates an order of magnitude less power than the HMOS MC68000. + + The MC68HC000 is an implementation of the M68000 16/-32 bit microprocessor + architecture. The MC68HC000 has a 16-bit data bus implementation of the MC68000 and + is upward code-compatible with the MC68010 virtual extensions and the MC68020 32-bit + implementation of the architecture. + + + 1.5 MC68HC001 + The MC68HC001 provides a functional extension to the MC68HC000 HCMOS 16-/32-bit + microprocessor with the addition of statically selectable 8- or 16-bit data bus operation. +Freescale Semiconductor, Inc... + + + + + The MC68HC001 is object-code compatible with the MC68HC000, and code written for + the MC68HC001 can be migrated without modification to any member of the M68000 + Family. + + + 1.6 MC68EC000 + The MC68EC000 is an economical high-performance embedded controller designed to + suit the needs of the cost-sensitive embedded controller market. The HCMOS + MC68EC000 has an internal 32-bit architecture that is supported by a statically selectable + 8- or 16-bit data bus. This architecture provides a fast and efficient processing device that + can satisfy the requirements of sophisticated applications based on high-level languages. + + The MC68EC000 is object-code compatible with the MC68000, and code written for the + MC68EC000 can be migrated without modification to any member of the M68000 Family. + The MC68EC000 brings the performance level of the M68000 Family to cost levels + previously associated with 8-bit microprocessors. The MC68EC000 benefits from the rich + M68000 instruction set and its related high code density with low memory bandwidth + requirements. + + + + + MOTOROLA M68000 8-/16-/32-BIT MICROPROCESSORS USER’S MANUAL 1-3 + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + + + + SECTION 2 + INTRODUCTION + The section provide a brief introduction to the M68000 microprocessors (MPUs). + Detailed information on the programming model, data types, addressing modes, data + organization and instruction set can be found in M68000PM/AD, M68000 Programmer's + Reference Manual. All the processors are identical from the programmer's viewpoint, + except that the MC68000 can directly access 16 Mbytes (24-bit address) and the +Freescale Semiconductor, Inc... + + + + + MC68008 can directly access 1 Mbyte (20-bit address on 48-pin version or 22-bit + address on 52-pin version). The MC68010, which also uses a 24-bit address, has much + in common with the other devices; however, it supports additional instructions and + registers and provides full virtual machine/memory capability. Unless noted, all + information pertains to all the M68000 MPUs. + + + 2.1 PROGRAMMER'S MODEL + All the microprocessors executes instructions in one of two modes—user mode or + supervisor mode. The user mode provides the execution environment for the majority of + application programs. The supervisor mode, which allows some additional instructions + and privileges, is used by the operating system and other system software. + + 2.1.1 User' Programmer's Model + The user programmer's model (see Figure 2-1) is common to all M68000 MPUs. The + user programmer's model, contains 16, 32-bit, general-purpose registers (D0–D7, A0– + A7), a 32-bit program counter, and an 8-bit condition code register. The first eight + registers (D0–D7) are used as data registers for byte (8-bit), word (16-bit), and long-word + (32-bit) operations. The second set of seven registers (A0–A6) and the user stack pointer + (USP) can be used as software stack pointers and base address registers. In addition, + the address registers can be used for word and long-word operations. All of the 16 + registers can be used as index registers. + + + + + MOTOROLA M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL 2-1 + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + 31 16 15 8 7 0 + D0 + D1 + D2 + D3 EIGHT + D4 DATA + REGISTERS + D5 + D6 + D7 + + + 31 16 15 0 + A0 + A1 + A2 +Freescale Semiconductor, Inc... + + + + + SEVEN + A3 ADDRESS + A4 REGISTERS + + A5 + A6 + + A7 USER STACK + (USP) POINTER + 31 0 + PC PROGRAM + COUNTER + 7 0 + STATUS + CCR + REGISTER + + + Figure 2-1. User Programmer's Model + (MC68000/MC68HC000/MC68008/MC68010) + + 2.1.2 Supervisor Programmer's Model + The supervisor programmer's model consists of supplementary registers used in the + supervisor mode. The M68000 MPUs contain identical supervisor mode register + resources, which are shown in Figure 2-2, including the status register (high-order byte) + and the supervisor stack pointer (SSP/A7'). + + 31 16 15 0 + A7' SUPERVISOR STACK + (SSP) POINTER + 15 8 7 0 + CCR SR STATUS REGISTER + + + + Figure 2-2. Supervisor Programmer's Model Supplement + + The supervisor programmer's model supplement of the MC68010 is shown in Figure 2- + 3. In addition to the supervisor stack pointer and status register, it includes the vector + base register (VRB) and the alternate function code registers (AFC).The VBR is used to + determine the location of the exception vector table in memory to support multiple vector + + + 2-2 M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + tables. The SFC and DFC registers allow the supervisor to access user data space or + emulate CPU space cycles. + + 31 16 15 0 + A7' SUPERVISOR STACK + (SSP) POINTER + 15 8 7 0 + CCR SR STATUS REGISTER + 31 0 + VBR VECTOR BASE REGISTER + 2 0 + SFC ALTERNATE FUNCTION + DFC CODE REGISTERS +Freescale Semiconductor, Inc... + + + + + Figure 2-3. Supervisor Programmer's Model Supplement + (MC68010) + + 2.1.3 Status Register + The status register (SR),contains the interrupt mask (eight levels available) and the + following condition codes: overflow (V), zero (Z), negative (N), carry (C), and extend (X). + Additional status bits indicate that the processor is in the trace (T) mode and/or in the + supervisor (S) state (see Figure 2-4). Bits 5, 6, 7, 11, 12, and 14 are undefined and + reserved for future expansion + + SYSTEM BYTE USER BYTE + + + + 15 13 10 8 4 0 + T S I2 I1 I0 X N Z V C + + TRACE MODE EXTEND + NEGATIVE + SUPERVISOR CONDITION + STATE ZERO + CODES + OVERFLOW + INTERRUPT + MASK CARRY + + + + Figure 2-4. Status Register + + + 2.2 DATA TYPES AND ADDRESSING MODES + The five basic data types supported are as follows: + + 1. Bits + 2. Binary-Coded-Decimal (BCD) Digits (4 Bits) + 3. Bytes (8 Bits) + 4. Words (16 Bits) + 5. Long Words (32 Bits) + + MOTOROLA M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL 2-3 + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + In addition, operations on other data types, such as memory addresses, status word + data, etc., are provided in the instruction set. + + The 14 flexible addressing modes, shown in Table 2-1, include six basic types: + 1. Register Direct + 2. Register Indirect + 3. Absolute + 4. Immediate + 5. Program Counter Relative + 6. Implied + The register indirect addressing modes provide postincrementing, predecrementing, + offsetting, and indexing capabilities. The program counter relative mode also supports +Freescale Semiconductor, Inc... + + + + + indexing and offsetting. For detail information on addressing modes refer to + M68000PM/AD, M68000 Programmer Reference Manual. + + + + + 2-4 M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + Table 2-1. Data Addressing Modes + Mode Generation Syntax + Register Direct Addressing + Data Register Direct EA=Dn Dn + Address Register Direct EA=An An + Absolute Data Addressing + Absolute Short EA = (Next Word) (xxx).W + Absolute Long EA = (Next Two Words) (xxx).L + Program Counter Relative + Addressing EA = (PC)+d16 (d16,PC) + Relative with Offset EA = (PC)+d8 (d8,PC,Xn) + Relative with Index and Offset + Register Indirect Addressing + Register Indirect EA = (An) (An) + Postincrement Register Indirect EA = (An), An ← An+N (An)+ +Freescale Semiconductor, Inc... + + + + + Predecrement Register Indirect An ¯ An–N, EA=(An) -(An) + Register Indirect with Offset EA = (An)+d16 (d16,An) + Indexed Register Indirect with Offset EA = (An)+(Xn)+d8 (d8,An,Xn) + Immediate Data Addressing + Immediate DATA = Next Word(s) # + Quick Immediate Inherent Data + Implied Addressing 1 + Implied Register EA = SR, USP, SSP, PC, SR,USP,SSP,PC, + VBR, SFC, DFC VBR, SFC,DFC + NOTES: 1. The VBR, SFC, and DFC apply to the MC68010 only + EA = Effective Address + Dn = Data Register + An = Address Register + () = Contents of + PC = Program Counter + d8 = 8-Bit Offset (Displacement) + d16 = 16-Bit Offset (Displacement) + N = 1 for byte, 2 for word, and 4 for long word. If An is the stack pointer and + the operand size is byte, N = 2 to keep the stack pointer on a word boundary. + ¯ = Replaces + Xn = Address or Data Register used as Index Register + SR = Status Register + USP = User Stack Pointer + SSP = Supervisor Stack Pointer + CP = Program Counter + VBR = Vector Base Register + + + + 2.3 DATA ORGANIZATION IN REGISTERS + The eight data registers support data operands of 1, 8, 16, or 32 bits. The seven address + registers and the active stack pointer support address operands of 32 bits. + + 2.3.1 Data Registers + Each data register is 32 bits wide. Byte operands occupy the low-order 8 bits, word + operands the low-order 16 bits, and long-word operands, the entire 32 bits. The least + significant bit is addressed as bit zero; the most significant bit is addressed as bit 31. + + + MOTOROLA M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL 2-5 + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + When a data register is used as either a source or a destination operand, only the + appropriate low-order portion is changed; the remaining high-order portion is neither + used nor changed. + + 2.3.2 Address Registers + Each address register (and the stack pointer) is 32 bits wide and holds a full, 32-bit + address. Address registers do not support byte-sized operands. Therefore, when an + address register is used as a source operand, either the low-order word or the entire + long-word operand is used, depending upon the operation size. When an address + register is used as the destination operand, the entire register is affected, regardless of + the operation size. If the operation size is word, operands are sign-extended to 32 bits + before the operation is performed. +Freescale Semiconductor, Inc... + + + + + 2.4 DATA ORGANIZATION IN MEMORY + Bytes are individually addressable. As shown in Figure 2-5, the high-order byte of a + word has the same address as the word. The low-order byte has an odd address, one + count higher. Instructions and multibyte data are accessed only on word (even byte) + boundaries. If a long-word operand is located at address n (n even), then the second + word of that operand is located at address n+2. + + 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 + ADDRESS WORD 0 + $000000 BYTE 000000 BYTE 000001 + WORD 1 + $000002 BYTE 000002 BYTE 000003 + + + + + WORD 7FFFFF + $FFFFFE + BYTE FFFFFE BYTE FFFFFE + + + + Figure 2-5. Word Organization in Memory + + The data types supported by the M68000 MPUs are bit data, integer data of 8, 16, and + 32 bits, 32-bit addresses, and binary-coded-decimal data. Each data type is stored in + memory as shown in Figure 2-6. The numbers indicate the order of accessing the data + from the processor. For the MC68008 with its 8-bit bus, the appearance of data in + memory is identical to the all the M68000 MPUs. The organization of data in the memory + of the MC68008 is shown in Figure 2-7. + + + + + 2-6 M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + BIT DATA + 1 BYTE = 8 BITS + 7 6 5 4 3 2 1 0 + + + + INTEGER DATA + 1 BYTE = 8 BITS + 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 + + MSB BYTE 0 LSB BYTE 1 + + BYTE 2 BYTE 3 + + 1 WORD = 16 BITS + 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 + + MSB WORD 0 LSB +Freescale Semiconductor, Inc... + + + + + WORD 1 + + WORD 2 + + EVEN BYTE ODD BYTE + + 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 + 1 LONG WORD = 32 BITS + 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 + MSB HIGH ORDER + LONG WORD 0 + LOW ORDER LSB + + LONG WORD 1 + + + + LONG WORD 2 + + + ADDRESSES + 1 ADDRESS = 32 BITS + 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 + MSB HIGH ORDER + ADDRESS 0 + LOW ORDER LSB + + + ADDRESS 1 + + + + ADDRESS 2 + + + MSB = MOST SIGNIFICANT BIT + LSB = LEAST SIGNIFICANT BIT + DECIMAL DATA + 2 BINARY-CODED-DECIMAL DIGITS = 1 BYTE + 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 + MSD + BCD 0 BCD 1 BCD 2 BCD 3 + LSD + + BCD 4 BCD 5 BCD 6 BCD 7 + + MSD = MOST SIGNIFICANT DIGIT + LSD = LEAST SIGNIFICANT DIGIT + + + Figure 2-6. Data Organization in Memory + + MOTOROLA M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL 2-7 + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + BIT DATA 1 BYTE = 8 BITS + 7 6 5 4 3 2 1 0 + + + + + INTEGER DATA 1 BYTE = 8 BITS + 7 6 5 4 3 2 1 0 + + BYTE 0 LOWER ADDRESSES + + BYTE 1 + + BYTE 2 + + BYTE 3 HIGHER ADDRESSES + + + 1 WORD = 2 BYTES = 16 BITS + + BYTE 0 (MS BYTE) LOWER ADDRESSES +Freescale Semiconductor, Inc... + + + + + WORD 0 + BYTE 1 (LS BYTE) + + BYTE 0 (MS BYTE) + WORD 1 + BYTE 1 (LS BYTE) HIGHER ADDRESSES + + + 1 LONG WORD = 2 WORDS = 4 BYTES = 32 BITS + + BYTE 0 LOWER ADDRESSES + HIGH-ORDER + WORD + BYTE 1 + LONG WORD 0 + BYTE 2 + LOW-ORDER + WORD + BYTE 3 + + BYTE 0 + HIGH-ORDER + WORD + BYTE 1 + LONG WORD 1 + BYTE 2 + LOW-ORDER + WORD + BYTE 3 HIGHER ADDRESSES + + + + Figure 2-7. Memory Data Organization of the MC68008 + + + 2.5 INSTRUCTION SET SUMMARY + Table 2-2 provides an alphabetized listing of the M68000 instruction set listed by + opcode, operation, and syntax. In the syntax descriptions, the left operand is the source + operand, and the right operand is the destination operand. The following list contains the + notations used in Table 2-2. + + + + + 2-8 M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + Notation for operands: + + PC — Program counter + SR — Status register + V— Overflow condition code + Immediate Data —Immediate data from the instruction + Source — Source contents + Destination —Destination contents + Vector —Location of exception vector + Positive infinity + +inf — + Negative infinity + –inf — + —Operand data format: byte (B), word (W), long (L), single + (S), double (D), extended (X), or packed (P). + FPm — One of eight floating-point data registers (always +Freescale Semiconductor, Inc... + + + + + specifies the source register) + FPn — One of eight floating-point data registers (always + specifies the destination register) + + Notation for subfields and qualifiers: + of — Selects a single bit of the operand + {offset:width} — Selects a bit field + () — The contents of the referenced location + 10 — The operand is binary-coded decimal, operations are + performed in decimal + (
) — The register indirect operator + –(
) — Indicates that the operand register points to the memory + (
)+ — Location of the instruction operand—the optional mode + qualifiers are –, +, (d), and (d, ix) + #xxx or # — Immediate data that follows the instruction word(s) + + Notations for operations that have two operands, written , + where is one of the following: + + → — The source operand is moved to the destination operand + ↔ — The two operands are exchanged + + — The operands are added + – — The destination operand is subtracted from the source + operand + ×— The operands are multiplied + ÷— The source operand is divided by the destination + operand + <— Relational test, true if source operand is less than + destination operand + >— Relational test, true if source operand is greater than + destination operand + V— Logical OR + ⊕— Logical exclusive OR + Λ— Logical AND + + MOTOROLA M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL 2-9 + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + shifted by, rotated by — The source operand is shifted or rotated by the number of + positions specified by the second operand + + Notation for single-operand operations: + ~ — The operand is logically complemented + sign-extended — The operand is sign-extended, all bits of the upper + portion are made equal to the high-order bit of the lower + portion + tested — The operand is compared to zero and the condition + codes are set appropriately + + Notation for other operations: + TRAP — Equivalent to Format/Offset Word → (SSP); SSP–2 → + SSP; PC → (SSP); SSP–4 → SSP; SR → (SSP); +Freescale Semiconductor, Inc... + + + + + SSP–2 → SSP; (vector) → PC + STOP — Enter the stopped state, waiting for interrupts + If then — The condition is tested. If true, the operations after "then" + else are performed. If the condition is false and the optional + "else" clause is present, the operations after "else" are + performed. If the condition is false and else is omitted, the + instruction performs no operation. Refer to the Bcc + instruction description as an example. + + + + + 2-10 M68000 8-/16-/32-BIT MICROPROCESSOR USER’S MANUAL MOTOROLA + For More Information On This Product, + Go to: www.freescale.com + Freescale Semiconductor, Inc. + + Table 2-2. Instruction Set Summary (Sheet 1 of 4) + Opcode Operation Syntax + ABCD Source10 + Destination10 + X → Destination ABCD Dy,Dx + ABCD –(Ay), –(Ax) + ADD Source + Destination → Destination ADD ,Dn + ADD Dn, + ADDA Source + Destination → Destination ADDA ,An + ADDI Immediate Data + Destination → Destination ADDI # , + ADDQ Immediate Data + Destination → Destination ADDQ # , + ADDX Source + Destination + X → Destination ADDX Dy, Dx + ADDX –(Ay), –(Ax) + AND Source Λ Destination → Destination AND ,Dn + AND Dn, +Freescale Semiconductor, Inc... + + + + + ANDI Immediate Data Λ Destination → Destination ANDI # , + ANDI to CCR Source Λ CCR → CCR ANDI # , CCR + ANDI to SR If supervisor state ANDI # , SR + then Source Λ SR → SR + else TRAP + ASL, ASR Destination Shifted by → Destination ASd Dx,Dy + ASd # ,Dy + ASd + Bcc If (condition true) then PC + d → PC Bcc