M68300 Family Freescale Semiconductor, Inc... MC68332 User's Manual (c) MOTOROLA, INC. 1995 For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc... Freescale Semiconductor, Inc. For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS Paragraph Title Page SECTION 1 INTRODUCTION SECTION 2NOMENCLATURE Freescale Semiconductor, Inc... 2.1 2.2 2.3 2.4 2.5 Symbols and Operators .................................................................................. 2-1 CPU32 Registers ............................................................................................ 2-2 Pin and Signal Mnemonics ............................................................................. 2-3 Register Mnemonics ....................................................................................... 2-4 Conventions ................................................................................................... 2-5 SECTION 3OVERVIEW 3.1 3.1.1 3.1.2 3.1.3 3.1.4 3.1.5 3.2 3.3 3.4 3.5 3.6 3.6.1 3.6.2 3.7 3.7.1 3.7.2 MC68332 Features ......................................................................................... 3-1 System Integration Module (SIM) ........................................................... 3-1 Central Processing Unit (CPU) ............................................................... 3-1 Time Processor Unit (TPU) .................................................................... 3-1 Queued Serial Module (QSM) ................................................................ 3-2 Static RAM Module with TPU Emulation Capability (TPURAM) ............. 3-2 System Block Diagram and Pin Assignment Diagrams .................................. 3-2 Pin Descriptions ............................................................................................. 3-5 Signal Descriptions ......................................................................................... 3-7 Intermodule Bus ............................................................................................. 3-9 System Memory Map ..................................................................................... 3-9 Internal Register Map ........................................................................... 3-10 Address Space Maps ........................................................................... 3-10 System Reset ............................................................................................... 3-15 SIM Reset Mode Selection ................................................................... 3-15 MCU Module Pin Function During Reset ............................................. 3-16 SECTION 4 SYSTEM INTEGRATION MODULE 4.1 4.2 4.2.1 4.2.2 4.2.3 4.2.4 4.2.5 4.2.6 4.2.7 4.2.8 4.2.9 General ........................................................................................................... 4-1 System Configuration and Protection ............................................................. 4-2 Module Mapping ..................................................................................... 4-3 Interrupt Arbitration ................................................................................. 4-3 Show Internal Cycles .............................................................................. 4-4 Factory Test Mode ................................................................................. 4-4 Register Access ..................................................................................... 4-4 Reset Status ........................................................................................... 4-4 Bus Monitor ............................................................................................ 4-5 Halt Monitor ............................................................................................ 4-5 Spurious Interrupt Monitor ...................................................................... 4-5 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS Freescale Semiconductor, Inc... Paragraph (Continued) Title Page 4.2.10 Software Watchdog ................................................................................ 4-5 4.2.11 Periodic Interrupt Timer .......................................................................... 4-7 4.2.12 Low-Power Stop Operation .................................................................... 4-8 4.2.13 Freeze Operation ................................................................................... 4-9 4.3 System Clock ................................................................................................. 4-9 4.3.1 Clock Sources ...................................................................................... 4-10 4.3.2 Clock Synthesizer Operation ................................................................ 4-10 4.3.3 External Bus Clock ............................................................................... 4-15 4.3.4 Low-Power Operation ........................................................................... 4-15 4.3.5 Loss of Reference Signal ..................................................................... 4-16 4.4 External Bus Interface .................................................................................. 4-17 4.4.1 Bus Signals .......................................................................................... 4-18 4.4.1.1 Address Bus ................................................................................. 4-18 4.4.1.2 Address Strobe ............................................................................ 4-18 4.4.1.3 Data Bus ...................................................................................... 4-18 4.4.1.4 Data Strobe .................................................................................. 4-18 4.4.1.5 Read/Write Signal ........................................................................ 4-18 4.4.1.6 Size Signals ................................................................................. 4-19 4.4.1.7 Function Codes ............................................................................ 4-19 4.4.1.8 Data and Size Acknowledge Signals ........................................... 4-19 4.4.1.9 Bus Error Signal ........................................................................... 4-20 4.4.1.10 Halt Signal .................................................................................... 4-20 4.4.1.11 Autovector Signal ......................................................................... 4-20 4.4.2 Dynamic Bus Sizing ............................................................................. 4-20 4.4.3 Operand Alignment .............................................................................. 4-21 4.4.4 Misaligned Operands ........................................................................... 4-22 4.4.5 Operand Transfer Cases ...................................................................... 4-22 4.5 Bus Operation .............................................................................................. 4-22 4.5.1 Synchronization to CLKOUT ................................................................ 4-23 4.5.2 Regular Bus Cycles .............................................................................. 4-23 4.5.2.1 Read Cycle ................................................................................... 4-24 4.5.2.2 Write Cycle ................................................................................... 4-25 4.5.3 Fast Termination Cycles ....................................................................... 4-26 4.5.4 CPU Space Cycles ............................................................................... 4-27 4.5.4.1 Breakpoint Acknowledge Cycle .................................................... 4-28 4.5.4.2 LPSTOP Broadcast Cycle ............................................................ 4-31 4.5.5 Bus Exception Control Cycles .............................................................. 4-31 4.5.5.1 Bus Errors .................................................................................... 4-33 4.5.5.2 Double Bus Faults ........................................................................ 4-33 4.5.5.3 Retry Operation ............................................................................ 4-34 4.5.5.4 Halt Operation .............................................................................. 4-34 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS Freescale Semiconductor, Inc... Paragraph 4.5.6 4.5.6.1 4.5.6.2 4.6 4.6.1 4.6.2 4.6.3 4.6.3.1 4.6.3.2 4.6.3.3 4.6.4 4.6.5 4.6.5.1 4.6.5.2 4.6.6 4.6.7 4.6.8 4.6.9 4.7 4.7.1 4.7.2 4.7.3 4.7.4 4.7.5 4.8 4.8.1 4.8.1.1 4.8.1.2 4.8.1.3 4.8.1.4 4.8.2 4.8.3 4.8.4 4.9 4.9.1 4.9.2 4.9.3 4.10 (Continued) Title Page External Bus Arbitration ........................................................................ 4-35 Slave (Factory Test) Mode Arbitration ......................................... 4-36 Show Cycles ................................................................................ 4-36 Reset ............................................................................................................ 4-37 Reset Exception Processing ................................................................ 4-37 Reset Control Logic .............................................................................. 4-38 Reset Mode Selection .......................................................................... 4-38 Data Bus Mode Selection ............................................................. 4-39 Clock Mode Selection .................................................................. 4-41 Breakpoint Mode Selection .......................................................... 4-41 MCU Module Pin Function During Reset ............................................. 4-41 Pin State During Reset ......................................................................... 4-42 Reset States of SIM Pins ............................................................. 4-42 Reset States of Pins Assigned to Other MCU Modules ............... 4-43 Reset Timing ........................................................................................ 4-43 Power-On Reset ................................................................................... 4-44 Reset Processing Summary ................................................................. 4-45 Reset Status Register .......................................................................... 4-46 Interrupts ...................................................................................................... 4-46 Interrupt Exception Processing ............................................................ 4-46 Interrupt Priority and Recognition ......................................................... 4-46 Interrupt Acknowledge and Arbitration ................................................. 4-47 Interrupt Processing Summary ............................................................. 4-48 Interrupt Acknowledge Bus Cycles ....................................................... 4-49 Chip Selects ................................................................................................. 4-49 Chip-Select Registers ........................................................................... 4-51 Chip-Select Pin Assignment Registers ........................................ 4-52 Chip-Select Base Address Registers ........................................... 4-53 Chip-Select Option Registers ....................................................... 4-53 PORTC Data Register .................................................................. 4-55 Chip-Select Operation .......................................................................... 4-55 Using Chip-Select Signals for Interrupt Acknowledge .......................... 4-55 Chip-Select Reset Operation ................................................................ 4-56 Parallel Input/Output Ports ........................................................................... 4-58 Pin Assignment Registers .................................................................... 4-58 Data Direction Registers ...................................................................... 4-58 Data Registers ...................................................................................... 4-58 Factory Test ................................................................................................. 4-58 SECTION 5 CENTRAL PROCESSING UNIT 5.1 General ........................................................................................................... 5-1 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS Freescale Semiconductor, Inc... Paragraph (Continued) Title Page 5.2 CPU32 Registers ............................................................................................ 5-2 5.2.1 Data Registers ........................................................................................ 5-3 5.2.2 Address Registers .................................................................................. 5-5 5.2.3 Program Counter .................................................................................... 5-5 5.2.4 Control Registers .................................................................................... 5-5 5.2.4.1 Status Register ............................................................................... 5-5 5.2.4.2 Alternate Function Code Registers ................................................ 5-6 5.2.5 Vector Base Register (VBR) ................................................................... 5-6 5.3 Memory Organization ..................................................................................... 5-6 5.4 Virtual Memory ............................................................................................... 5-8 5.5 Addressing Modes .......................................................................................... 5-8 5.6 Processing States .......................................................................................... 5-8 5.7 Privilege Levels .............................................................................................. 5-9 5.8 Instructions ..................................................................................................... 5-9 5.8.1 M68000 Family Compatibility ............................................................... 5-12 5.8.2 Special Control Instructions .................................................................. 5-13 5.8.2.1 Low Power Stop (LPSTOP) ......................................................... 5-13 5.8.2.2 Table Lookup and Interpolate (TBL) ............................................ 5-13 5.9 Exception Processing ................................................................................... 5-13 5.9.1 Exception Vectors ................................................................................ 5-13 5.9.2 Types of Exceptions ............................................................................. 5-14 5.9.3 Exception Processing Sequence .......................................................... 5-15 5.10 Development Support ................................................................................... 5-15 5.10.1 M68000 Family Development Support ................................................. 5-15 5.10.2 Background Debugging Mode .............................................................. 5-16 5.10.2.1 Enabling BDM .............................................................................. 5-17 5.10.2.2 BDM Sources ............................................................................... 5-17 5.10.2.3 Entering BDM ............................................................................... 5-18 5.10.2.4 BDM Commands .......................................................................... 5-19 5.10.2.5 Background Mode Registers ........................................................ 5-20 5.10.2.6 Returning from BDM .................................................................... 5-20 5.10.2.7 Serial Interface ............................................................................. 5-20 5.10.3 Recommended BDM Connection ......................................................... 5-22 5.10.4 Deterministic Opcode Tracking ............................................................ 5-22 5.10.5 On-Chip Breakpoint Hardware ............................................................. 5-23 5.11 Loop Mode Instruction Execution ................................................................. 5-23 SECTION 6QUEUED SERIAL MODULE 6.1 6.2 6.2.1 General ........................................................................................................... 6-1 QSM Registers and Address Map .................................................................. 6-2 QSM Global Registers ........................................................................... 6-2 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS Freescale Semiconductor, Inc... Paragraph (Continued) Title Page 6.2.1.1 Low-Power Stop Operation ........................................................... 6-2 6.2.1.2 Freeze Operation .......................................................................... 6-3 6.2.1.3 QSM Interrupts .............................................................................. 6-3 6.2.2 QSM Pin Control Registers ................................................................... 6-3 6.3 Queued Serial Peripheral Interface ................................................................ 6-4 6.3.1 QSPI Registers ...................................................................................... 6-6 6.3.1.1 Control Registers ........................................................................... 6-7 6.3.1.2 Status Register .............................................................................. 6-7 6.3.2 QSPI RAM ............................................................................................. 6-7 6.3.2.1 Receive RAM ................................................................................. 6-7 6.3.2.2 Transmit RAM ................................................................................ 6-8 6.3.2.3 Command RAM ............................................................................. 6-8 6.3.3 QSPI Pins ............................................................................................... 6-8 6.3.4 QSPI Operation ...................................................................................... 6-9 6.3.5 QSPI Operating Modes ........................................................................ 6-10 6.3.5.1 Master Mode ................................................................................ 6-17 6.3.5.2 Master Wraparound Mode ........................................................... 6-20 6.3.5.3 Slave Mode .................................................................................. 6-20 6.3.5.4 Slave Wraparound Mode ............................................................. 6-22 6.3.6 Peripheral Chip Selects ........................................................................ 6-22 6.4 Serial Communication Interface ................................................................... 6-22 6.4.1 SCI Registers ....................................................................................... 6-22 6.4.1.1 Control Registers ......................................................................... 6-22 6.4.1.2 Status Register ............................................................................. 6-25 6.4.1.3 Data Register ............................................................................... 6-25 6.4.2 SCI Pins .............................................................................................. 6-25 6.4.3 SCI Operation ....................................................................................... 6-25 6.4.3.1 Definition of Terms ....................................................................... 6-25 6.4.3.2 Serial Formats .............................................................................. 6-26 6.4.3.3 Baud Clock ................................................................................... 6-26 6.4.3.4 Parity Checking ............................................................................ 6-27 6.4.3.5 Transmitter Operation .................................................................. 6-27 6.4.3.6 Receiver Operation ...................................................................... 6-28 6.4.3.7 Idle-Line Detection ....................................................................... 6-29 6.4.3.8 Receiver Wakeup ......................................................................... 6-30 6.4.3.9 Internal Loop ................................................................................ 6-30 6.5 QSM Initialization ......................................................................................... 6-31 SECTION 7TIME PROCESSOR UNIT 7.1 7.2 General ........................................................................................................... 7-1 TPU Components ........................................................................................... 7-2 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS Freescale Semiconductor, Inc... Paragraph 7.2.1 7.2.2 7.2.3 7.2.4 7.2.5 7.2.6 7.3 7.3.1 7.3.2 7.3.3 7.3.4 7.3.5 7.3.6 7.3.7 7.4 7.4.1 7.4.2 7.4.3 7.4.4 7.4.5 7.4.6 7.4.7 7.4.8 7.4.9 7.4.10 7.4.11 7.5 7.5.1 7.5.2 7.5.3 7.5.4 7.5.5 7.5.6 7.5.7 7.5.8 7.5.9 7.5.10 7.6 7.6.1 7.6.1.1 7.6.1.2 (Continued) Title Page Time Bases ............................................................................................ 7-2 Timer Channels ...................................................................................... 7-2 Scheduler ............................................................................................... 7-2 Microengine ............................................................................................ 7-2 Host Interface ......................................................................................... 7-2 Parameter RAM ...................................................................................... 7-3 TPU Operation ............................................................................................... 7-3 Event Timing .......................................................................................... 7-3 Channel Orthogonality ............................................................................ 7-4 Interchannel Communication .................................................................. 7-4 Programmable Channel Service Priority ................................................ 7-4 Coherency .............................................................................................. 7-4 Emulation Support .................................................................................. 7-4 TPU Interrupts ........................................................................................ 7-5 Standard and Enhanced Standard Time Functions ....................................... 7-6 Discrete Input/Output (DIO) .................................................................... 7-6 Input Capture/Input Transition Counter (ITC) ......................................... 7-6 Output Compare (OC) ............................................................................ 7-6 Pulse-Width Modulation (PWM) ............................................................. 7-7 Synchronized Pulse-Width Modulation (SPWM) .................................... 7-7 Period Measurement with Additional Transition Detect (PMA) .............. 7-7 Period Measurement with Missing Transition Detect (PMM) ................. 7-7 Position-Synchronized Pulse Generator (PSP) ...................................... 7-7 Stepper Motor (SM) ................................................................................ 7-8 Period/Pulse-Width Accumulator (PPWA) .............................................. 7-8 Quadrature Decode (QDEC) .................................................................. 7-9 Motion Control Time Functions ...................................................................... 7-9 Table Stepper Motor (TSM) .................................................................... 7-9 New Input Capture/Transition Counter (NITC) ....................................... 7-9 Queued Output Match (QOM) .............................................................. 7-10 Programmable Time Accumulator (PTA) ............................................. 7-10 Multichannel Pulse-Width Modulation (MCPWM) ................................ 7-10 Fast Quadrature Decode (FQD) ........................................................... 7-10 Universal Asynchronous Receiver/Transmitter (UART) ....................... 7-11 Brushless Motor Commutation (COMM) .............................................. 7-11 Frequency Measurement (FQM) .......................................................... 7-11 Hall Effect Decode (HALLD) ................................................................. 7-11 Host Interface Registers ............................................................................... 7-11 System Configuration Registers ........................................................... 7-12 Prescaler Control for TCR1 .......................................................... 7-12 Prescaler Control for TCR2 .......................................................... 7-12 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS (Continued) Title Paragraph Freescale Semiconductor, Inc... 7.6.1.3 7.6.1.4 7.6.2 7.6.2.1 7.6.2.2 7.6.2.3 7.6.2.4 7.6.2.5 7.6.3 Page Emulation Control ......................................................................... 7-13 Low-Power Stop Control .............................................................. 7-13 Channel Control Registers ................................................................... 7-14 Channel Interrupt Enable and Status Registers ........................... 7-14 Channel Function Select Registers .............................................. 7-14 Host Sequence Registers ............................................................ 7-14 Host Service Registers ................................................................. 7-14 Channel Priority Registers ........................................................... 7-14 Development Support and Test Registers ........................................... 7-15 SECTION 8STANDBY RAM WITH TPU EMULATION 8.1 8.2 8.3 8.4 8.5 8.6 8.7 8.8 8.9 General ........................................................................................................... 8-1 TPURAM Register Block ................................................................................ 8-1 TPURAM Array Address Mapping .................................................................. 8-1 TPURAM Privilege Level ................................................................................ 8-2 Normal Operation ........................................................................................... 8-2 Standby Operation ......................................................................................... 8-2 Low-Power Stop Operation ............................................................................ 8-3 Reset .............................................................................................................. 8-3 TPU Microcode Emulation .............................................................................. 8-3 APPENDIX A ELECTRICAL CHARACTERISTICS APPENDIX B MECHANICAL DATA AND ORDERING INFORMATION APPENDIX CDEVELOPMENT SUPPORT C.1 C.2 M68MMDS1632 Modular Development System ........................................... C-1 M68MEVB1632 Modular Evaluation Board ................................................... C-2 APPENDIX D REGISTER SUMMARY D.1 D.1.1 D.1.2 D.2 D.2.1 D.2.2 D.2.3 D.2.4 D.2.5 D.2.6 Central Processing Unit ................................................................................. D-1 CPU32 Register Model .......................................................................... D-2 SR -- Status Register ........................................................................... D-3 System Integration Module ............................................................................ D-3 SIMCR -- Module Configuration Register ............................. $YFFA00 D-5 SIMTR -- System Integration Test Register .......................... $YFFA02 D-6 SYNCR -- Clock Synthesizer Control Register .................... $YFFA04 D-6 RSR -- Reset Status Register .............................................. $YFFA07 D-7 SIMTRE -- System Integration Test Register (ECLK) ........... $YFFA08 D-7 PORTE0/PORTE1 -- Port E Data Register .......... $YFFA11, $YFFA13 D-8 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS Freescale Semiconductor, Inc... Paragraph (Continued) Title Page D.2.7 DDRE -- Port E Data Direction Register ............................... $YFFA15 D-8 D.2.8 PEPAR -- Port E Pin Assignment Register ........................... $YFFA17 D-8 D.2.9 PORTF0/PORTF1 -- Port F Data Register...........$YFFA19, $YFFA1B D-9 D.2.10 DDRF -- Port F Data Direction Register................................$YFFA1D D-9 D.2.11 PFPAR -- Port F Pin Assignment Register............................ $YFFA1F D-9 D.2.12 SYPCR -- System Protection Control Register ................... $YFFA21 D-10 D.2.13 PICR -- Periodic Interrupt Control Register......................... $YFFA22 D-11 D.2.14 PITR -- Periodic Interrupt Timer Register ........................... $YFFA24 D-11 D.2.15 SWSR -- Software Service Register ................................... $YFFA27 D-11 D.2.16 TSTMSRA -- Master Shift Register A.................................. $YFFA30 D-11 D.2.17 TSTMSRB -- Master Shift Register B.................................. $YFFA32 D-11 D.2.18 TSTSC -- Test Module Shift Count ..................................... $YFFA34 D-12 D.2.19 TSTRC -- Test Module Repetition Count ............................ $YFFA36 D-12 D.2.20 CREG -- Test Submodule Control Register ....................... $YFFA38 D-12 D.2.21 DREG -- Distributed Register..............................................$YFFA3A D-12 D.2.22 PORTC -- Port C Data Register .......................................... $YFFA41 D-12 D.2.23 CSPAR0 -- Chip Select Pin Assignment Register 0............ $YFFA44 D-12 D.2.24 CSPAR1 -- Chip Select Pin Assignment Register 1............ $YFFA46 D-13 D.2.25 CSBARBT -- Chip Select Base Address Register Boot ROM $YFFA48 D13 D.2.26 CSBAR[0:10] -- Chip Select Base Address Registers $YFFA4C-$YFFA74 D-13 D.2.27 CSORBT -- Chip Select Option Register Boot ROM...........$YFFA4A D-14 D.2.28 CSOR[0:10] -- Chip Select Option Registers .....$YFFA4E-$YFFA76 D-14 D.3 Standby RAM Module with TPU Emulation ................................................. D-16 D.3.1 TRAMMCR -- TPURAM Module Configuration Register..... $YFFB00 D-16 D.3.2 TRAMTST -- TPURAM Test Register ................................. $YFFB02 D-16 D.3.3 TRAMBAR -- TPURAM Base Address and Status Register $YFFB04 D-16 D.4 Queued Serial Module ................................................................................. D-18 D.4.1 QSMCR -- QSM Configuration Register ............................. $YFFC00 D-18 D.4.2 QTEST -- QSM Test Register ............................................. $YFFC02 D-19 D.4.3 QILR -- QSM Interrupt Level Register..........................................$YFFC04 QIVR -- QSM Interrupt Vector Register$YFFC05 .................................................... D-19 D.4.4 SCCR0 -- SCI Control Register 0 ....................................... $YFFC08 D-20 D.4.5 SCCR1 -- SCI Control Register 1........................................$YFFC0A D-20 D.4.6 SCSR -- SCI Status Register ............................................. $YFFC0C D-22 D.4.7 SCDR -- SCI Data Register.................................................$YFFC0E D-23 D.4.8 PORTQS -- Port QS Data Register..................................... $YFFC15 D-23 D.4.9 PQSPAR -- PORT QS Pin Assignment Register .........................$YFFC16 DDRQS -- PORT QS Data Direction Register$YFFC17 .......................................... D-23 D.4.10 SPCR0 -- QSPI Control Register 0 ..................................... $YFFC18 D-25 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS Freescale Semiconductor, Inc... Paragraph (Continued) Title Page D.4.11 SPCR1 -- QSPI Control Register 1 ....................................$YFFC1A D-26 D.4.12 SPCR2 -- QSPI Control Register 2 ................................... $YFFC1C D-27 D.4.13 SPCR3 -- QSPI Control Register 3 ............................................ $YFFC1E SPSR -- QSPI Status Register $YFFC1F ................................................................ D-27 D.4.14 RR[0:F] -- Receive Data RAM........................... $YFFD00-$YFFD0E D-28 D.4.15 TR[0:F] -- Transmit Data RAM ......................... $YFFD20-$YFFD3E D-28 D.4.16 CR[0:F] -- Command RAM................................ $YFFD40-$YFFD4F D-29 D.5.1 TPUMCR -- TPU Module Configuration Register................ $YFFE00 D-30 D.5.2 TCR -- Test Configuration Register..................................... $YFFE02 D-32 D.5.3 DSCR -- Development Support Control Register................ $YFFE04 D-32 D.5.4 DSSR -- Development Support Status Register ................. $YFFE06 D-33 D.5.5 TICR -- TPU Interrupt Configuration Register ..................... $YFFE08 D-33 D.5.6 CIER -- Channel Interrupt Enable Register.........................$YFFE0A D-34 D.5.7 CFSR0 -- Channel Function Select Register 0 ...................$YFFE0C D-34 D.5.8 CFSR1 -- Channel Function Select Register 1 ...................$YFFE0E D-34 D.5.9 CFSR2 -- Channel Function Select Register 2 ................... $YFFE10 D-34 D.5.10 CFSR3 -- Channel Function Select Register 3 ................... $YFFE12 D-34 D.5.11 HSQR0 -- Host Sequence Register 0 ................................. $YFFE14 D-35 D.5.12 HSQR1 -- Host Sequence Register 1 ................................. $YFFE16 D-35 D.5.13 HSRR0 -- Host Service Request Register 0 ....................... $YFFE18 D-35 D.5.15 CPR0 -- Channel Priority Register 0 ..................................$YFFE1C D-36 D.5.16 CPR1 -- Channel Priority Register 1 .................................. $YFFE1E D-36 D.5.17 CISR -- Channel Interrupt Status Register.......................... $YFFE20 D-36 D.5.18 LR -- Link Register .............................................................. $YFFE22 D-36 D.5.19 SGLR -- Service Grant Latch Register................................ $YFFE24 D-36 D.5.20 DCNR -- Decoded Channel Number Register .................... $YFFE26 D-37 D.5.21 TPU Parameter RAM .......................................................................... D-37 SUMMARY OF CHANGES MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. TABLE OF CONTENTS (Continued) Title Page Freescale Semiconductor, Inc... Paragraph MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. LIST OF ILLUSTRATIONS Freescale Semiconductor, Inc... Figure 3-1 3-2 3-3 3-4 3-5 3-6 3-7 3-8 4-1 4-2 4-3 4-4 4-5 4-6 4-7 4-8 4-9 4-10 4-11 4-12 4-13 4-14 4-15 4-16 4-17 4-18 4-19 5-1 5-2 5-3 5-4 5-5 5-6 5-7 5-8 5-9 5-10 5-11 5-12 6-1 6-2 Title Page MCU Block Diagram ....................................................................................... 3-3 Pin Assignments for 132-Pin Package ........................................................... 3-4 Pin Assignments for 144-Pin Package ........................................................... 3-5 Internal Register Memory Map ..................................................................... 3-10 Overall Memory Map .................................................................................... 3-11 Separate Supervisor and User Space Map .................................................. 3-12 Supervisor Space (Separate Program/Data Space) Map ............................ 3-13 User Space (Separate Program/Data Space) Map ...................................... 3-14 System Integration Module Block Diagram .................................................... 4-2 System Configuration and Protection ............................................................. 4-3 Periodic Interrupt Timer and Software Watchdog Timer ................................ 4-7 System Clock Block Diagram ......................................................................... 4-9 System Clock Oscillator Circuit .................................................................... 4-10 System Clock Filter Networks ...................................................................... 4-11 MCU Basic System ...................................................................................... 4-17 Operand Byte Order ..................................................................................... 4-21 Word Read Cycle Flowchart ......................................................................... 4-25 Write Cycle Flowchart .................................................................................. 4-26 CPU Space Address Encoding .................................................................... 4-27 Breakpoint Operation Flowchart ................................................................... 4-30 LPSTOP Interrupt Mask Level ...................................................................... 4-31 Bus Arbitration Flowchart for Single Request ............................................... 4-36 Data Bus Mode Select Conditioning ............................................................. 4-40 Power-On Reset ........................................................................................... 4-45 Basic MCU System ...................................................................................... 4-50 Chip-Select Circuit Block Diagram ............................................................... 4-51 CPU Space Encoding for Interrupt Acknowledge ......................................... 4-56 CPU32 Block Diagram ................................................................................... 5-2 User Programming Model .............................................................................. 5-3 Supervisor Programming Model Supplement ................................................. 5-3 Data Organization in Data Registers .............................................................. 5-4 Address Organization in Address Registers ................................................... 5-5 Memory Operand Addressing ........................................................................ 5-7 Common in-Circuit Emulator Diagram .......................................................... 5-16 Bus State Analyzer Configuration ................................................................ 5-17 Debug Serial I/O Block Diagram .................................................................. 5-21 BDM Serial Data Word ................................................................................. 5-22 BDM Connector Pinout ................................................................................. 5-22 Loop Mode Instruction Sequence ................................................................. 5-23 QSM Block Diagram ....................................................................................... 6-1 QSPI Block Diagram ..................................................................................... 6-6 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. LIST OF ILLUSTRATIONS Freescale Semiconductor, Inc... Figure 6-3 6-4 6-5 6-5 6-5 6-6 6-6 6-7 6-8 7-1 7-2 7-3 A-1 A-2 A-3 A-4 A-5 A-6 A-7 A-8 A-9 A-10 A-11 A-12 A-13 A-14 A-15 A-16 A-17 A-18 A-19 A-20 B-1 B-2 D-1 D-2 (Continued) Title Page QSPI RAM ...................................................................................................... 6-8 Flowchart of QSPI Initialization Operation .................................................... 6-11 Flowchart of QSPI Master Operation (Part 1) .............................................. 6-12 Flowchart of QSPI Master Operation (Part 2) .............................................. 6-13 Flowchart of QSPI Master Operation (Part 3) .............................................. 6-14 Flowchart of QSPI Slave Operation (Part 1) ................................................ 6-15 Flowchart of QSPI Slave Operation (Part 2) ................................................ 6-16 SCI Transmitter Block Diagram .................................................................... 6-23 SCI Receiver Block Diagram ........................................................................ 6-24 TPU Block Diagram ........................................................................................ 7-1 TCR1 Prescaler Control ............................................................................... 7-12 TCR2 Prescaler Control ............................................................................... 7-13 CLKOUT Output Timing Diagram ................................................................. A-14 External Clock Input Timing Diagram ........................................................... A-14 ECLK Output Timing Diagram ...................................................................... A-14 Read Cycle Timing Diagram ........................................................................ A-15 Write Cycle Timing Diagram ......................................................................... A-16 Fast Termination Read Cycle Timing Diagram ............................................ A-17 Fast Termination Write Cycle Timing Diagram ............................................. A-18 Bus Arbitration Timing Diagram --Active Bus Case .................................... A-19 Bus Arbitration Timing Diagram -- Idle Bus Case ....................................... A-20 Show Cycle Timing Diagram ........................................................................ A-20 Chip Select Timing Diagram ......................................................................... A-21 Reset and Mode Select Timing Diagram ...................................................... A-21 Background Debugging Mode Timing Diagram -- Serial Communication ... A-23 Background Debugging Mode Timing Diagram -- Freeze Assertion ........... A-23 ECLK Timing Diagram .................................................................................. A-25 QSPI Timing -- Master, CPHA = 0 .............................................................. A-27 QSPI Timing -- Master, CPHA = 1 .............................................................. A-27 QSPI Timing -- Slave, CPHA = 0 ................................................................ A-28 QSPI Timing -- Slave, CPHA = 1 ................................................................ A-28 TPU Timing Diagram .................................................................................... A-29 132-Pin Plastic Surface Mount Package Pin Assignments ............................ B-2 144-Pin Plastic Surface Mount Package Pin Assignments ............................ B-3 User Programming Model ..............................................................................D-2 Supervisor Programming Model Supplement .................................................D-2 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. LIST OF TABLES Freescale Semiconductor, Inc... Table 3-1 3-2 3-3 3-4 3-5 3-6 3-7 4-1 4-2 4-3 4-4 4-5 4-6 4-7 4-8 4-9 4-10 4-11 4-12 4-13 4-14 4-15 4-16 4-17 4-18 4-19 4-20 4-21 4-22 4-23 4-24 5-1 5-2 5-3 5-4 5-5 5-6 6-1 6-2 6-3 6-4 Title Page MCU Driver Types........................................................................................... 3-6 MCU Pin Characteristics ................................................................................. 3-6 MCU Power Connections ................................................................................ 3-7 MCU Signal Characteristics ............................................................................ 3-7 MCU Signal Function ...................................................................................... 3-8 SIM Reset Mode Selection............................................................................ 3-15 Module Pin Functions.................................................................................... 3-16 Show Cycle Enable Bits .................................................................................. 4-4 Bus Monitor Period.......................................................................................... 4-5 MODCLK Pin and SWP Bit During Reset ....................................................... 4-6 Software Watchdog Ratio................................................................................ 4-6 MODCLK Pin and PTP Bit at Reset ................................................................ 4-7 Periodic Interrupt Priority................................................................................. 4-8 Clock Control Multipliers................................................................................ 4-12 System Frequencies from 32.768-kHz Reference........................................ 4-14 Clock Control................................................................................................. 4-16 Size Signal Encoding .................................................................................... 4-19 Address Space Encoding .............................................................................. 4-19 Effect of DSACK Signals ............................................................................... 4-21 Operand Transfer Cases............................................................................... 4-22 DSACK, BERR, and HALT Assertion Results ............................................... 4-32 Reset Source Summary ................................................................................ 4-38 Reset Mode Selection ................................................................................... 4-39 Module Pin Functions.................................................................................... 4-42 SIM Pin Reset States .................................................................................... 4-43 Chip-Select Pin Functions ............................................................................. 4-52 Pin Assignment Field Encoding..................................................................... 4-52 Block Size Encoding...................................................................................... 4-53 Option Register Function Summary .............................................................. 4-54 Chip Select Base and Option Register Reset Values ................................... 4-57 CSBOOT Base and Option Register Reset Values....................................... 4-58 Instruction Set Summary ............................................................................... 5-10 Exception Vector Assignments...................................................................... 5-14 BDM Source Summary.................................................................................. 5-17 Polling the BDM Entry Source....................................................................... 5-18 Background Mode Command Summary ....................................................... 5-19 CPU Generated Message Encoding ............................................................. 5-22 QSM Pin Function ........................................................................................... 6-4 QSPI Pin Function........................................................................................... 6-9 BITS Encoding .............................................................................................. 6-19 SCI Pin Function ........................................................................................... 6-25 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. LIST OF TABLES Freescale Semiconductor, Inc... Table 6-5 6-6 7-1 7-2 7-3 A-1 A-2 A-2 a. A-3 A-4 A-4 a. A-5 A-5 a. A-6 A-6 a. A-7 A-8 A-8 a. A-9 A-10 A-11 B-1 B-2 C-1 D-1 D-2 D-3 D-4 D-5 D-6 D-7 D-8 (Continued) Title Page Serial Frame Formats.................................................................................... 6-26 Effect of Parity Checking on Data Size ......................................................... 6-27 TCR1 Prescaler Control ................................................................................ 7-12 TCR2 Prescaler Control ................................................................................ 7-13 Channel Priority Encodings ........................................................................... 7-15 Maximum Ratings............................................................................................ A-1 Typical Ratings, 16.78 MHz Operation............................................................ A-2 Typical Ratings, 20.97 MHz Operation............................................................ A-2 Thermal Characteristics .................................................................................. A-3 16.78 MHz Clock Control Timing..................................................................... A-4 20.97 MHz Clock Control Timing..................................................................... A-5 16.78 MHz DC Characteristics ........................................................................ A-6 20.97 MHz DC Characteristics ........................................................................ A-7 16.78 MHz AC Timing ..................................................................................... A-9 20.97 MHz AC Timing ................................................................................... A-11 Background Debugging Mode Timing ........................................................... A-22 16.78 MHz ECLK Bus Timing........................................................................ A-24 20.97 MHz ECLK Bus Timing........................................................................ A-24 QSPI Timing .................................................................................................. A-26 16.78 MHz Time Processor Unit Timing........................................................ A-29 20.97 MHz Time Processor Unit Timing........................................................ A-29 MCU Ordering Information .............................................................................. B-5 Quantity Order Suffix....................................................................................... B-7 MC68332 Development Tools.........................................................................C-1 Module Address Map ......................................................................................D-1 SIM Address Map............................................................................................D-4 TPURAM Address Map .................................................................................D-16 QSM Address Map ........................................................................................D-18 TPU Address Map .........................................................................................D-30 Parameter RAM Address Map ......................................................................D-37 MC68332 Module Address Map....................................................................D-38 Register Bit and Field Mnemonics.................................................................D-41 MC68332 USER'S MANUAL For More Information On This Product, Go to: www.freescale.com Freescale Semiconductor, Inc. SECTION 1 INTRODUCTION Freescale Semiconductor, Inc... The MC68332, a highly-integrated 32-bit microcontroller, combines high-performance data manipulation capabilities with powerful peripheral subsystems. The MCU is built up from standard modules that interface through a common intermodule bus (IMB). Standardization facilitates rapid development of devices tailored for specific applications. The MCU incorporates a 32-bit CPU (CPU32), a system integration module (SIM), a time processor unit (TPU), a queued serial module (QSM), and a 2-Kbyte static RAM module with TPU emulation capability (TPURAM). The MCU can either synthesize an internal clock signal from an external reference or use an external clock input directly. Operation with a 32.768-kHz reference frequency is standard. System hardware and software allow changes in clock rate during operation. Because MCU operation is fully static, register and memory contents are not affected by clock rate changes. High-density complementary metal-oxide semiconductor (HCMOS) architecture makes the basic power consumption of the MCU low. Power consumption can be minimized by stopping the system clock. The CPU32 instruction set includes a low-power stop (LPSTOP) command that efficiently implements this capability. Documentation for the Modular Microcontroller Family follows the modular construction of the devices in the product line. Each microcontroller has a comprehensive user's manual that provides sufficient information for normal operation of the device. The user's manual is supplemented by module reference manuals that provide detailed information about module operation and applications. Refer to Freescale publicationAdvanced Microcontroller Unit (AMCU) Literature (BR1116/D) for a complete listing of documentation. MC68332 USER'S MANUAL INTRODUCTION For More Information On This Product, Go to: www.freescale.com 1-1 Freescale Semiconductor, Inc... Freescale Semiconductor, Inc. INTRODUCTION 1-2 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. SECTION 2 NOMENCLATURE The following nomenclature is used throughout the manual. Nomenclature used only in certain sections, such as register bit mnemonics, is defined in those sections. Freescale Semiconductor, Inc... 2.1 Symbols and Operators + * / > < = * ; NOT : % $ -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Addition Subtraction or negation (two's complement) Multiplication Division Greater Less Equal Equal or greater Equal or less Not equal AND Inclusive OR (OR) Exclusive OR (EOR) Complementation Concatenation Transferred Exchanged Sign bit; also used to show tolerance Sign extension Binary value Hexadecimal value MC68332 USER'S MANUAL NOMENCLATURE For More Information On This Product, Go to: www.freescale.com 2-1 Freescale Semiconductor, Inc. Freescale Semiconductor, Inc... 2.2 CPU32 Registers A6-A0 A7 (SSP) A7 (USP) CCR D7-D0 DFC PC SFC SR VBR X N Z V C -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Address registers (Index registers) Supervisor Stack Pointer User Stack Pointer Condition code register (user portion of SR) Data Registers (Index registers) Alternate function code register Program counter Alternate function code register Status register Vector base register Extend indicator Negative indicator Zero indicator Two's complement overflow indicator Carry/borrow indicator NOMENCLATURE 2-2 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Freescale Semiconductor, Inc... 2.3 Pin and Signal Mnemonics ADDR[23:0] AS AVEC BERR BG BGACK BKPT BR CLKOUT CS[10:0] CSBOOT DATA[15:0] DS DSACK[1:0] DSCLK DSI DSO EXTAL FC[2:0] FREEZE HALT IFETCH IPIPE IRQ[7:1] MISO MODCLK MOSI PC[6:0] PCS[3:0] PE[7:0] PF[7:0] PQS[7:0] QUOT R/W RESET RMC RXD SCK SIZ[1:0] SS T2CLK TPUCH[15:0] TSC TXD XFC XTAL MC68332 USER'S MANUAL -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Address Bus Address Strobe Autovector Bus Error Bus Grant Bus Grant Acknowledge Breakpoint Bus Request System Clock Chip Selects Boot ROM Chip Select Data Bus Data Strobe Data and Size Acknowledge Development Serial Clock Development Serial Input Development Serial Output External Crystal Oscillator Connection Function Codes Freeze Halt Instruction Fetch Instruction Pipeline Interrupt Request Master In Slave Out Clock Mode Select Master Out Slave In SIM I/O Port C Peripheral Chip Selects SIM I/O Port E SIM I/O Port F QSM I/O Port Quotient Out Read/Write Reset Read-Modify-Write Cycle SCI Receive Data QSPI Serial Clock Size Slave Select TPU Clock In TPU Channel Signals Three-State Control SCI Transmit Data External Filter Capacitor External Crystal Oscillator Connection NOMENCLATURE For More Information On This Product, Go to: www.freescale.com 2-3 Freescale Semiconductor, Inc. 2.4 Register Mnemonics Freescale Semiconductor, Inc... CFSR[0:3] CIER CISR CPR[0:1] CREG CR[0:F] CSBARBT CSBAR[0:10] CSORBT CSOR[0:10] CSPAR[0:1] DCNR DDRE DDRF DDRQS DREG DSCR DSSR HSQR[0:1] HSRR[0:1] LR PEPAR PFPAR PICR PITR PORTC PORTE PORTF PORTQS PQSPAR QILR QIVR QSMCR QTEST RR[0:F] RSR SCCR[0:1] SCDR SCSR SGLR SIMCR SIMTR SIMTRE SPCR[0:3] SPSR -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Channel Function Select Registers [0:3] Channel Interrupt Enable Register Channel Interrupt Status Register Channel Priority Registers [0:1] Test Control Register C QSM Command RAM Chip-Select Base Address Register Boot ROM Chip-Select Base Address Registers [0:10] Chip-Select Option Register Boot ROM Chip-Select Option Registers [0:10] Chip-Select Pin Assignment Registers [0:1] Decoded Channel Number Register Port E Data Direction Register Port F Data Direction Register Port QS Data Direction Register SIM Test Module Distributed Register Development Support Control Register Development Support Status Register Host Sequence Registers [0:1] Host Service Request Registers [0:1] Link Register Port E Pin Assignment Register Port F Pin Assignment Register Periodic Interrupt Control Register Periodic Interrupt Timer Register Port C Data Register Port E Data Register Port F Data Register Port QS Data Register Port QS Pin Assignment Register QSM Interrupt Level Register QSM Interrupt Vector Register QSM Configuration Register QSM Test Register QSM Receive Data RAM Reset Status Register SCI Control Registers [0:1] SCI Data Register SCI Status Register Service Grant Latch Register SIM Module Configuration Register System Integration Test Register System Integration Test Register (ECLK) QSPI Control Registers [0:3] QSPI Status Register NOMENCLATURE 2-4 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc... Freescale Semiconductor, Inc. SWSR SYNCR SYPCR TCR TICR TPUMCR TRAMBAR TRAMMCR TRAMTST TR[0:F] TSTMSRA TSTMSRB TSTRC TSTSC -- -- -- -- -- -- -- -- -- -- -- -- -- -- Software Watchdog Service Register Clock Synthesizer Control Register System Protection Control Register TPU Test Configuration Register TPU Interrupt Configuration Register TPU Module Configuration Register TPURAM Base Address/Status Register TPURAM Module Configuration Register TPURAM Test Register QSM Transmit Data RAM Test Module Master Shift Register A Test Module Master Shift Register B Test Module Repetition Counter Test Module Shift Count Register 2.5 Conventions Logic level one is the voltage that corresponds to a Boolean true (1) state. Logic level zero is the voltage that corresponds to a Boolean false (0) state. Set refers specifically to establishing logic level one on a bit or bits. Clear refers specifically to establishing logic level zero on a bit or bits. Asserted means that a signal is in active logic state. An active low signal changes from logic level one to logic level zero when asserted, and an active high signal changes from logic level zero to logic level one. Negated means that an asserted signal changes logic state. An active low signal changes from logic level zero to logic level one when negated, and an active high signal changes from logic level one to logic level zero. A specific mnemonic within a range is referred to by mnemonic and number. A15 is bit 15 of accumulator A; ADDR7 is line 7 of the address bus; CSOR0 is chip-select option register 0. A range of mnemonics is referred to by mnemonic and the numbers that define the range. AM[35:30] are bits 35 to 30 of accumulator M; CSOR[0:5] are the first six option registers Parentheses are used to indicate the content of a register or memory location, rather than the register or memory location itself. (A) is the content of accumulator A. (M : M + 1) is the content of the word at address M. LSB means least significant bit or bits. MSB means most significant bit or bits. References to low and high bytes are spelled out. LSW means least significant word or words. MSW means most significant word or words. ADDR is the address bus. ADDR[7:0] are the eight LSB of the address bus. DATA is the data bus. DATA[15:8] are the eight MSB of the data bus. MC68332 USER'S MANUAL NOMENCLATURE For More Information On This Product, Go to: www.freescale.com 2-5 Freescale Semiconductor, Inc... Freescale Semiconductor, Inc. NOMENCLATURE 2-6 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. SECTION 3 OVERVIEW Freescale Semiconductor, Inc... This section contains information about the entire modular microcontroller. It lists the features of each module, shows device functional divisions and pin assignments, summarizes signal and pin functions, discusses the intermodule bus, and provides system memory maps. Timing and electrical specifications for the entire microcontroller and for individual modules are provided in APPENDIX A ELECTRICAL CHARACTERISTICS. Comprehensive module register descriptions and memory maps are provided in APPENDIX D REGISTER SUMMARY. 3.1 MC68332 Features The following paragraphs highlight capabilities of each of the microcontroller modules. Each module is discussed separately in a subsequent section of this user's manual. 3.1.1 System Integration Module (SIM) * External Bus Support * Programmable Chip-Select Outputs * System Protection Logic * Watchdog Timer, Clock Monitor, and Bus Monitor * System Protection Logic * System Clock Based on 32.768-kHz Crystal for Low Power Operation * Test/Debug Submodule for Factory/User Test and Development 3.1.2 Central Processing Unit (CPU) * Upward Object Code Compatible * New Instructions for Controller Applications * 32-Bit Architecture * Virtual Memory Implementation * Loop Mode of Instruction Execution * Table Lookup and Interpolate Instruction * Improved Exception Handling for Controller Applications * Trace on Change of Flow * Hardware Breakpoint Signal, Background Mode * Fully Static Operation 3.1.3 Time Processor Unit (TPU) * Dedicated Microengine Operating Independently of CPU32 * 16 Independent, Programmable Channels and Pins * Any Channel can Perform any Time Function * Two Timer Count Registers with Programmable Prescalers * Selectable Channel Priority Levels MC68332 USER'S MANUAL OVERVIEW For More Information On This Product, Go to: www.freescale.com 3-1 Freescale Semiconductor, Inc. 3.1.4 Queued Serial Module (QSM) * Enhanced Serial Communication Interface (SCI), Universal Asynchronous Receiver Transmitter (UART): Modulus Baud Rate, Parity * Queued Serial Peripheral Interface (SPI): 80-Byte RAM, Up to 16 Automatic Transfers * Dual Function I/O Ports * Continuous Cycling, 8-16 Bits per Transfer Freescale Semiconductor, Inc... 3.1.5 Static RAM Module with TPU Emulation Capability (TPURAM) * 2-Kbytes of Static RAM * May be Used as Normal RAM or TPU Microcode Emulation RAM 3.2 System Block Diagram and Pin Assignment Diagrams Figure 3-1 is a functional diagram of the MCU. Although diagram blocks represent the relative size of the physical modules, there is not a one-to-one correspondence between location and size of blocks in the diagram and location and size of integratedcircuit modules. Figure 3-2 shows the pin assignments of the 132-pin plastic surfacemount package. Figure 3-3 shows the pin assignments of the 144-pin plastic surfacemount package. Refer to APPENDIX B MECHANICAL DATA AND ORDERING INFORMATION for package dimensions. All pin functions and signal names are shown in this drawing. Refer to subsequent paragraphs in this section for pin and signal descriptions. OVERVIEW 3-2 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. VSTBY CHIP SELECTS TPUCH[15:0] TPUCH[15:0] T2CLK FC2 FC1 FC0 2 KBYTES RAM TPU SIZ1 SIZ0 DS AS RMC AVEC DSACK1 DSACK0 EBI RXD PQS7/TXD PQS6/PCS3 PQS5/PCS2 PQS4/PCS1 PQS3/PCS0/SS PQS2/SCK PQS1/MOSI PQS0/MISO PORT QS CONTROL IMB TXD PCS3 PCS2 PCS1 PCS0/SS SCK MOSI MISO DATA[15:0] CONTROL PORT F CPU 32 MODCLK BKPT IFETCH IPIPE DSI DSO DSCLK FREEZE CLOCK R/W RESET HALT BERR PF7/IRQ7 PF6/IRQ6 PF5/IRQ5 PF4/IRQ4 PF3/IRQ3 PF2/IRQ2 PF1/IRQ1 PF0/MODCLK CLKOUT XTAL EXTAL XFC VDDSYN TSC CONTROL BKPT/DSCLK IFETCH/DSI IPIPE/DSO TSC TEST QUOT PE7/SIZ1 PE6/SIZ0 PE5/DS PE4/AS PE3/RMC PE2/AVEC PE1/DSACK1 PE0/DSACK0 DATA[15:0] IRQ[7:1] QSM CSBOOT ADDR23/CS10 PC6/ADDR22/CS9 PC5/ADDR21/CS8 PC4/ADDR20/CS7 PC3/ADDR19/CS6 PC2/FC2/CS5 PC1/FC1/CS4 PC0/FC0/CS3 BGACK/CS2 BG/CS1 BR/CS0 ADDR[18:0] CONTROL PORT E ADDR[23:0] CONTROL Freescale Semiconductor, Inc... ADDR[23:19] T2CLK CONTROL PORT C BR BG BGACK CS[10:0] FREEZE/QUOT 332 BLOCK Figure 3-1 MCU Block Diagram MC68332 USER'S MANUAL OVERVIEW For More Information On This Product, Go to: www.freescale.com 3-3 ADDR23/CS10 PC6/ADDR22/CS9 PC5/ADDR21/CS8 PC4/ADDR20/CS7 PC3/ADDR19/CS6 PC2/FC2/CS5 PC1/FC1/CS4 PC0/FC0/CS3 VSS TPUCH12 TPUCH13 TPUCH14 TPUCH15 T2CLK VSS VDD TPUCH8 TPUCH9 TPUCH10 TPUCH11 VSS VDD TPUCH0 TPUCH1 TPUCH2 TPUCH3 TPUCH4 TPUCH5 TPUCH6 TPUCH7 VSS VDD 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 116 115 114 113 112 111 110 109 108 107 106 105 104 103 102 101 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 MC68332 VDD BGACK/CS2 BG/CS1 BR/CS0 CSBOOT DATA0 DATA1 DATA2 DATA3 VDD VSS DATA4 DATA5 DATA6 DATA7 VSS DATA8 DATA9 DATA10 DATA11 VDD VSS DATA12 DATA13 DATA14 DATA15 ADDR0 PE0/DSACK0 PE1/DSACK1 PE2/AVEC PE3/RMC PE5/DS VDD EXTAL VDD XFC VDD CLKOUT VSS RESET HALT BERR PF7/IRQ7 PF6/IRQ6 PF5/IRQ5 PF4/IRQ4 PF3/IRQ3 PF2/IRQ2 PF1/IRQ1 PF0/MODCLK R/W PE7/SIZ1 PE6/SIZ0 AS VSS 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 VDD VSTBY ADDR1 ADDR2 ADDR3 ADDR4 ADDR5 ADDR6 ADDR7 ADDR8 VDD VSS ADDR9 ADDR10 ADDR11 ADDR12 VSS ADDR13 ADDR14 ADDR15 ADDR16 VDD VSS ADDR17 ADDR18 PQS0/MISO PQS1/MOSI PQS2/SCK PQS3/PCS0/SS PQS4/PCS1 PQS5/PCS2 PQS6/PCS3 VDD VSS PQS7/TXD RXD IPIPE/DSO IFETCH/DSI BKPT/DSCLK TSC FREEZE/QUOT VSS XTAL VDDSYN Freescale Semiconductor, Inc... 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 132 131 130 129 128 127 126 125 124 123 122 121 120 119 118 117 VSS Freescale Semiconductor, Inc. 332 132-PIN QFP Figure 3-2 Pin Assignments for 132-Pin Package OVERVIEW 3-4 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL 144 143 142 141 140 139 138 137 136 135 134 133 132 131 130 129 128 127 126 125 124 123 122 121 120 119 118 117 116 115 114 113 112 111 110 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 MC68332 109 108 107 106 105 104 103 102 101 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 75 74 73 NC VSS PE4/AS PE6/SIZ0 PE7/SIZ1 R/W PF0/MODCLK PF1/IRQ1 PF2/IRQ2 PF3/IRQ3 PF4/IRQ4 PF5/IRQ5 PF6/IRQ6 PF7/IRQ7 BERR HALT RESET VSS CLKOUT VDD NC XFC VDD EXTAL VDD XTAL VSS FREEZE/QUOT TSC BKPT/DSCLK IFETCH/DSI IPIPE/DSO RXD PQS7/TXD VSS NC 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 NC VSS FC0/CS3 FC1/CS4 FC2/CS5 ADDR19/CS6 ADDR20/CS7 ADDR21/CS8 ADDR22/CS9 ADDR23/CS10 VDD VSS T2CLK TPUCH15 TPUCH14 TPUCH13 TPUCH12 NC VDD VSS TPUCH11 TPUCH10 TPUCH9 TPUCH8 VDDE VSSE TPUCH7 TPUCH6 TPUCH5 TPUCH4 TPUCH3 TPUCH2 TPUCH1 TPUCH0 VSS NC VDD VSTBY ADDR1 ADDR2 ADDR3 ADDR4 ADDR5 ADDR6 ADDR7 ADDR8 VDD VSS ADDR9 ADDR10 ADDR11 ADDR12 NC VSS NC ADDR13 ADDR14 ADDR15 NC ADDR16 VDD VSS ADDR17 ADDR18 PQS0/MISO PQS1/MOSI PQS2/SCK PQS3/PCS0/SS PQS4/PCS1 PQS5/PCS2 PQS6/PCS3 VDD Freescale Semiconductor, Inc... VDD BGACK/CS2 BG/CS1 BR/CS0 CSBOOT DATA0 DATA1 DATA2 DATA3 VDD VSS DATA4 DATA5 DATA6 DATA7 NC VSS DATA8 NC DATA9 DATA10 NC DATA11 VDD VSS DATA12 DATA13 DATA14 DATA15 ADDR0 PE0/DSACK0 PE1/DSACK1 PE2/AVEC PE3/RMC PE5/DS VDD Freescale Semiconductor, Inc. 332 144-PIN QFP Figure 3-3 Pin Assignments for 144-Pin Package 3.3 Pin Descriptions The following tables summarize functional characteristics of MCU pins. Table 3-1 shows types of output drivers. Table 3-2 shows all inputs and outputs. Digital inputs and outputs use CMOS logic levels. An entry in the Discrete I/O column indicates that a pin can also be used for general-purpose input, output, or both. The I/O port designation is given when it applies. Table 3-3 shows characteristics of power pins. Refer to Figure 3-1 for port organization. MC68332 USER'S MANUAL OVERVIEW For More Information On This Product, Go to: www.freescale.com 3-5 Freescale Semiconductor, Inc. Table 3-1 MCU Driver Types Type A Aw B I/O O O O Bo O Description Output-only signals that are always driven; no external pull-up required Type A output with weak P-channel pull-up during reset Three-state output that includes circuitry to pull up output before high impedance is established, to ensure rapid rise time. An external holding resistor is required to maintain logic level while the pin is in the high-impedance state. Type B output that can be operated in an open-drain mode Table 3-2 MCU Pin Characteristics Freescale Semiconductor, Inc... Pin Mnemonic ADDR23/CS10/ECLK ADDR[22:19]/CS[9:6] ADDR[18:0] AS AVEC BERR BG/CS1 BGACK/CS2 BKPT/DSCLK BR/CS0 CLKOUT CSBOOT DATA[15:0]1 DS DSACK1 DSACK0 DSI/IFETCH DSO/IPIPE EXTAL2 FC[2:0]/CS[5:3] FREEZE/QUOT HALT IRQ[7:1] MISO MODCLK1 MOSI PCS0/SS PCS[3:1] R/W RESET RMC RXD SCK SIZ[1:0] T2CLK TPUCH[15:0] TSC Output Driver A A A B B B B B -- B A B Aw Input Synchronized Y Y Y Y Y Y -- Y Y Y -- -- Y Input Hysteresis N N N N N N -- N Y N -- -- N Discrete I/O O O -- I/O I/O -- -- -- -- -- -- -- -- Port Designation -- PC[6:3] -- PE5 PE2 -- -- -- -- -- -- -- -- B B B A A -- Y Y Y Y -- -- N N N Y -- Special I/O I/O I/O -- -- -- PE4 PE1 PE0 -- -- -- A A Bo B Bo B Y -- Y Y Y Y N -- N Y Y N O -- -- I/O I/O I/O PC[2:0] -- -- PF[7:1] PQS0 PF0 Bo Bo Bo A Bo B -- Bo B -- A -- Y Y Y Y Y Y N Y Y Y Y Y Y Y Y N Y N N Y N Y Y Y I/O I/O I/O -- -- I/O -- I/O I/O -- -- -- PQS1 PQS3 PQS[6:4] -- -- PE3 -- PQS2 PE[7:6] -- -- -- OVERVIEW 3-6 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Table 3-2 MCU Pin Characteristics (Continued) Pin Mnemonic TXD XFC2 Output Driver Bo -- Input Synchronized Y -- Input Hysteresis Y -- Discrete I/O I/O Special Port Designation PQS7 -- XTAL2 -- -- -- Special -- NOTES: 1. DATA[15:0] are synchronized during reset only. MODCLK is synchronized only when used as an input port pin. 2. EXTAL, XFC, and XTAL are clock reference connections. Table 3-3 MCU Power Connections Freescale Semiconductor, Inc... Pin Mnemonic VSTBY Description Standby RAM Power VDDSYN Clock Synthesizer Power VSSE/VDDE External Periphery Power (Source and Drain) VSSI/VDDI Internal Module Power (Source and Drain) 3.4 Signal Descriptions The following tables define MCU signals. Table 3-4 shows signal origin, type, and active state. Table 3-5 describes signal functions. Both tables are sorted alphabetically by mnemonic. MCU pins often have multiple functions. More than one description can apply to a pin. Table 3-4 MCU Signal Characteristics Signal Name ADDR[23:0] AS AVEC BERR BG BGACK BKPT BR CLKOUT CS[10:0] CSBOOT DATA[15:0] DS DSACK[1:0] DSCLK DSI DSO EXTAL FC[2:0] FREEZE HALT MC68332 USER'S MANUAL MCU Module SIM SIM SIM SIM SIM SIM CPU32 SIM SIM SIM SIM SIM SIM SIM CPU32 CPU32 CPU32 SIM SIM SIM SIM Signal Type Bus Output Input Input Output Input Input Input Output Output Output Bus Output Input Input Input Output Input Output Output Input/Output Active State -- 0 0 0 0 0 0 0 -- 0 0 -- 0 0 Serial Clock (Serial Data) (Serial Data) -- -- 1 0 OVERVIEW For More Information On This Product, Go to: www.freescale.com 3-7 Freescale Semiconductor, Inc. Freescale Semiconductor, Inc... Table 3-4 MCU Signal Characteristics (Continued) Signal Name IFETCH IPIPE IRQ[7:1] MISO MODCLK MOSI PC[6:0] PCS[3:0] PE[7:0] PF[7:0] PQS[7:0] QUOT RESET RMC R/W RXD SCK SIZ[1:0] SS T2CLK TPUCH[15:0] TSC TXD XFC XTAL MCU Module CPU32 CPU32 SIM QSM SIM QSM SIM QSM SIM SIM QSM SIM SIM SIM SIM QSM QSM SIM QSM TPU TPU SIM QSM SIM SIM Signal Type Output Output Input Input/Output Input Input/Output Output Input/Output Input/Output Input/Output Input/Output Output Input/Output Output Output Input Input/Output Output Input Input Input/Output Input Output Input Output Active State -- -- 0 -- -- -- (Port) -- (Port) (Port) (Port) -- 0 0 1/0 -- -- -- 0 -- 1 -- -- -- -- Table 3-5 MCU Signal Function Signal Name Address Bus Address Strobe Autovector Bus Error Bus Grant Bus Grant Acknowledge Breakpoint Bus Request System Clockout Chip Selects Boot Chip Select Data Bus Data Strobe Data and Size Acknowledge Development Serial In, Out, Clock Crystal Oscillator Mnemonic ADDR[23:0] AS AVEC BERR BG BGACK BKPT BR CLKOUT CS[10:0] CSBOOT DATA[15:0] DS Function 24-bit address bus Indicates that a valid address is on the address bus Requests an automatic vector during interrupt acknowledge Indicates that a bus error has occurred Indicates that the MCU has relinquished the bus Indicates that an external device has assumed bus mastership Signals a hardware breakpoint to the CPU Indicates that an external device requires bus mastership System clock output Select external devices at programmed addresses Chip select for external boot start-up ROM 16-bit data bus During a read cycle, indicates when it is possible for an external device to place data on the data bus. During a write cycle, indicates that valid data is on the data bus. Provide asynchronous data transfers and dynamic bus sizing Serial I/O and clock for background debugging mode DSACK[1:0] DSI, DSO, DSCLK EXTAL, XTAL Connections for clock synthesizer circuit reference; a crystal or an external oscillator can be used OVERVIEW 3-8 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Table 3-5 MCU Signal Function (Continued) Freescale Semiconductor, Inc... Signal Name Function Codes Freeze Halt Instruction Pipeline Interrupt Request Level Master In Slave Out Mnemonic FC[2:0] FREEZE HALT IPIPE, IFETCH IRQ[7:1] MISO Clock Mode Select Master Out Slave In MODCLK MOSI Port C Auxiliary Timer Clock Input Peripheral Chip Select Port E Port F Port QS Quotient Out Reset Read-Modify-Write Cycle Read/Write SCI Receive Data QSPI Serial Clock PC[6:0] PCLK PCS[3:0] PE[7:0] PF[7:0] PQS[7:0] QUOT RESET RMC R/W RXD SCK Size Slave Select SIZ[1:0] SS TCR2 Clock TPU Channel Pins Three-State Control SCI Transmit Data External Filter Capacitor T2CLK TPUCH[15:0] TSC TXD XFC Function Identify processor state and current address space Indicates that the CPU has entered background mode Suspend external bus activity Indicate instruction pipeline activity Provides an interrupt priority level to the CPU Serial input to QSPI in master mode; serial output from QSPI in slave mode Selects the source and type of system clock Serial output from QSPI in master mode; serial input to QSPI in slave mode SIM digital output port signals External clock dedicated to the GPT QSPI peripheral chip selects SIM digital I/O port signals SIM digital I/O port signals QSM digital I/O port signals Provides the quotient bit of the polynomial divider System reset Indicates an indivisible read-modify-write instruction Indicates the direction of data transfer on the bus Serial input to the SCI Clock output from QSPI in master mode; clock input to QSPI in slave mode Indicates the number of bytes to be transferred during a bus cycle Causes serial transmission when QSPI is in slave mode; causes mode fault in master mode External clock source for TCR2 counter Bidirectional pins associated with TPU channels Places all output drivers in a high-impedance state Serial output from the SCI Connection for external phase-locked loop filter capacitor 3.5 Intermodule Bus The intermodule bus (IMB) is a standardized bus developed to facilitate both design and operation of modular microcontrollers. It contains circuitry to support exception processing, address space partitioning, multiple interrupt levels, and vectored interrupts. The standardized modules in the MCU communicate with one another and with external components through the IMB. The IMB in the MCU uses 24 address and 16 data lines. 3.6 System Memory Map Figure 3-4 through Figure 3-8 are MCU memory maps. Figure 3-4 shows IMB addresses of internal registers. Figure 3-5 through Figure 3-8 show system memory maps that use different external decoding schemes. MC68332 USER'S MANUAL OVERVIEW For More Information On This Product, Go to: www.freescale.com 3-9 Freescale Semiconductor, Inc. 3.6.1 Internal Register Map In Figure 3-4, IMB ADDR[23:20] are represented by the letter Y. The value represented by Y determines the base address of MCU module control registers. In M68300 microcontrollers, Y is equal to M111, where M is the logic state of the module mapping (MM) bit in the system integration module configuration register (SIMCR). $YFF000 $YFFA00 $YFFA80 Freescale Semiconductor, Inc... $YFFB00 $YFFB40 SIM RESERVED TPURAM CONTROL RESERVED 2-KBYTE TPURAM ARRAY $YFFC00 QSM $YFFE00 TPU $YFFFFF 332 ADDRESS MAP Figure 3-4 Internal Register Memory Map 3.6.2 Address Space Maps Figure 3-5 shows a single memory space. Function codes FC[2:0] are not decoded externally so that separate user/supervisor or program/data spaces are not provided. In Figure 3-6, FC2 is decoded, resulting in separate supervisor and user spaces. FC[1:0] are not decoded, so that separate program and data spaces are not provided. In Figure 3-7 and Figure 3-8, FC[2:0] are decoded, resulting in four separate memory spaces: supervisor/program, supervisor/data, user/program and user/data. All exception vectors are located in supervisor data space, except the reset vector, which is located in supervisor program space. Only the initial reset vector is fixed in the processor's memory map. Once initialization is complete, there are no fixed assignments. Since the vector base register (VBR) provides the base address of the vector table, the vector table can be located anywhere in memory. Refer to SECTION 5 CENTRAL PROCESSING UNIT for more information concerning memory management, extended addressing, and exception processing. Refer to SECTION 4 SYSTEM INTEGRATION MODULE for more information concerning function codes and address space types. OVERVIEW 3-10 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. $000000 VECTOR VECTOR OFFSET NUMBER 0 0000 1 0004 2 0008 3 000C 4 0010 5 0014 6 0018 7 001C 8 0020 9 0024 10 0028 11 002C 12 0030 13 0034 14 0038 15 003C 0040-005C 16-23 24 006C 25 0064 26 0068 27 006C 28 0070 29 0074 30 0078 31 007C 0080-00BC 32-47 00C0-00EB 48-58 00EC-00FC 59-63 0100-03FC 64-255 Freescale Semiconductor, Inc... COMBINED SUPERVISOR AND USER SPACE TYPE OF EXCEPTION RESET -- INITIAL STACK POINTER RESET -- INITIAL PC BUS ERROR ADDRESS ERROR ILLEGAL INSTRUCTION ZERO DIVISION CHK, CHK2 INSTRUCTIONS TRAPcc, TRAPV INSTRUCTIONS PRIVILEGE VIOLATION TRACE LINE 1010 EMULATOR LINE 1111 EMULATOR HARDWARE BREAKPOINT (RESERVED COPROCESSOR PROTOCOL VIOLATION) FORMAT ERROR AND UNINITIALIZED INTERRUPT FORMAT ERROR AND UNINITIALIZED INTERRUPT (UNASSIGNED, RESERVED) SPURIOUS INTERRUPT LEVEL 1 INTERRUPT AUTOVECTOR LEVEL 2 INTERRUPT AUTOVECTOR LEVEL 3 INTERRUPT AUTOVECTOR LEVEL 4 INTERRUPT AUTOVECTOR LEVEL 5 INTERRUPT AUTOVECTOR LEVEL 6 INTERRUPT AUTOVECTOR LEVEL 7 INTERRUPT AUTOVECTOR TAP INSTRUCTION VECTORS (0-15) (RESERVED, COPROCESSOR) (UNASSIGNED, RESERVED) USER-DEFINED VECTORS $XX0000 $XX03FC $YFF000 $YFFA00 SIM $7FF000 INTERNAL REGISTERS (MM = 0) RESERVED $YFFA80 TPURAM CTL $YFFB00 RESERVED $YFFB40 $YFFC00 QSM $YFFE00 TPU $FF0000 INTERNAL REGISTERS (MM = 1) $YFFFFF $FFFFFF NOTES: 1. Location of the exception vector table is determined by the vector base register. The vector address is the sum of the vector base register and the vector offset. 2. Location of the module control registers is determined by the state of the module mapping (MM) bit in the SIM configure register. Y = M111, where M is the state of the MM bit. 3. Unused addresses within the internal register block are mapped externally. "RESERVED" blocks are not mapped externally. 332 S/U COMB MAP Figure 3-5 Overall Memory Map MC68332 USER'S MANUAL OVERVIEW For More Information On This Product, Go to: www.freescale.com 3-11 Freescale Semiconductor, Inc. $000000 Freescale Semiconductor, Inc... SUPERVISOR SPACE VECTOR VECTOR OFFSET NUMBER 0 0000 1 0004 2 0008 3 000C 4 0010 5 0014 6 0018 7 001C 8 0020 9 0024 10 0028 11 002C 12 0030 13 0034 14 0038 15 003C 0040-005C 16-23 24 006C 25 0064 26 0068 27 006C 28 0070 29 0074 30 0078 31 007C 0080-00BC 32-47 00C0-00EB 48-58 00EC-00FC 59-63 0100-03FC 64-255 TYPE OF EXCEPTION RESET -- INITIAL STACK POINTER RESET -- INITIAL PC BUS ERROR ADDRESS ERROR ILLEGAL INSTRUCTION ZERO DIVISION CHK, CHK2 INSTRUCTIONS TRAPcc, TRAPV INSTRUCTIONS PRIVILEGE VIOLATION TRACE LINE 1010 EMULATOR LINE 1111 EMULATOR HARDWARE BREAKPOINT (RESERVED COPROCESSOR PROTOCOL VIOLATION) FORMAT ERROR AND UNINITIALIZED INTERRUPT FORMAT ERROR AND UNINITIALIZED INTERRUPT (UNASSIGNED, RESERVED) SPURIOUS INTERRUPT LEVEL 1 INTERRUPT AUTOVECTOR LEVEL 2 INTERRUPT AUTOVECTOR LEVEL 3 INTERRUPT AUTOVECTOR LEVEL 4 INTERRUPT AUTOVECTOR LEVEL 5 INTERRUPT AUTOVECTOR LEVEL 6 INTERRUPT AUTOVECTOR LEVEL 7 INTERRUPT AUTOVECTOR TAP INSTRUCTION VECTORS (0-15) (RESERVED, COPROCESSOR) (UNASSIGNED, RESERVED) USER-DEFINED VECTORS $000000 $XX0000 USER SPACE $XX03FC $YFF000 $YFFA00 SIM $7FF000 INTERNAL REGISTERS INTERNAL REGISTERS RESERVED $YFFA80 TPURAM CTL $YFFB00 RESERVED $YFFB40 $7FF0004 $YFFC00 QSM $YFFE00 TPU $FF0000 $FFFFFF INTERNAL REGISTERS $YFFFFF INTERNAL REGISTERS $FF00004 $FFFFFF NOTES: 1. Location of the exception vector table is determined by the vector base register. The vector address is the sum of the vector base register and the vector offset. 2. Location of the module control registers is determined by the state of the module mapping (MM) bit in the SIM configure register. Y = M111, where M is the state of the MM bit. 3. Unused addresses within the internal register block are mapped externally. "RESERVED" blocks are not mapped externally. 4. Some internal registers are not available in user space. 332 S/U SEP MAP Figure 3-6 Separate Supervisor and User Space Map OVERVIEW 3-12 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. VECTOR OFFSET 0000 0004 Freescale Semiconductor, Inc... $000000 SUPERVISOR DATA SPACE VECTOR NUMBER 0 1 VECTOR VECTOR OFFSET NUMBER 0 0000 1 0004 2 0008 3 000C 4 0010 5 0014 6 0018 7 001C 8 0020 9 0024 10 0028 11 002C 12 0030 13 0034 14 0038 15 003C 0040-005C 16-23 24 006C 25 0064 26 0068 27 006C 28 0070 29 0074 30 0078 31 007C 0080-00BC 32-47 00C0-00EB 48-58 00EC-00FC 59-63 0100-03FC 64-255 EXCEPTION VECTORS LOCATED IN SUPERVISOR PROGRAM SPACE RESET -- INITIAL STACK POINTER RESET -- INITIAL PC EXCEPTION VECTORS LOCATED IN SUPERVISOR DATA SPACE RESET -- INITIAL STACK POINTER RESET -- INITIAL PC BUS ERROR ADDRESS ERROR ILLEGAL INSTRUCTION ZERO DIVISION CHK, CHK2 INSTRUCTIONS TRAPcc, TRAPV INSTRUCTIONS PRIVILEGE VIOLATION TRACE LINE 1010 EMULATOR LINE 1111 EMULATOR HARDWARE BREAKPOINT (RESERVED COPROCESSOR PROTOCOL VIOLATION) FORMAT ERROR AND UNINITIALIZED INTERRUPT FORMAT ERROR AND UNINITIALIZED INTERRUPT (UNASSIGNED, RESERVED) SPURIOUS INTERRUPT LEVEL 1 INTERRUPT AUTOVECTOR LEVEL 2 INTERRUPT AUTOVECTOR LEVEL 3 INTERRUPT AUTOVECTOR LEVEL 4 INTERRUPT AUTOVECTOR LEVEL 5 INTERRUPT AUTOVECTOR LEVEL 6 INTERRUPT AUTOVECTOR LEVEL 7 INTERRUPT AUTOVECTOR TAP INSTRUCTION VECTORS (0-15) (RESERVED, COPROCESSOR) (UNASSIGNED, RESERVED) USER-DEFINED VECTORS $000000 $XX0000 $XX0004 $XX0000 SUPERVISOR PROGRAM SPACE $XX03FC $YFF000 $YFFA00 SIM $7FF000 INTERNAL REGISTERS RESERVED $YFFA80 TPURAM CTL $YFFB00 RESERVED $YFFB40 $YFFC00 QSM $YFFE00 TPU $FF0000 INTERNAL REGISTERS $FFFFFF $YFFFFF $FFFFFF NOTES: 1. Location of the exception vector table is determined by the vector base register. The vector address is the sum of the vector base register and the vector offset. 2. Location of the module control registers is determined by the state of the module mapping (MM) bit in the SIM configure register. Y = M111, where M is the state of the MM bit. 3. Unused addresses within the internal register block are mapped externally. "RESERVED" blocks are not mapped externally. 4. Some internal registers are not available in user space. 332 SUPER P/D MAP Figure 3-7 Supervisor Space (Separate Program/Data Space) Map MC68332 USER'S MANUAL OVERVIEW For More Information On This Product, Go to: www.freescale.com 3-13 Freescale Semiconductor, Inc. $000000 $000000 Freescale Semiconductor, Inc... USER PROGRAM SPACE USER DATA SPACE $YFF000 $YFFA00 SIM $7FF000 INTERNAL REGISTERS RESERVED $YFFA80 TPURAM CTL $YFFB00 RESERVED $YFFB40 $YFFC00 QSM $YFFE00 TPU $FF0000 $FFFFFF INTERNAL REGISTERS $FFFFFF $YFFFFF NOTES: 1. Location of the exception vector table is determined by the vector base register. The vector address is the sum of the vector base register and the vector offset. 2. Unused addresses within the internal register block are mapped externally. "RESERVED" blocks are not mapped externally. 3. Some internal registers are not available in user space. 332 USER P/D MAP Figure 3-8 User Space (Separate Program/Data Space) Map OVERVIEW 3-14 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. 3.7 System Reset The following information is a concise reference only. MC68332 system reset is a complex operation. To understand operation during and after reset, refer to SECTION 4 SYSTEM INTEGRATION MODULE, paragraph 4.6 Reset for more complete discussion of the reset function. 3.7.1 SIM Reset Mode Selection The logic states of certain data bus pins during reset determine SIM operating configuration. In addition, the state of the MODCLK pin determines system clock source and the state of the BKPT pin determines what happens during subsequent breakpoint assertions. Table 3-6 is a summary of reset mode selection options. Freescale Semiconductor, Inc... Table 3-6 SIM Reset Mode Selection Mode Select Pin DATA0 DATA1 DATA2 DATA3 DATA4 DATA5 DATA6 DATA7 DATA8 DATA9 DATA11 MODCLK BKPT MC68332 USER'S MANUAL Default Function (Pin Left High) CSBOOT 16-Bit CS0 CS1 CS2 CS3 CS4 CS5 CS6 CS[7:6] CS[8:6] CS[9:6] CS[10:6] DSACK0, DSACK1, AVEC, DS, AS, SIZ[1:0] IRQ[7:1] MODCLK Test Mode Disabled VCO = System Clock Background Mode Disabled Alternate Function (Pin Pulled Low) CSBOOT 8-Bit BR BG BGACK FC0 FC1 FC2 ADDR19 ADDR[20:19] ADDR[21:19] ADDR[22:19] ADDR[23:19] PORTE PORTF Test Mode Enabled EXTAL = System Clock Background Mode Enabled OVERVIEW For More Information On This Product, Go to: www.freescale.com 3-15 Freescale Semiconductor, Inc. 3.7.2 MCU Module Pin Function During Reset Generally, pins associated with modules other than the SIM default to port functions, and input/output ports are set to input state. This is accomplished by disabling pin functions in the appropriate control registers, and by clearing the appropriate port data direction registers. Refer to individual module sections in this manual for more information. Table 3-7 is a summary of module pin function out of reset. Table 3-7 Module Pin Functions Module CPU32 Freescale Semiconductor, Inc... TPU QSM Pin Mnemonic DSI/IFETCH DSO/IPIPE BKPT/DSCLK TPUCH[15:0] T2CLK PQS7/TXD PQS[6:4]/PCS[3:1] PQS3/PCS0/SS PQS2/SCK PQS1/MOSI PQS0/MISO RXD Function DSI/IFETCH DSO/IPIPE BKPT/DSCLK TPU Input TCR2 Clock Discrete Input Discrete Input Discrete Input Discrete Input Discrete Input Discrete Input RXD OVERVIEW 3-16 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. SECTION 4 SYSTEM INTEGRATION MODULE This section is an overview of SIM function. Refer to the SIM Reference Manual (SIMRM/AD) for a comprehensive discussion of SIM capabilities. Refer to APPENDIX D REGISTER SUMMARY for information concerning the SIM address map and register structure. Freescale Semiconductor, Inc... 4.1 General The system integration module (SIM) consists of five functional blocks. Figure 4-1 is a block diagram of the SIM. The system configuration and protection block controls configuration parameters and provides bus and software watchdog monitors. In addition, it provides a periodic interrupt generator to support execution of time-critical control routines. The system clock generates clock signals used by the SIM, other IMB modules, and external devices. The external bus interface handles the transfer of information between IMB modules and external address space. EBI pins can also be configured for use as general-purpose I/O ports E and F. The chip-select block provides 12 chip-select signals. Each chip-select signal has an associated base register and option register that contain the programmable characteristics of that chip select. Chip-select pins can also be configured for use as generalpurpose output port C. The system test block incorporates hardware necessary for testing the MCU. It is used to perform factory tests, and its use in normal applications is not supported. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-1 Freescale Semiconductor, Inc. SYSTEM CONFIGURATION AND PROTECTION CLOCK SYNTHESIZER Freescale Semiconductor, Inc... CHIP SELECTS CLKOUT EXTAL MODCLK CHIP SELECTS EXTERNAL BUS EXTERNAL BUS INTERFACE RESET FACTORY TEST TSC FREEZE/QUOT S(C)IM BLOCK Figure 4-1 System Integration Module Block Diagram 4.2 System Configuration and Protection The system configuration and protection functional block controls module configuration, preserves reset status, monitors internal activity, and provides periodic interrupt generation. Figure 4-2 is a block diagram of the submodule. SYSTEM INTEGRATION MODULE 4-2 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. MODULE CONFIGURATION AND TEST Freescale Semiconductor, Inc... RESET STATUS HALT MONITOR RESET REQUEST BUS MONITOR BERR SPURIOUS INTERRUPT MONITOR SOFTWARE WATCHDOG TIMER CLOCK RESET REQUEST 29 PRESCALER PERIODIC INTERRUPT TIMER IRQ [7:1] SYS PROTECT BLOCK Figure 4-2 System Configuration and Protection 4.2.1 Module Mapping Control registers for all the modules in the microcontroller are mapped into a 4-Kbyte block. The state of the module mapping bit (MM) in the SIM configuration register (SIMCR) determines where the control register block is located in the system memory map. When MM = 0, register addresses range from $7FF000 to $7FFFFF; when MM = 1, register addresses range from $FFF000 to $FFFFFF. 4.2.2 Interrupt Arbitration Each module that can generate interrupt requests has an interrupt arbitration (IARB) field. Arbitration between interrupt requests of the same priority is performed by serial contention between IARB field bit values. Contention must take place whenever an inMC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-3 Freescale Semiconductor, Inc. terrupt request is acknowledged, even when there is only a single request pending. For an interrupt to be serviced, the appropriate IARB field must have a non-zero value. If an interrupt request from a module with an IARB field value of %0000 is recognized, the CPU32 processes a spurious interrupt exception. Freescale Semiconductor, Inc... Because the SIM routes external interrupt requests to the CPU32, the SIM IARB field value is used for arbitration between internal and external interrupts of the same priority. The reset value of IARB for the SIM is %1111, and the reset IARB value for all other modules is %0000, which prevents SIM interrupts from being discarded during initialization. Refer to 4.7 Interrupts for a discussion of interrupt arbitration. 4.2.3 Show Internal Cycles A show cycle allows internal bus transfers to be monitored externally. The SHEN field in the SIMCR determines what the external bus interface does during internal transfer operations. Table 4-1 shows whether data is driven externally, and whether external bus arbitration can occur. Refer to 4.5.6.2 Show Cycles for more information. Table 4-1 Show Cycle Enable Bits SHEN 00 01 10 11 Action Show cycles disabled, external arbitration enabled Show cycles enabled, external arbitration disabled Show cycles enabled, external arbitration enabled Show cycles enabled, external arbitration enabled; internal activity is halted by a bus grant 4.2.4 Factory Test Mode The internal IMB can serve as slave to an external master for direct module testing. This test mode is reserved for factory test. Slave mode is enabled by holding DATA11 low during reset. The slave enabled (SLVEN) bit is a read-only bit that shows the reset state of DATA11. 4.2.5 Register Access The CPU32 can operate at either of two privilege levels. Supervisor level is more privileged than user level -- all instructions and system resources are available at supervisor level, but access is restricted at user level. Effective use of privilege level can protect system resources from uncontrolled access. The state of the S bit in the CPU status register determines access level, and whether the user or supervisor stack pointer is used for stacking operations. The SUPV bit places SIM global registers in either supervisor or user data space. When SUPV = 0, registers with controlled access are accessible from either the user or supervisor privilege level; when SUPV = 1, registers with controlled access are restricted to supervisor access only. 4.2.6 Reset Status The reset status register (RSR) latches internal MCU status during reset. Refer to 4.6.9 Reset Status Register for more information. SYSTEM INTEGRATION MODULE 4-4 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. 4.2.7 Bus Monitor The internal bus monitor checks data and size acknowledge (DSACK) or autovector (AVEC) signal response times during normal bus cycles. The monitor asserts the internal bus error (BERR) signal when the response time is excessively long. DSACK and AVEC response times are measured in clock cycles. Maximum allowable response time can be selected by setting the bus monitor timing (BMT) field in the system protection control register (SYPCR). Table 4-2 shows the periods allowed. Freescale Semiconductor, Inc... Table 4-2 Bus Monitor Period BMT 00 01 10 11 Bus Monitor Time-out Period 64 System Clocks 32 System Clocks 16 System Clocks 8 System Clocks The monitor does not check DSACK response on the external bus unless the CPU32 initiates a bus cycle. The BME bit in SYPCR enables the internal bus monitor for internal to external bus cycles. If a system contains external bus masters, an external bus monitor must be implemented and the internal-to-external bus monitor option must be disabled. When monitoring transfers to an 8-bit port, the bus monitor does not reset until both byte accesses of a word transfer are completed. Monitor time-out period must be at least twice the number of clocks that a single byte access requires. 4.2.8 Halt Monitor The halt monitor responds to an assertion of the HALT signal on the internal bus. Refer to 4.5.5.2 Double Bus Faults for more information. Halt monitor reset can be inhibited by the halt monitor (HME) bit in SYPCR. 4.2.9 Spurious Interrupt Monitor During interrupt exception processing, the CPU32 normally acknowledges an interrupt request, recognizes the highest priority source, and then acquires a vector or responds to a request for autovectoring. The spurious interrupt monitor asserts the internal bus error signal (BERR) if no interrupt arbitration occurs during interrupt exception processing. The assertion of BERR causes the CPU32 to load the spurious interrupt exception vector into the program counter. The spurious interrupt monitor cannot be disabled. Refer to 4.7 Interrupts for further information. For detailed information about interrupt exception processing, refer to SECTION 5 CENTRAL PROCESSING UNIT. 4.2.10 Software Watchdog The software watchdog is controlled by the software watchdog enable (SWE) bit in SYPCR. When enabled, the watchdog requires that a service sequence be written to software service register SWSR on a periodic basis. If servicing does not take place, the watchdog times out and asserts the reset signal. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-5 Freescale Semiconductor, Inc. Perform a software watchdog service sequence as follows: 1. Write $55 to SWSR. 2. Write $AA to SWSR. Both writes must occur before time-out in the order listed, but any number of instructions can be executed between the two writes. Watchdog clock rate is affected by the software watchdog prescale (SWP) and software watchdog timing (SWT) fields in SYPCR. Freescale Semiconductor, Inc... SWP determines system clock prescaling for the watchdog timer and determines that one of two options, either no prescaling or prescaling by a factor of 512, can be selected. The value of SWP is affected by the state of the MODCLK pin during reset, as shown in Table 4-3. System software can change SWP value. Table 4-3 MODCLK Pin and SWP Bit During Reset MODCLK 0 (External Clock) 1 (Internal Clock) SWP 1 (/ 512) 0 (/ 1) The SWT field selects the divide ratio used to establish software watchdog time-out period. Time-out period is given by the following equations. 1 Time-out Period = ------------------------------------------------------------------------------------EXTAL Frequency Divide Ratio or Divide Ratio Time-out Period = ------------------------------------------------EXTAL Frequency Table 4-4 shows the ratio for each combination of SWP and SWT bits. When SWT[1:0] are modified, a watchdog service sequence must be performed before the new timeout period can take effect. Table 4-4 Software Watchdog Ratio SWP 0 SWT 00 Ratio 0 01 211 0 10 213 0 11 215 1 00 218 1 01 220 1 10 222 1 11 224 29 Figure 4-3 is a block diagram of the watchdog timer and the clock control for the periodic interrupt timer. SYSTEM INTEGRATION MODULE 4-6 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. PITR SWP PTP FREEZE EXTAL CLOCK DISABLE PRESCALER (29) CLOCK PRECLK MUX /4 PITCLK 8-BIT MODULUS COUNTER PIT INTERRUPT RESET SWCLK LPSTOP SWT1 SWT0 SWE 15 STAGE DIVIDER CHAIN (215) Freescale Semiconductor, Inc... 29 211 213 215 PIT BLOCK Figure 4-3 Periodic Interrupt Timer and Software Watchdog Timer 4.2.11 Periodic Interrupt Timer The periodic interrupt timer allows the generation of interrupts of specific priority at predetermined intervals. This capability is often used to schedule control system tasks that must be performed within time constraints. The timer consists of a prescaler, a modulus counter, and registers that determine interrupt timing, priority and vector assignment. Refer to SECTION 5 CENTRAL PROCESSING UNIT for further information about interrupt exception processing. The periodic interrupt modulus counter is clocked by a signal derived from the buffered crystal oscillator (EXTAL) input pin unless an external frequency source is used. The value of the periodic timer prescaler (PTP) bit in the periodic interrupt timer register (PITR) determines system clock prescaling for the watchdog timer. One of two options, either no prescaling, or prescaling by a factor of 512, can be selected. The value of PTP is affected by the state of the MODCLK pin during reset, as shown in Table 45. System software can change PTP value. Table 4-5 MODCLK Pin and PTP Bit at Reset MODCLK 0 (External Clock) 1 (Internal Clock) PTP 1 (/ 512) 0 (/ 1) Either clock signal (EXTAL or EXTAL / 512) is divided by four before driving the modulus counter (PITCLK). The modulus counter is initialized by writing a value to the periodic timer modulus (PITM) field in the PITR. A zero value turns off the periodic timer. When the modulus counter value reaches zero, an interrupt is generated. The modulus counter is then reloaded with the value in PITM and counting repeats. If a new value is written to PITR, it is loaded into the modulus counter when the current count is completed. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-7 Freescale Semiconductor, Inc. Use the following expression to calculate timer period. ( PIT Modulus ) ( Prescaler Value ) ( 4 ) PIT Period = ---------------------------------------------------------------------------------------------EXTAL Frequency Interrupt priority and vectoring are determined by the values of the periodic interrupt request level (PIRQL) and periodic interrupt vector (PIV) fields in the periodic interrupt control register (PICR). Freescale Semiconductor, Inc... Content of PIRQL is compared to the CPU32 interrupt priority mask to determine whether the interrupt is recognized. Table 4-6 shows priority of PIRQL values. Because of SIM hardware prioritization, a PIT interrupt is serviced before an external interrupt request of the same priority. The periodic timer continues to run when the interrupt is disabled. Table 4-6 Periodic Interrupt Priority PIRQL 000 001 010 011 100 101 110 111 Priority Level Periodic Interrupt Disabled Interrupt Priority Level 1 Interrupt Priority Level 2 Interrupt Priority Level 3 Interrupt Priority Level 4 Interrupt Priority Level 5 Interrupt Priority Level 6 Interrupt Priority Level 7 The PIV field contains the periodic interrupt vector. The vector is placed on the IMB when an interrupt request is made. The vector number used to calculate the address of the appropriate exception vector in the exception vector table. Reset value of the PIV field is $0F, which corresponds to the uninitialized interrupt exception vector. 4.2.12 Low-Power Stop Operation When the CPU32 executes the LPSTOP instruction, the current interrupt priority mask is stored in the clock control logic, internal clocks are disabled according to the state of the STSIM bit in the SIMCR, and the MCU enters low-power stop mode. The bus monitor, halt monitor, and spurious interrupt monitor are all inactive during low-power stop. During low-power stop, the clock input to the software watchdog timer is disabled and the timer stops. The software watchdog begins to run again on the first rising clock edge after low-power stop ends. The watchdog is not reset by low-power stop. A service sequence must be performed to reset the timer. The periodic interrupt timer does not respond to the LPSTOP instruction, but continues to run during LPSTOP. To stop the periodic interrupt timer, PITR must be loaded with a zero value before the LPSTOP instruction is executed. A PIT interrupt, or an external interrupt request, can bring the MCU out of the low-power stop condition if it has a higher priority than the interrupt mask value stored in the clock control logic when lowpower stop is initiated. LPSTOP can be terminated by a reset. SYSTEM INTEGRATION MODULE 4-8 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Freescale Semiconductor, Inc... 4.2.13 Freeze Operation The FREEZE signal halts MCU operations during debugging. FREEZE is asserted internally by the CPU32 if a breakpoint occurs while background mode is enabled. When FREEZE is asserted, only the bus monitor, software watchdog, and periodic interrupt timer are affected. The halt monitor and spurious interrupt monitor continue to operate normally. Setting the freeze bus monitor (FRZBM) bit in the SIMCR disables the bus monitor when FREEZE is asserted, and setting the freeze software watchdog (FRZSW) bit disables the software watchdog and the periodic interrupt timer when FREEZE is asserted. When FRZSW is set, FREEZE assertion must be at least two times the PIT clock source period to ensure an accurate number of PIT counts. 4.3 System Clock The system clock in the SIM provides timing signals for the IMB modules and for an external peripheral bus. Because the MCU is a fully static design, register and memory contents are not affected when the clock rate changes. System hardware and software support changes in clock rate during operation. The system clock signal can be generated in one of three ways. An internal phaselocked loop can synthesize the clock from either an internal reference or an external reference, or the clock signal can be input from an external frequency source. Keep these clock sources in mind while reading the rest of this section. Figure 4-4 is a block diagram of the system clock. Refer to APPENDIX A ELECTRICAL CHARACTERISTICS for clock specifications. EXTAL XTAL CRYSTAL OSCILLATOR PHASE COMPARATOR XFC VDDSYN LOW-PASS FILTER VCO FEEDBACK DIVIDER SYSTEM CLOCK CONTROL CLKOUT W Y X SYSTEM CLOCK 32 PLL BLOCK Figure 4-4 System Clock Block Diagram MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-9 Freescale Semiconductor, Inc. 4.3.1 Clock Sources The state of the clock mode (MODCLK) pin during reset determines clock source. When MODCLK is held high during reset, the clock synthesizer generates a clock signal from either an internal or an external reference frequency -- the clock synthesizer control register (SYNCR) determines operating frequency and mode of operation. When MODCLK is held low during reset, the clock synthesizer is disabled and an external system clock signal must be applied -- SYNCR control bits have no effect. Freescale Semiconductor, Inc... To generate a reference frequency using the internal oscillator a reference crystal must be connected between the EXTAL and XTAL pins. Figure 4-5 shows a recommended circuit. C1 22 pF* R1 330k XTAL R2 10M VSSI C2 22 pF* EXTAL * Resistance and capacitance based on a test circuit constructed with a DAISHINKU DMX-38 32.768-kHz crystal. Specific components must be based on crystal type. Contact crystal vendor for exact circuit. 32 OSCILLATOR Figure 4-5 System Clock Oscillator Circuit If an external reference signal or an external system clock signal is applied via the EXTAL pin, the XTAL pin must be left floating. External reference signal frequency must be less than or equal to maximum specified reference frequency. External system clock signal frequency must be less than or equal to maximum specified system clock frequency. When an external system clock signal is applied (PLL disabled, MODCLK = 0 during reset), the duty cycle of the input is critical, especially at operating frequencies close to maximum. The relationship between clock signal duty cycle and clock signal period is expressed: Minimum External Clock Period = Minimum External Clock High Low Time ---------------------------------------------------------------------------------------------------------------------------------------------------------------------50% - Percentage Variation of External Clock Input Duty Cycle 4.3.2 Clock Synthesizer Operation VDDSYN is used to power the clock circuits when either an internal or an external reference frequency is applied. A separate power source increases MCU noise immunity and can be used to run the clock when the MCU is powered down. A quiet power supSYSTEM INTEGRATION MODULE 4-10 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. ply must be used as the VDDSYN source. Adequate external bypass capacitors should be placed as close as possible to the VDDSYN pin to assure stable operating frequency. When an external system clock signal is applied and the PLL is disabled, VDDSYN should be connected to the VDD supply. Refer to the SIM Reference Manual (SIMRM/ AD) for more information regarding system clock power supply conditioning. Freescale Semiconductor, Inc... A voltage controlled oscillator (VCO) generates the system clock signal. To maintain a 50% clock duty cycle, VCO frequency is either two or four times system clock frequency, depending on the state of the X bit in SYNCR. A portion of the clock signal is fed back to a divider/counter. The divider controls the frequency of one input to a phase comparator. The other phase comparator input is a reference signal, either from the crystal oscillator or from an external source. The comparator generates a control signal proportional to the difference in phase between the two inputs. The signal is lowpass filtered and used to correct VCO output frequency. Filter geometry can vary, depending upon the external environment and required clock stability. Figure 4-6 shows two recommended filters. XFC pin leakage must be as specified in APPENDIX A ELECTRICAL CHARACTERISTICS to maintain optimum stability and PLL performance. An external filter network connected to the XFC pin is not required when an external system clock signal is applied and the PLL is disabled. The XFC pin must be left floating in this case. C3 0.1F C3 0.1F C1 0.1F XFC1 C1 0.1F R1 18k VDDSYN VSSI C4 0.01F VSSI NORMAL OPERATING ENVIRONMENT C4 0.01F XFC1, 2 C2 0.01F VDDSYN HIGH-STABILITY OPERATING ENVIRONMENT 1. Maintain low-leakage on the XFC node. See Appendix A electrical characteristics for more information. 2. Recommended loop filter for reduced sensitivity to low-frequency noise. 16/32 XFC CONN Figure 4-6 System Clock Filter Networks The synthesizer locks when VCO frequency is equal to EXTAL frequency. Lock time is affected by the filter time constant and by the amount of difference between the two comparator inputs. Whenever comparator input changes, the synthesizer must relock. Lock status is shown by the SLOCK bit in SYNCR. During power-up, the MCU does not come out of reset state until the synthesizer locks. Crystal type, characteristic frequency, and layout of external oscillator circuitry affect lock time. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-11 Freescale Semiconductor, Inc. When the clock synthesizer is used, control register SYNCR determines operating frequency and various modes of operation. The SYNCR W bit controls a three-bit prescaler in the feedback divider. Setting W increases VCO speed by a factor of four. The SYNCR Y field determines the count modulus for a modulo 64 down counter, causing it to divide by a value of Y + 1. When W or Y values change, VCO frequency changes, and there is a VCO relock delay. The SYNCR X bit controls a divide-by-two circuit that is not in the synthesizer feedback loop. When X = 0 (reset state), the divider is enabled, and system clock frequency is one-fourth VCO frequency; setting X disables the divider, doubling clock speed without changing VCO speed. There is no relock delay when clock speed is changed by the X bit. Clock frequency is determined by SYNCR bit settings as follows: Freescale Semiconductor, Inc... F SYSTEM = F REFERENCE [ 4 ( Y + 1 ) ( 2 2W + X )] The reset state of SYNCR ($3F00) produces a modulus-64 count. For the device to perform correctly, system clock and VCO frequencies selected by the W, X, and Y bits must be within the limits specified for the MCU. Do not use a combination of bit values that selects either an operating frequency or a VCO frequency greater than the maximum specified values in APPENDIX A ELECTRICAL CHARACTERISTICS. Table 4-7 shows clock control multipliers for all possible combinations of SYNCR bits. Table 4-8 shows clock frequencies available with a 32.768-kHz reference and a maximum specified clock frequency of 20.97 MHz. Table 4-7 Clock Control Multipliers To obtain clock frequency in kilohertz, find counter modulus in the left column, then multiply reference frequency by value in appropriate prescaler cell. Modulus Y 000000 000001 000010 011111 000011 000100 000101 000110 000111 001000 001001 001010 001011 001100 001101 001110 001111 010000 010001 [W:X] = 00 4 8 12 16 20 24 28 32 36 40 44 48 52 56 60 64 68 72 76 Prescalers [W:X] = 01 [W:X] = 10 8 16 16 32 24 48 32 64 40 80 48 96 56 112 64 128 72 144 80 160 88 176 96 192 104 208 112 224 120 240 128 256 136 272 144 288 152 304 SYSTEM INTEGRATION MODULE 4-12 For More Information On This Product, Go to: www.freescale.com [W:X] = 11 32 64 96 128 160 192 224 256 288 320 352 384 416 448 480 512 544 576 608 MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Table 4-7 Clock Control Multipliers (Continued) Freescale Semiconductor, Inc... To obtain clock frequency in kilohertz, find counter modulus in the left column, then multiply reference frequency by value in appropriate prescaler cell. Modulus Y 010010 010011 010100 010101 010110 010111 011000 011001 011010 011011 011100 011101 011110 100000 100001 100010 100011 100100 100101 100110 100111 101000 101001 101010 101011 101100 101101 101110 101111 110000 110001 110010 110011 110100 110101 110110 110111 111000 111001 111010 111011 111100 111101 111110 111111 MC68332 USER'S MANUAL [W:X] = 00 80 84 88 92 96 100 104 108 112 116 120 124 128 132 136 140 144 148 152 156 160 164 168 172 176 180 184 188 192 196 200 204 208 212 216 220 224 228 232 236 240 244 248 252 256 Prescalers [W:X] = 01 [W:X] = 10 160 320 168 336 176 352 184 368 192 384 200 400 208 416 216 432 224 448 232 464 240 480 248 496 256 512 264 528 272 544 280 560 288 576 296 592 304 608 312 624 320 640 328 656 336 672 344 688 352 704 360 720 368 736 376 752 384 768 392 784 400 800 408 816 416 832 424 848 432 864 440 880 448 896 456 912 464 928 472 944 480 960 488 976 496 992 504 1008 512 1024 [W:X] = 11 640 672 704 736 768 800 832 864 896 928 960 992 1024 1056 1088 1120 1152 1184 1216 1248 1280 1312 1344 1376 1408 1440 1472 1504 1536 1568 1600 1632 1664 1696 1728 1760 1792 1824 1856 1888 1920 1952 1984 2016 2048 SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-13 Freescale Semiconductor, Inc. Table 4-8 System Frequencies from 32.768-kHz Reference To obtain clock frequency in kilohertz, find counter modulus in the left column, then multiply reference frequency by value in appropriate prescaler cell. Freescale Semiconductor, Inc... Modulus Y 000000 000001 000010 000011 000100 000101 000110 000111 001000 001001 001010 001011 001100 001101 001110 001111 010000 010001 010010 010011 010100 010101 010110 010111 011000 011001 011010 011011 011100 011101 011110 011111 100000 100001 100010 100011 100100 100101 100110 100111 101000 101001 101010 101011 101100 Prescaler [W:X] = 00 131 262 393 524 655 786 918 1049 1180 1311 1442 1573 1704 1835 1966 2097 2228 2359 2490 2621 2753 2884 3015 3146 3277 3408 3539 3670 3801 3932 4063 4194 4325 4456 4588 4719 4850 4981 5112 5243 5374 5505 5636 5767 5898 [W:X] = 01 262 524 786 1049 1311 1573 1835 2097 2359 2621 2884 3146 3408 3670 3932 4194 4456 4719 4981 5243 5505 5767 6029 6291 6554 6816 7078 7340 7602 7864 8126 8389 8651 8913 9175 9437 9699 9961 10224 10486 10748 11010 11272 11534 11796 [W:X] = 10 524 1049 1573 2097 2621 3146 3670 4194 4719 5243 5767 6291 6816 7340 7864 8389 8913 9437 9961 10486 11010 11534 12059 12583 13107 13631 14156 14680 15204 15729 16253 16777 17302 17826 18350 18874 19399 19923 20447 20972 21496 22020 22544 23069 23593 SYSTEM INTEGRATION MODULE 4-14 For More Information On This Product, Go to: www.freescale.com [W:X] = 11 1049 2097 3146 4194 5243 6291 7340 8389 9437 10486 11534 12583 13631 14680 15729 16777 17826 18874 19923 20972 22020 23069 24117 25166 26214 27263 28312 29360 30409 31457 32506 33554 34603 35652 36700 37749 38797 39846 40894 41943 42992 44040 45089 46137 47186 MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Table 4-8 System Frequencies from 32.768-kHz Reference (Continued) Freescale Semiconductor, Inc... To obtain clock frequency in kilohertz, find counter modulus in the left column, then multiply reference frequency by value in appropriate prescaler cell. Modulus Y 101101 101110 101111 110000 110001 110010 110011 110100 110101 110110 110111 111000 111001 111010 111011 111100 111101 111110 111111 Prescaler [W:X] = 00 6029 6160 6291 6423 6554 6685 6816 6947 7078 7209 7340 7471 7602 7733 7864 7995 8126 8258 8389 [W:X] = 01 12059 12321 12583 12845 13107 13369 13631 13894 14156 14418 14680 14942 15204 15466 15729 15991 16253 16515 16777 [W:X] = 10 24117 24642 25166 25690 26214 26739 27263 27787 28312 28836 29360 2988 30409 30933 31457 31982 32506 33030 33554 [W:X] = 11 48234 49283 50332 51380 52428 53477 54526 55575 56623 57672 58720 59769 60817 61866 62915 63963 65011 66060 67109 4.3.3 External Bus Clock The state of the external clock division bit (EDIV) in SYNCR determines clock rate for the external bus clock signal (ECLK) available on pin ADDR23. ECLK is a bus clock for MC6800 devices and peripherals. ECLK frequency can be set to system clock frequency divided by eight or system clock frequency divided by sixteen. The clock is enabled by the CS10 field in chip select pin assignment register 1 (CSPAR1). ECLK operation during low-power stop is described in the following paragraph. Refer to 4.8 Chip Selects for more information about the external bus clock. 4.3.4 Low-Power Operation Low-power operation is initiated by the CPU32. To reduce power consumption selectively, the CPU can set the STOP bits in each module configuration register. To minimize overall microcontroller power consumption, the CPU can execute the LPSTOP instruction, which causes the SIM to turn off the system clock. When individual module STOP bits are set, clock signals inside each module are turned off, but module registers are still accessible. When the CPU executes LPSTOP, a special CPU space bus cycle writes a copy of the current interrupt mask into the clock control logic. The SIM brings the MCU out of low-power operation when either an interrupt of higher priority than the stored mask or a reset occurs. Refer to 4.5.4.2 LPSTOP Broadcast Cycle and SECTION 5 CENTRAL PROCESSING UNIT for more information. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-15 Freescale Semiconductor, Inc. During a low-power stop, unless the system clock signal is supplied by an external source and that source is removed, the SIM clock control logic and the SIM clock signal (SIMCLK) continue to operate. The periodic interrupt timer and input logic for the RESET and IRQ pins are clocked by SIMCLK. The SIM can also continue to generate the CLKOUT signal while in low-power mode. The stop mode system integration module clock (STSIM) and stop mode external clock (STEXT) bits in SYNCR determine clock operation during low-power stop. Table 4-9 is a summary of the effects of STSIM and STEXT. MODCLK value is the logic level on the MODCLK pin during the last reset before LPSTOP execution. Any clock in the off state is held low. If the synthesizer VCO is turned off during LPSTOP, there is a PLL relock delay after the VCO is turned back on. Freescale Semiconductor, Inc... Table 4-9 Clock Control Mode LPSTOP No Pins MODCLK 0 Yes 0 Yes 0 Yes 0 Yes 0 No 1 Yes 1 Yes 1 Yes 1 Yes 1 EXTAL External Clock External Clock External Clock External Clock External Clock Crystal or Reference Crystal or Reference Crystal or Reference Crystal or Reference Crystal or Reference SYNCR Bits STSIM STEXT X X 0 0 0 1 1 0 1 1 X X 0 0 0 1 1 1 SIMCLK External Clock External Clock External Clock External Clock External Clock VCO Clock Status CLKOUT External Clock Off ECLK External Clock Off External Clock Off External Clock Off External Clock VCO External Clock VCO Off Off Crystal/ Reference Off Off 0 Crystal or Reference Crystal or Reference VCO 1 VCO VCO VCO Off 4.3.5 Loss of Reference Signal The state of the reset enable (RSTEN) bit in SYNCR determines what happens when clock logic detects a reference failure. When RSTEN is cleared (default state out of reset), the clock synthesizer is forced into an operating condition referred to as limp mode. Limp mode frequency varies from device to device, but maximum limp frequency does not exceed one half maximum system clock when X = 0, or maximum system clock frequency when X = 1. When RSTEN is set, the SIM resets the MCU. The limp status bit (SLIMP) in SYNCR indicates whether the synthesizer has a reference signal. It is set when a reference failure is detected. SYSTEM INTEGRATION MODULE 4-16 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Freescale Semiconductor, Inc... 4.4 External Bus Interface The external bus interface (EBI) transfers information between the internal MCU bus and external devices. Figure 4-7 shows a basic system with external memory and peripherals. 1 FC SIZ CLKOUT AS DSACK DS CS3 CS5 IRQ ADDR[23:0] DATA[15:0] ASYNC BUS PERIPHERAL SIZ CLK AS DSACK DS CS IACK IRQ 2 ADDR[15:0] DATA[15:0] MEMORY MCU CSBOOT R/W ADDR[23:0] DATA[15:8] CS R/W 2 MEMORY ADDR[23:0] DATA[7:0] CS R/W 2 1. Can be decoded to provide additional address space. 2. Varies depending upon peripheral memory size. 32 EXAMPLE SYS BLOCK Figure 4-7 MCU Basic System The external bus has 24 address lines and 16 data lines. The EBI provides dynamic sizing between 8-bit and 16-bit data accesses. It supports byte, word, and long-word transfers. Ports are accessed through the use of asynchronous cycles controlled by the data transfer (SIZ1 and SIZ0) and data size acknowledge pins (DSACK1 and DSACK0). Multiple bus cycles may be required for a transfer to or from an 8-bit port. The maximum number of bits transferred during an access is referred to as port width. Widths of eight and sixteen bits can be accessed by asynchronous bus cycles controlled by the data size (SIZ[1:0]) and the data and size acknowledge (DSACK[1:0]) signals. Multiple bus cycles may be required for a dynamically-sized transfer. To add flexibility and minimize the necessity for external logic, MCU chip-select logic can be synchronized with EBI transfers. Refer to 4.8 Chip Selects for more information. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-17 Freescale Semiconductor, Inc. 4.4.1 Bus Signals The address bus provides addressing information to external devices. The data bus transfers 8-bit and 16-bit data between the MCU and external devices. Strobe signals, one for the address bus and another for the data bus, indicate the validity of an address and provide timing information for data. Freescale Semiconductor, Inc... Control signals indicate the beginning of each bus cycle, the address space it is to take place in, the size of the transfer, and the type of cycle. External devices decode these signals and respond to transfer data and terminate the bus cycle. The EBI operates in an asynchronous mode for any port width. 4.4.1.1 Address Bus Bus signals ADDR[23:0] define the address of the byte (or the most significant byte) to be transferred during a bus cycle. The MCU places the address on the bus at the beginning of a bus cycle. The address is valid while AS is asserted. 4.4.1.2 Address Strobe Address strobe (AS) is a timing signal that indicates the validity of an address on the address bus and of many control signals. It is asserted one-half clock after the beginning of a bus cycle. 4.4.1.3 Data Bus Signals DATA[15:0] form a bidirectional, nonmultiplexed parallel bus that transfers data to or from the MCU. A read or write operation can transfer eight or sixteen bits of data in one bus cycle. During a read cycle, the data is latched by the MCU on the last falling edge of the clock for that bus cycle. For a write cycle, all 16 bits of the data bus are driven, regardless of the port width or operand size. The MCU places the data on the data bus one-half clock cycle after AS is asserted in a write cycle. 4.4.1.4 Data Strobe Data strobe (DS) is a timing signal. For a read cycle, the MCU asserts DS to signal an external device to place data on the bus. DS is asserted at the same time as AS during a read cycle. For a write cycle, DS signals an external device that data on the bus is valid. The MCU asserts DS one full clock cycle after the assertion of AS during a write cycle. 4.4.1.5 Read/Write Signal The read/write signal (R/W) determines the direction of the transfer during a bus cycle. This signal changes state, when required, at the beginning of a bus cycle, and is valid while AS is asserted. R/W only transitions when a write cycle is preceded by a read cycle or vice versa. The signal may remain low for two consecutive write cycles. SYSTEM INTEGRATION MODULE 4-18 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. 4.4.1.6 Size Signals Size signals (SIZ[1:0]) indicate the number of bytes remaining to be transferred during an operand cycle. They are valid while the address strobe (AS) is asserted. Table 410 shows SIZ0 and SIZ1 encoding. Table 4-10 Size Signal Encoding Freescale Semiconductor, Inc... SIZ1 0 1 1 0 SIZ0 1 0 1 0 Transfer Size Byte Word 3 Byte Long Word 4.4.1.7 Function Codes The CPU generates function code output signals FC[2:0] to indicate the type of activity occurring on the data or address bus. These signals can be considered address extensions that can be externally decoded to determine which of eight external address spaces is accessed during a bus cycle. Address space 7 is designated CPU space. CPU space is used for control information not normally associated with read or write bus cycles. Function codes are valid while AS is asserted. Table 4-11 shows address space encoding. Table 4-11 Address Space Encoding FC2 0 0 0 0 1 1 1 1 FC1 0 0 1 1 0 0 1 1 FC0 0 1 0 1 0 1 0 1 Address Space Reserved User Data Space User Program Space Reserved Reserved Supervisor Data Space Supervisor Program Space CPU Space The supervisor bit in the status register determines whether the CPU is operating in supervisor or user mode. Addressing mode and the instruction being executed determine whether a memory access is to program or data space. 4.4.1.8 Data and Size Acknowledge Signals During normal bus transfers, external devices assert the data and size acknowledge signals (DSACK[1:0]) to indicate port width to the MCU. During a read cycle, these signals tell the MCU to terminate the bus cycle and to latch data. During a write cycle, the signals indicate that an external device has successfully stored data and that the cycle can terminate. DSACK[1:0] can also be supplied internally by chip-select logic. Refer to 4.8 Chip Selects for more information. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-19 Freescale Semiconductor, Inc. 4.4.1.9 Bus Error Signal The bus error signal (BERR) is asserted when a bus cycle is not properly terminated by DSACK or AVEC assertion. BERR can also be asserted at the same time as DSACK, provided the appropriate timing requirements are met. Refer to 4.5.5 Bus Exception Control Cycles for more information. Freescale Semiconductor, Inc... The internal bus monitor can generate the BERR signal for internal and internal-to-external transfers. An external bus master must provide its own BERR generation and drive the BERR pin, because the internal BERR monitor has no information about transfers initiated by an external bus master. Refer to 4.5.6 External Bus Arbitration for more information. 4.4.1.10 Halt Signal The halt signa (HALT) can be asserted by an external device for debugging purposes to cause single bus cycle operation or (in combination with BERR) a retry of a bus cycle in error. The HALT signal affects external bus cycles only, so a program not requiring the use of external bus may continue executing, unaffected by the HALT signal. When the MCU completes a bus cycle with the HALT signal asserted, DATA[15:0] is placed in the high-impedance state, and bus control signals are driven inactive; the address, function code, size, and read/write signals remain in the same state. If HALT is still asserted once bus mastership is returned to the MCU, the address, function code, size, and read/write signals are again driven to their previous states. The MCU does not service interrupt requests while it is halted. Refer to 4.5.5 Bus Exception Control Cycles for further information. 4.4.1.11 Autovector Signal The autovector signal (AVEC) can be used to terminate external interrupt acknowledge cycles. Assertion of AVEC causes the CPU32 to generate vector numbers to locate an interrupt handler routine. If it is continuously asserted, autovectors are generated for all external interrupt requests. AVEC is ignored during all other bus cycles. Refer to 4.7 Interrupts for more information. AVEC for external interrupt requests can also be supplied internally by chip-select logic. Refer to 4.8 Chip Selects for more information. The autovector function is disabled when there is an external bus master. Refer to 4.5.6 External Bus Arbitration for more information. 4.4.2 Dynamic Bus Sizing The MCU dynamically interprets the port size of an addressed device during each bus cycle, allowing operand transfers to or from 8-bit and 16-bit ports. During an operand transfer cycle, an external device signals its port size and indicates completion of the bus cycle to the MCU through the use of the DSACK inputs, as shown in Table 4-12. Chip-select logic can generate data and size acknowledge signals for an external device. Refer to 4.8 Chip Selects for further information. SYSTEM INTEGRATION MODULE 4-20 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Table 4-12 Effect of DSACK Signals DSACK1 1 1 0 0 DSACK0 1 0 1 0 Result Insert Wait States in Current Bus Cycle Complete Cycle -- Data Bus Port Size is 8 Bits Complete Cycle -- Data Bus Port Size is 16 Bits Reserved Freescale Semiconductor, Inc... If the CPU is executing an instruction that reads a long-word operand from a 16-bit port, the MCU latches the 16 bits of valid data and then runs another bus cycle to obtain the other 16 bits. The operation for an 8-bit port is similar, but requires four read cycles. The addressed device uses the DSACK signals to indicate the port width. For instance, a 16-bit device always returns DSACK for a 16-bit port (regardless of whether the bus cycle is a byte or word operation). Dynamic bus sizing requires that the portion of the data bus used for a transfer to or from a particular port size be fixed. A 16-bit port must reside on data bus bits [15:0], and an 8-bit port must reside on data bus bits [15:8]. This minimizes the number of bus cycles needed to transfer data and ensures that the MCU transfers valid data. The MCU always attempts to transfer the maximum amount of data on all bus cycles. For a word operation, it is assumed that the port is 16 bits wide when the bus cycle begins. Operand bytes are designated as shown in Figure 4-8. OP[0:3] represent the order of access. For instance, OP0 is the most significant byte of a long-word operand, and is accessed first, while OP3, the least significant byte, is accessed last. The two bytes of a word-length operand are OP0 (most significant) and OP1. The single byte of a bytelength operand is OP0. Operand 31 Long Word Three Byte Word Byte 24 OP0 23 Byte Order 16 15 8 OP1 OP2 OP0 OP1 OP0 7 0 OP3 OP2 OP1 OP0 Figure 4-8 Operand Byte Order 4.4.3 Operand Alignment The EBI data multiplexer establishes the necessary connections for different combinations of address and data sizes. The multiplexer takes the two bytes of the 16-bit bus and routes them to their required positions. Positioning of bytes is determined by the size and address outputs. SIZ1 and SIZ0 indicate the remaining number of bytes to be transferred during the current bus cycle. The number of bytes transferred is equal to or less than the size indicated by SIZ1 and SIZ0, depending on port width. ADDR0 also affects the operation of the data multiplexer. During an operand transfer, ADDR[23:1] indicate the word base address of the portion of the operand to be accessed, and ADDR0 indicates the byte offset from the base. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-21 Freescale Semiconductor, Inc. 4.4.4 Misaligned Operands CPU32 architecture uses a basic operand size of 16 bits. An operand is misaligned when it overlaps a word boundary. This is determined by the value of ADDR0. When ADDR0 = 0 (an even address), the address is on a word and byte boundary. When ADDR0 = 1 (an odd address), the address is on a byte boundary only. A byte operand is aligned at any address; a word or long-word operand is misaligned at an odd address. Freescale Semiconductor, Inc... The largest amount of data that can be transferred by a single bus cycle is an aligned word. If the MCU transfers a long-word operand through a 16-bit port, the most significant operand word is transferred on the first bus cycle and the least significant operand word is transferred on a following bus cycle. 4.4.5 Operand Transfer Cases Table 4-13 is a summary of how operands are aligned for various types of transfers. OPn entries are portions of a requested operand that are read or written during a bus cycle and are defined by SIZ1, SIZ0, and ADDR0 for that bus cycle. The following paragraphs discuss all the allowable transfer cases in detail. Table 4-13 Operand Transfer Cases Nu m 1 2 3 4 5 6 7 8 9 10 11 12 13 Transfer Case Byte to 8-Bit Port (Even/Odd) Byte to 16-Bit Port (Even) Byte to 16-Bit Port (Odd) Word to 8-Bit Port (Aligned) Word to 8-Bit Port (Misaligned)1 Word to 16-Bit Port (Aligned) Word to 16-Bit Port (Misaligned)1 Long Word to 8-Bit Port (Aligned) Long Word to 8-Bit Port (Misaligned)1 Long Word to 16-Bit Port (Aligned) Long Word to 16-Bit Port (Misaligned)1 3 Byte to 8-Bit Port (Aligned)2 3 Byte to 8-Bit Port (Misaligned)2 SIZ [1:0] 01 01 01 10 10 10 10 00 10 00 10 11 11 Read Cycles ADDR0 DSACK DATA DATA [1:0] [15:8] [7:0] X 10 OP0 -- 0 01 OP0 -- 1 01 -- OP0 0 10 OP0 -- 1 10 OP0 -- 0 11 OP0 OP1 1 01 -- OP0 0 10 OP0 -- 1 10 OP0 -- 0 01 OP0 OP1 1 01 -- OP0 0 1 10 10 OP0 OP0 -- -- Write Cycles DATA DATA Next [15:8] [7:0] Cycle OP0 (OP0) -- OP0 (OP0) -- (OP0) OP0 -- OP0 (OP1) 1 OP0 (OP0) 1 OP0 OP1 -- (OP0) OP0 2 OP0 (OP1) 13 OP0 (OP0) 12 OP0 OP1 6 (OP0) OP0 2 OP0 OP0 (OP1) (OP0) 5 4 NOTES: 1. The CPU32 does not support misaligned transfers. 2. Three-byte transfer cases occur only as a result of a long word to byte transfer. 4.5 Bus Operation Internal microcontroller modules are typically accessed in two system clock cycles, with no wait states. Regular external bus cycles use handshaking between the MCU and external peripherals to manage transfer size and data. These accesses take three system clock cycles, again with no wait states. During regular cycles, wait states can be inserted as needed by bus control logic. Refer to 4.5.2 Regular Bus Cycles for more information. SYSTEM INTEGRATION MODULE 4-22 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Fast-termination cycles, which are two-cycle external accesses with no wait states, use chip-select logic to generate handshaking signals internally. Chip-select logic can also be used to insert wait states before internal generation of handshaking signals. Refer to 4.5.3 Fast Termination Cycles and 4.8 Chip Selects for more information. Bus control signal timing, as well as chip-select signal timing, are specified in APPENDIX A ELECTRICAL CHARACTERISTICS. Refer to the SIM Reference Manual (SIMRM/AD) for more information about each type of bus cycle. Freescale Semiconductor, Inc... The MCU is responsible for de-skewing signals it issues at both the start and the end of a cycle. In addition, the MCU is responsible for de-skewing acknowledge and data signals from peripheral devices. 4.5.1 Synchronization to CLKOUT External devices connected to the MCU bus can operate at a clock frequency different from the frequencies of the MCU as long as the external devices satisfy the interface signal timing constraints. Although bus cycles are classified as asynchronous, they are interpreted relative to the MCU system clock output (CLKOUT). Descriptions are made in terms of individual system clock states, labeled {S0, S1, S2,..., SN}. The designation "state" refers to the logic level of the clock signal, and does not correspond to any implemented machine state. A clock cycle consists of two successive states. Refer to APPENDIX A ELECTRICAL CHARACTERISTICS for more information. Bus cycles terminated by DSACK assertion normally require a minimum of three CLKOUT cycles. To support systems that use CLKOUT to generate DSACK and other inputs, asynchronous input setup time and asynchronous input hold times are specified. When these specifications are met, the MCU is guaranteed to recognize the appropriate signal on a specific edge of the CLKOUT signal. For a read cycle, when assertion of DSACK is recognized on a particular falling edge of the clock, valid data is latched into the MCU on the next falling clock edge, provided that the data meets the data setup time. In this case, the parameter for asynchronous operation can be ignored. When a system asserts DSACK for the required window around the falling edge of S2 and obeys the bus protocol by maintaining DSACK and BERR or HALT until and throughout the clock edge that negates AS, no wait states are inserted. The bus cycle runs at the maximum speed of three clocks per cycle. To ensure proper operation in a system synchronized to CLKOUT, when either BERR, or BERR and HALT is asserted after DSACK, BERR (or BERR and HALT) assertion must satisfy the appropriate data-in setup and hold times before the falling edge of the clock cycle after DSACK is recognized. 4.5.2 Regular Bus Cycles The following paragraphs contain a discussion of cycles that use external bus control logic. Refer to 4.5.3 Fast Termination Cycles for information about fast cycles. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-23 Freescale Semiconductor, Inc. To initiate a transfer, the MCU asserts an address and the SIZ[1:0] signals. The SIZ signals and ADDR0 are externally decoded to select the active portion of the data bus (refer to 4.4.2 Dynamic Bus Sizing). When AS, DS, and R/W are valid, a peripheral device either places data on the bus (read cycle) or latches data from the bus (write cycle), then asserts a DSACK[1:0] combination that indicates port size. The DSACK[1:0] signals can be asserted before the data from a peripheral device is valid on a read cycle. To ensure valid data is latched into the MCU, a maximum period between DSACK assertion and DS assertion is specified. Freescale Semiconductor, Inc... There is no specified maximum for the period between the assertion of AS and DSACK. Although the MCU can transfer data in a minimum of three clock cycles when the cycle is terminated with DSACK, the MCU inserts wait cycles in clock period increments until either DSACK signal goes low. NOTE The SIM bus monitor asserts BERR when response time exceeds a predetermined limit. Bus monitor period is determined by the BMT field in SYPCR. The bus monitor cannot be disabled; maximum monitor period is 64 system clock cycles. If no peripheral responds to an access, or if an access is invalid, external logic should assert the BERR or HALT signals to abort the bus cycle (when BERR and HALT are asserted simultaneously, the CPU32 acts as though only BERR is asserted). If bus termination signals are not asserted within a specified period, the bus monitor terminates the cycle. 4.5.2.1 Read Cycle During a read cycle, the MCU transfers data from an external memory or peripheral device. If the instruction specifies a long-word or word operation, the MCU attempts to read two bytes at once. For a byte operation, the MCU reads one byte. The portion of the data bus from which each byte is read depends on operand size, peripheral address, and peripheral port size. Figure 4-9 is a flowchart of a word read cycle. Refer to 4.4.2 Dynamic Bus Sizing, 4.4.4 Misaligned Operands, and the SIM Reference Manual (SIMRM/AD) for more information. SYSTEM INTEGRATION MODULE 4-24 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. MCU PERIPHERAL ADDRESS DEVICE (S0) 1) SET R/W TO READ 2) DRIVE ADDRESS ON ADDR[23:0] 3) DRIVE FUNCTION CODE ON FC[2:0] 4) DRIVE SIZ[1:0] FOR OPERAND SIZE ASSERT AS AND DS (S1) Freescale Semiconductor, Inc... DECODE DSACK (S3) PRESENT DATA (S2) 1) DECODE ADDR, R/W, SIZ[1:0], DS 2) PLACE DATA ON DATA[15:0] OR DATA[15:8] IF 8-BIT DATA 3) DRIVE DSACK SIGNALS LATCH DATA (S4) NEGATE AS AND DS (S5) START NEXT CYCLE (S0) TERMINATE CYCLE (S5) 1) REMOVE DATA FROM DATA BUS 2) NEGATE DSACK RD CYC FLOW Figure 4-9 Word Read Cycle Flowchart 4.5.2.2 Write Cycle During a write cycle, the MCU transfers data to an external memory or peripheral device. If the instruction specifies a long-word or word operation, the MCU attempts to write two bytes at once. For a byte operation, the MCU writes one byte. The portion of the data bus upon which each byte is written depends on operand size, peripheral address, and peripheral port size. Refer to 4.4.2 Dynamic Bus Sizing and 4.4.4 Misaligned Operands for more information. Figure 4-10 is a flowchart of a write-cycle operation for a word transfer. Refer to the SIM Reference Manual (SIMRM/AD) for more information. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-25 Freescale Semiconductor, Inc. MCU PERIPHERAL ADDRESS DEVICE (S0) 1) SET R/W TO WRITE 2) DRIVE ADDRESS ON ADDR[23:0] 3) DRIVE FUNCTION CODE ON FC[2:0] 4) DRIVE SIZ[1:0] FOR OPERAND SIZE ASSERT AS (S1) Freescale Semiconductor, Inc... PLACE DATA ON DATA[15:0] (S2) ASSERT DS AND WAIT FOR DSACK (S3) OPTIONAL STATE (S4) ACCEPT DATA (S2 + S3) 1) DECODE ADDRESS 2) LATCH DATA FROM DATA BUS 3) ASSERT DSACK SIGNALS NO CHANGE TERMINATE OUTPUT TRANSFER (S5) 1) NEGATE DS AND AS 2) REMOVE DATA FROM DATA BUS TERMINATE CYCLE 1) NEGATE DSACK START NEXT CYCLE WR CYC FLOW Figure 4-10 Write Cycle Flowchart 4.5.3 Fast Termination Cycles When an external device has a fast access time, the chip-select circuit fast-termination option can provide a two-cycle external bus transfer. Because the chip-select circuits are driven from the system clock, the bus cycle termination is inherently synchronized with the system clock. If multiple chip selects are to be used to select the same device that can support fast termination, and match conditions can occur simultaneously, program the DSACK field in each associated chip-select option register for fast termination. Alternately, program one DSACK field for fast termination and the remaining DSACK fields for external termination. Fast termination cycles use internal handshaking signals generated by the chip-select logic. To initiate a transfer, the MCU asserts an address and the SIZ[1:0] signals. SYSTEM INTEGRATION MODULE 4-26 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. When AS, DS, and R/W are valid, a peripheral device either places data on the bus (read cycle) or latches data from the bus (write cycle). At the appropriate time, chipselect logic asserts data and size acknowledge signals. The DSACK option fields in the chip-select option registers determine whether internally generated DSACK or externally generated DSACK are used. For fast termination cycles, the F-term encoding (%1110) must be used. Refer to 4.8.1 Chip-Select Registers for information about fast-termination setup. Freescale Semiconductor, Inc... To use fast-termination, an external device must be fast enough to have data ready, within the specified setup time, by the falling edge of S4. Refer to APPENDIX A ELECTRICAL CHARACTERISTICS for tabular information about fast termination timing. When fast termination is in use, DS is asserted during read cycles but not during write cycles. The STRB field in the chip-select option register used must be programmed with the address strobe encoding to assert the chip select signal for a fast-termination write. 4.5.4 CPU Space Cycles Function code signals FC[2:0] designate which of eight external address spaces is accessed during a bus cycle. Address space 7 is designated CPU space. CPU space is used for control information not normally associated with read or write bus cycles. Function codes are valid only while AS is asserted. Refer to 4.4.1.7 Function Codes for more information on codes and encoding. During a CPU space access, ADDR[19:16] are encoded to reflect the type of access being made. Figure 4-11 shows the three encodings used by 68300 family microcontrollers. These encodings represent breakpoint acknowledge (Type $0) cycles, low power stop broadcast (Type $3) cycles, and interrupt acknowledge (Type $F) cycles. Refer to 4.7 Interrupts for information about interrupt acknowledge bus cycles. CPU SPACE CYCLES FUNCTION CODE 2 BREAKPOINT ACKNOWLEDGE LOW POWER STOP BROADCAST INTERRUPT ACKNOWLEDGE 0 ADDRESS BUS 23 19 16 4 2 1 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 BKPT# T 0 2 23 0 19 16 0 1 1 1 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 2 23 0 1 1 1 19 16 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 LEVEL 1 CPU SPACE TYPE FIELD CPU SPACE CYC TIM Figure 4-11 CPU Space Address Encoding MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-27 Freescale Semiconductor, Inc. 4.5.4.1 Breakpoint Acknowledge Cycle Breakpoints stop program execution at a predefined point during system development. Breakpoints can be used alone or in conjunction with the background debugging mode. The following paragraphs discuss breakpoint processing when background debugging mode is not enabled. See SECTION 5 CENTRAL PROCESSING UNIT for more information on exception processing and the background debugging mode. Freescale Semiconductor, Inc... In M68300 microcontrollers, both hardware and software can initiate breakpoints. 4.5.4.1.1 Software Breakpoints The CPU32 BKPT instruction allows the user to insert breakpoints through software. The CPU responds to this instruction by initiating a breakpoint-acknowledge read cycle in CPU space. It places the breakpoint acknowledge (%0000) code on ADDR[19:16], the breakpoint number (bits [2:0] of the BKPT opcode) in ADDR[4:2], and %0 (indicating a software breakpoint) on ADDR1. The external breakpoint circuitry decodes the function code and address lines and responds by either asserting BERR or placing an instruction word on the data bus and asserting DSACK. If the bus cycle is terminated by DSACK, the CPU32 reads the instruction on the data bus and inserts the instruction into the pipeline. (For 8-bit ports, this instruction fetch may require two read cycles.) If the bus cycle is terminated by BERR, the CPU32 then performs illegal-instruction exception processing: it acquires the number of the illegal-instruction exception vector, computes the vector address from this number, loads the content of the vector address into the PC, and jumps to the exception handler routine at that address. 4.5.4.1.2 Hardware Breakpoints Assertion of the BKPT input initiates a hardware breakpoint. The CPU responds by initiating a breakpoint-acknowledge read cycle in CPU space. It places $00001E on the address bus. (The breakpoint acknowledge code of %0000 is placed on ADDR[19:16], the breakpoint number value of %111 is placed on ADDR[4:2], and ADDR1 is set to one, indicating a hardware breakpoint.) The external breakpoint circuitry decodes the function code and address lines, places an instruction word on the data bus, and asserts BERR. The CPU then performs hardware breakpoint exception processing: it acquires the number of the hardware breakpoint exception vector, computes the vector address from this number, loads the content of the vector address into the PC, and jumps to the exception handler routine at that address. If the external device asserts DSACK rather than BERR, the CPU ignores the breakpoint and continues processing. When BKPT assertion is synchronized with an instruction prefetch, processing of the breakpoint exception occurs at the end of that instruction. The prefetched instruction is "tagged" with the breakpoint when it enters the instruction pipeline, and the breakpoint exception occurs after the instruction executes. If the pipeline is flushed before SYSTEM INTEGRATION MODULE 4-28 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. the tagged instruction is executed, no breakpoint occurs. When BKPT assertion is synchronized with an operand fetch, exception processing occurs at the end of the instruction during which BKPT is latched. Freescale Semiconductor, Inc... Refer to the CPU32 Reference Manual (CPU32RM/AD) and the SIM Reference Manual (SIMRM/AD) for additional information. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-29 Freescale Semiconductor, Inc. BREAKPOINT OPERATION FLOW CPU32 PERIPHERAL ACKNOWLEDGE BREAKPOINT IF BREAKPOINT INSTRUCTION EXECUTED: 1) SET R/W TO READ 2) SET FUNCTION CODE TO CPU SPACE 3) PLACE CPU SPACE TYPE 0 ON ADDR[19:16] 4) PLACE BREAKPOINT NUMBER ON ADDR[4:2] 5) CLEAR T-BIT (ADDR1) TO ZERO 6) SET SIZE TO WORD 7) ASSERT AS AND DS Freescale Semiconductor, Inc... IF BKPT PIN ASSERTED: 1) SET R/W TO READ 2) SET FUNCTION CODE TO CPU SPACE 3) PLACE CPU SPACE TYPE 0 ON ADDR[19:16] 4) PLACE ALL ONES ON ADDR[4:2] 5) SET T-BIT (ADDR1) TO ONE 6) SET SIZE TO WORD 7) ASSERT AS AND DS IF BREAKPOINT INSTRUCTION EXECUTED AND DSACK IS ASSERTED: 1) LATCH DATA 2) NEGATE AS AND DS 3) GO TO (A) IF BKPT INSTRUCTION EXECUTED: 1) PLACE REPLACEMENT OPCODE ON DATA BUS 2) ASSERT DSACK OR: 1) ASSERT BERR TO INITIATE EXCEPTION PROCESSING IF BKPT ASSERTED: 1) ASSERT DSACK OR: 1) ASSERT BERR TO INITIATE EXCEPTION PROCESSING IF BKPT PIN ASSERTED AND DSACK IS ASSERTED: 1) NEGATE AS AND DS 2) GO TO (A) IF BERR ASSERTED: 1) NEGATE AS AND DS 2) GO TO (B) (A) (B) IF BKPT INSTRUCTION EXECUTED: 1) PLACE LATCHED DATA IN INSTRUCTION PIPELINE 2) CONTINUE PROCESSING 1) NEGATE DSACK or BERR IF BKPT PIN ASSERTED: 1) CONTINUE PROCESSING IF BKPT INSTRUCTION EXECUTED: 1) INITIATE ILLEGAL INSTRUCTION PROCESSING IF BKPT PIN ASSERTED: 1) INITIATE HARDWARE BREAKPOINT PROCESSING 1110A Figure 4-12 Breakpoint Operation Flowchart SYSTEM INTEGRATION MODULE 4-30 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Freescale Semiconductor, Inc... 4.5.4.2 LPSTOP Broadcast Cycle Low-power stop is initiated by the CPU32. Individual modules can be stopped by setting the STOP bits in each module configuration register, or the SIM can turn off system clocks after execution of the LPSTOP instruction. When the CPU executes LPSTOP, the LPSTOP broadcast cycle is generated. The SIM brings the MCU out of low-power mode when either an interrupt of higher priority than the stored mask or a reset occurs. Refer to and SECTION 5 CENTRAL PROCESSING UNIT for more information. During an LPSTOP broadcast cycle, the CPU performs a CPU space write to address $3FFFE. This write puts a copy of the interrupt mask value in the clock control logic. The mask is encoded on the data bus as shown in Figure 4-13. The LPSTOP CPU space cycle is shown externally (if the bus is available) as an indication to external devices that the MCU is going into low-power stop mode. The SIM provides an internally generated DSACK response to this cycle. The timing of this bus cycle is the same as for a fast write cycle. 15 14 13 12 11 10 9 8 7 6 5 4 3 0 0 0 0 0 0 0 0 0 0 0 0 0 2 1 0 IP MASK Figure 4-13 LPSTOP Interrupt Mask Level 4.5.5 Bus Exception Control Cycles An external device or a chip-select circuit must assert at least one of the DSACK[1:0] signals or the AVEC signal to terminate a bus cycle normally. Bus error processing occurs when bus cycles are not terminated in the expected manner. The internal bus monitor can be used to generate BERR internally, causing a bus error exception to be taken. Bus cycles can also be terminated by assertion of the external BERR or HALT signal, or by assertion of the two signals simultaneously. Acceptable bus cycle termination sequences are summarized as follows. The case numbers refer to Table 4-5, which indicates the results of each type of bus cycle termination. Normal Termination DSACK is asserted; BERR and HALT remain negated (case 1). Halt Termination HALT is asserted at the same time or before DSACK, and BERR remains negated (case 2). Bus Error Termination BERR is asserted in lieu of, at the same time as, or before DSACK, or after DSACK, and HALT remains negated; BERR is negated at the same time or after DSACK. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-31 Freescale Semiconductor, Inc. Retry Termination HALT and BERR are asserted in lieu of, at the same time as, or before DSACK or after DSACK; BERR is negated at the same time or after DSACK; HALT may be negated at the same time or after BERR. Table 4-14 shows various combinations of control signal sequences and the resulting bus cycle terminations. Freescale Semiconductor, Inc... Table 4-14 DSACK, BERR, and HALT Assertion Results Case Number Control Signal 1 DSACK BERR HALT DSACK BERR HALT DSACK BERR HALT DSACK BERR HALT DSACK BERR HALT DSACK BERR HALT 2 3 4 5 6 NOTES: N = A = NA = X = S = Asserted on Rising Edge of State N N+2 A S NA NA NA X A S NA NA A/S S NA/A X A S NA X A X A S NA NA NA/A X A S A/S S A X NA A NA A Result Normal termination. Halt termination: normal cycle terminate and halt. Continue when HALT is negated. Bus error termination: terminate and take bus error exception, possibly deferred. Bus error termination: terminate and take bus error exception, possibly deferred. Retry termination: terminate and retry when HALT is negated. Retry termination: terminate and retry when HALT is negated. The number of current even bus state (S2, S4, etc.). Signal is asserted in this bus state. Signal is not asserted in this state Don't care. Signal was asserted in previous state and remains asserted in this state. To properly control termination of a bus cycle for a retry or a bus error condition, DSACK, BERR, and HALT must be asserted and negated with the rising edge of the MCU clock. This ensures that when two signals are asserted simultaneously, the required setup time and hold time for both of them are met for the same falling edge of the MCU clock. (Refer to APPENDIX A ELECTRICAL CHARACTERISTICS for timing requirements.) External circuitry that provides these signals must be designed with these constraints in mind, or else the internal bus monitor must be used. DSACK, BERR, and HALT may be negated after AS is negated. WARNING If DSACK or BERR remain asserted into S2 of the next bus cycle, that cycle may be terminated prematurely. SYSTEM INTEGRATION MODULE 4-32 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. 4.5.5.1 Bus Errors The CPU32 treats bus errors as a type of exception. Bus error exception processing begins when the CPU detects assertion of the IMB BERR signal (by the internal bus monitor or an external source) while the HALT signal remains negated. Freescale Semiconductor, Inc... BERR assertions do not force immediate exception processing. The signal is synchronized with normal bus cycles and is latched into the CPU32 at the end of the bus cycle in which it was asserted. Because bus cycles can overlap instruction boundaries, bus error exception processing may not occur at the end of the instruction in which the bus cycle begins. Timing of BERR detection/acknowledge is dependent upon several factors: * Which bus cycle of an instruction is terminated by assertion of BERR. * The number of bus cycles in the instruction during which BERR is asserted. * The number of bus cycles in the instruction following the instruction in which BERR is asserted. * Whether BERR is asserted during a program space access or a data space access. Because of these factors, it is impossible to predict precisely how long after occurrence of a bus error the bus error exception is processed. CAUTION The external bus interface does not latch data when an external bus cycle is terminated by a bus error. When this occurs during an instruction prefetch, the IMB precharge state (bus pulled high, or $FF) is latched into the CPU32 instruction register, with indeterminate results. 4.5.5.2 Double Bus Faults Exception processing for bus error exceptions follows the standard exception processing sequence. Refer to SECTION 5 CENTRAL PROCESSING UNIT for more information about exceptions. However, a special case of bus error, called double bus fault, can abort exception processing. BERR assertion is not detected until an instruction is complete. The BERR latch is cleared by the first instruction of the BERR exception handler. Double bus fault occurs in two ways: 1. When bus error exception processing begins and a second BERR is detected before the first instruction of the first exception handler is executed. 2. When one or more bus errors occur before the first instruction after a RESET exception is executed. 3. A bus error occurs while the CPU32 is loading information from a bus error stack frame during a return from exception (RTE) instruction. Multiple bus errors within a single instruction that can generate multiple bus cycles cause a single bus error exception after the instruction has been executed. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-33 Freescale Semiconductor, Inc. Freescale Semiconductor, Inc... Immediately after assertion of a second BERR, the MCU halts and drives the HALT line low. Only a reset can restart a halted MCU. However, bus arbitration can still occur (refer to 4.5.6 External Bus Arbitration). A bus error or address error that occurs after exception processing has been completed (during the execution of the exception handler routine, or later) does not cause a double bus fault. The MCU continues to retry the same bus cycle as long as the external hardware requests it. 4.5.5.3 Retry Operation When an external device asserts BERR and HALT during a bus cycle, the MCU enters the retry sequence. A delayed retry can also occur. The MCU terminates the bus cycle, places the AS and DS signals in their inactive state, and does not begin another bus cycle until the BERR and HALT signals are negated by external logic. After a synchronization delay, the MCU retries the previous cycle using the same address, function codes, data (for a write), and control signals. The BERR signal should be negated before S2 of the read cycle to ensure correct operation of the retried cycle. If BR, BERR, and HALT are all asserted on the same cycle, the EBI will enter the rerun sequence but first relinquishes the bus to an external master. Once the external master returns the bus and negates BERR and HALT, the EBI runs the previous bus cycle. This feature allows an external device to correct the problem that caused the bus error and then try the bus cycle again. The MCU retries any read or write cycle of an indivisible read-modify-write operation separately; RMC remains asserted during the entire retry sequence. The MCU will not relinquish the bus while RMC is asserted. Any device that requires the MCU to give up the bus and retry a bus cycle during a read-modify-write cycle must assert BERR and BR only (HALT must remain negated). The bus error handler software should examine the read-modify-write bit in the special status word and take the appropriate action to resolve this type of fault when it occurs. 4.5.5.4 Halt Operation When HALT is asserted while BERR is not asserted, the MCU halts external bus activity after negation of DSACK. The MCU may complete the current word transfer in progress. For a long-word to byte transfer, this could be after S2 or S4. For a word to byte transfer, activity ceases after S2. Negating and reasserting HALT according to timing requirements provides single-step (bus cycle to bus cycle) operation. The HALT signal affects external bus cycles only, so that a program that does not use external bus can continue executing. During dynamically-sized 8-bit transfers, external bus activity may not stop at the next cycle boundary. Occurrence of a bus error while HALT is asserted causes the CPU32 to initiate a retry sequence. When the MCU completes a bus cycle while the HALT signal is asserted, the data bus goes to high-impedance state and the AS and DS signals are driven to their inactive states. Address, function code, size, and read/write signals remain in the same state. SYSTEM INTEGRATION MODULE 4-34 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. The halt operation has no effect on bus arbitration (refer to 4.5.6 External Bus Arbitration). However, when external bus arbitration occurs while the MCU is halted, address and control signals go to high-impedance state. If HALT is still asserted when the MCU regains control of the bus, address, function code, size, and read/write signals revert to the previous driven states. The MCU cannot service interrupt requests while halted. Freescale Semiconductor, Inc... 4.5.6 External Bus Arbitration MCU bus design provides for a single bus master at any one time. Either the MCU or an external device can be master. Bus arbitration protocols determine when an external device can become bus master. Bus arbitration requests are recognized during normal processing, HALT assertion, and when the CPU has halted due to a double bus fault. The bus controller in the MCU manages bus arbitration signals so that the MCU has the lowest priority. External devices that need to obtain the bus must assert bus arbitration signals in the sequences described in the following paragraphs. Systems that include several devices that can become bus master require external circuitry to assign priorities to the devices, so that when two or more external devices attempt to become bus master at the same time, the one having the highest priority becomes bus master first. The protocol sequence is: A. An external device asserts bus request signal (BR); B. The MCU asserts the bus grant signal (BG) to indicate that the bus is available; C. An external device asserts the bus grant acknowledge (BGACK) signal to indicate that it has assumed bus mastership. BR can be asserted during a bus cycle or between cycles. BG is asserted in response to BR. To guarantee operand coherency, BG is only asserted at the end of operand transfer. Additionally, BG is not asserted until the end of an indivisible read-modifywrite operation (when RMC is negated). If more than one external device can be bus master, required external arbitration must begin when a requesting device receives BG. An external device must assert BGACK when it assumes mastership, and must maintain BGACK assertion as long as it is bus master. Two conditions must be met for an external device to assume bus mastership. The device must receive BG through the arbitration process, and BGACK must be inactive, indicating that no other bus master is active. This technique allows the processing of bus requests during data transfer cycles. BG is negated a few clock cycles after BGACK transition. However, if bus requests are still pending after BG is negated, the MCU asserts BG again within a few clock cycles. This additional BG assertion allows external arbitration circuitry to select the next bus master before the current master has released the bus. Refer to Figure 4-14, which shows bus arbitration for a single device. The flowchart shows BR negated at the same time BGACK is asserted. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-35 Freescale Semiconductor, Inc. MCU REQUESTING DEVICE REQUEST THE BUS GRANT BUS ARBITRATION 1) ASSERT BUS REQUEST (BR) 1) ASSERT BUS GRANT (BG) ACKNOWLEDGE BUS MASTERSHIP Freescale Semiconductor, Inc... TERMINATE ARBITRATION 1) EXTERNAL ARBITRATION DETERMINES NEXT BUS MASTER 2) NEXT BUS MASTER WAITS FOR BGACK TO BE NEGATED 3) NEXT BUS MASTER ASSERTS BGACK TO BECOME NEW MASTER 4) BUS MASTER NEGATES BR 1) NEGATE BG (AND WAIT FOR BGACK TO BE NEGATED) OPERATE AS BUS MASTER 1) PERFORM DATA TRANSFERS (READ AND WRITE CYCLES) ACCORDING TO THE SAME RULES THE PROCESSOR USES RELEASE BUS MASTERSHIP RE-ARBITRATE OR RESUME PROCESSOR OPERATION 1) NEGATE BGACK BUS ARB FLOW Figure 4-14 Bus Arbitration Flowchart for Single Request State changes occur on the next rising edge of CLKOUT after the internal signal is valid. The BG signal transitions on the falling edge of the clock after a state is reached during which G changes. The bus control signals (controlled by T) are driven by the MCU immediately following a state change, when bus mastership is returned to the MCU. State 0, in which G and T are both negated, is the state of the bus arbiter while the MCU is bus master. Request R and acknowledge A keep the arbiter in state 0 as long as they are both negated. 4.5.6.1 Slave (Factory Test) Mode Arbitration This mode is used for factory production testing of internal modules. It is not supported as a user operating mode. Slave mode is enabled by holding DATA11 low during reset. In slave mode, when BG is asserted, the MCU is slaved to an external master that has full access to all internal registers. 4.5.6.2 Show Cycles The MCU normally performs internal data transfers without affecting the external bus, but it is possible to show these transfers during debugging. AS is not asserted externally during show cycles. SYSTEM INTEGRATION MODULE 4-36 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Show cycles are controlled by the SHEN field in the SIMCR (refer to 4.2.3 Show Internal Cycles). This field is cleared by reset. When show cycles are disabled, the address bus, function codes, size, and read/write signals reflect internal bus activity, but AS and DS are not asserted externally and external data bus pins are in high-impedance state during internal accesses. Freescale Semiconductor, Inc... When show cycles are enabled, DS is asserted externally during internal cycles, and internal data is driven out on the external data bus. Because internal cycles normally continue to run when the external bus is granted, one SHEN encoding halts internal bus activity while there is an external master. SIZ[1:0] signals reflect bus allocation during show cycles. Only the appropriate portion of the data bus is valid during the cycle. During a byte write to an internal address, the portion of the bus that represents the byte that is not written reflects internal bus conditions, and is indeterminate. During a byte write to an external address, the data multiplexer in the SIM causes the value of the byte that is written to be driven out on both bytes of the data bus. 4.6 Reset Reset occurs when an active low logic level on the RESET pin is clocked into the SIM. The RESET input is synchronized to the system clock. If there is no clock when RESET is asserted, reset does not occur until the clock starts. Resets are clocked to allow completion of write cycles in progress at the time RESET is asserted. Reset procedures handle system initialization and recovery from catastrophic failure. The MCU performs resets with a combination of hardware and software. The system integration module determines whether a reset is valid, asserts control signals, performs basic system configuration and boot ROM selection based on hardware modeselect inputs, then passes control to the CPU32. 4.6.1 Reset Exception Processing The CPU32 processes resets as a type of asynchronous exception. An exception is an event that preempts normal processing, and can be caused by internal or external events. Exception processing makes the transition from normal instruction execution to execution of a routine that deals with an exception. Each exception has an assigned vector that points to an associated handler routine. These vectors are stored in the vector base register (VBR). The VBR contains the base address of a 1024-byte exception vector table, which consists of 256 exception vectors. The CPU32 uses vector numbers to calculate displacement into the table. Refer to SECTION 5 CENTRAL PROCESSING UNIT for more information concerning exceptions. Reset is the highest-priority CPU32 exception. Unlike all other exceptions, a reset occurs at the end of a bus cycle, and not at an instruction boundary. Handling resets in this way prevents write cycles in progress at the time the reset signal is asserted from being corrupted. However, any processing in progress is aborted by the reset exception, and cannot be restarted. Only essential reset tasks are performed during exception processing. Other initialization tasks must be accomplished by the exception handler routine. 4.6.8 Reset Processing Summary contains details of exception processing. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-37 Freescale Semiconductor, Inc. 4.6.2 Reset Control Logic SIM reset control logic determines the cause of a reset, synchronizes reset assertion if necessary to the completion of the current bus cycle, and asserts the appropriate reset lines. Reset control logic can drive four different internal signals. Freescale Semiconductor, Inc... 1. 2. 3. 4. EXTRST (external reset) drives the external reset pin. CLKRST (clock reset) resets the clock module. MSTRST (master reset) goes to all other internal circuits. SYSRST (system reset) indicates to internal circuits that the CPU has executed a RESET instruction. All resets are gated by CLKOUT. Resets are classified as synchronous or asynchronous. An asynchronous reset can occur on any CLKOUT edge. Reset sources that cause an asynchronous reset usually indicate a catastrophic failure; thus the reset control logic responds by asserting reset to the system immediately. (A system reset, however, caused by the CPU32 RESET instruction, is asynchronous but does not indicate any type of catastrophic failure). Synchronous resets are timed (CLKOUT) to occur at the end of bus cycles. The internal bus monitor is automatically enabled for synchronous resets. When a bus cycle does not terminate normally, the bus monitor terminates it. Refer to Table 4-15 for a summary of reset sources. Table 4-15 Reset Source Summary Type Source Timing Cause External Power Up External EBI Synch Asynch External Signal VDD Software Watchdog HALT Monitor Monitor Asynch Asynch Loss of Clock Test System Clock Test CPU32 Synch Synch Asynch Time Out Internal HALT Assertion (e.g. Double Bus Fault) Loss of Reference Test Mode RESET Instruction Reset Lines Asserted by Controller MSTRST CLKRST EXTRST MSTRST CLKRST EXTRST MSTRST MSTRST CLKRST CLKRST EXTRST EXTRST MSTRST MSTRST -- CLKRST -- -- EXTRST EXTRST EXTRST Internal single byte or aligned word writes are guaranteed valid for synchronous resets. External writes are also guaranteed to complete, provided the external configuration logic on the data bus is conditioned as shown in Figure 4-13. 4.6.3 Reset Mode Selection The logic states of certain data bus pins during reset determine SIM operating configuration. In addition, the state of the MODCLK pin determines system clock source and the state of the BKPT pin determines what happens during subsequent breakpoint assertions. Table 4-16 is a summary of reset mode selection options. SYSTEM INTEGRATION MODULE 4-38 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Table 4-16 Reset Mode Selection Mode Select Pin DATA0 DATA1 Freescale Semiconductor, Inc... DATA2 DATA3 DATA4 DATA5 DATA6 DATA7 DATA8 DATA9 DATA11 MODCLK BKPT Default Function (Pin Left High) CSBOOT 16-Bit CS0 CS1 CS2 CS3 CS4 CS5 CS6 CS[7:6] CS[8:6] CS[9:6] CS[10:6] DSACK[1:0], AVEC, DS, AS, SIZE IRQ[7:1] MODCLK Test Mode Disabled VCO = System Clock Background Mode Disabled Alternate Function (Pin Pulled Low) CSBOOT 8-Bit BR BG BGACK FC0 FC1 FC2 ADDR19 ADDR[20:19] ADDR[21:19] ADDR[22:19] ADDR[23:19] PORTE PORTF Test Mode Enabled EXTAL = System Clock Background Mode Enabled 4.6.3.1 Data Bus Mode Selection All data lines have weak internal pull-up drivers. When pins are held high by the internal drivers, the MCU uses a default operating configuration. However, specific lines can be held low externally to achieve an alternate configuration. NOTE External bus loading can overcome the weak internal pull-up drivers on data bus lines, and hold pins low during reset. Use an active device to hold data bus lines low. Data bus configuration logic must release the bus before the first bus cycle after reset to prevent conflict with external memory devices. The first bus cycle occurs ten CLKOUT cycles after RESET is released. If external mode selection logic causes a conflict of this type, an isolation resistor on the driven lines may be required. Figure 4-15 shows a recommended method for conditioning the mode select signals. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-39 Freescale Semiconductor, Inc. DATA15 ** ** ** MODE SELECT LINES ** ** ** DATA1 DATA0 VDD VDD * * * ** ** ** RESET Freescale Semiconductor, Inc... DS R/W *Optional, to prevent conflict on RESET negation. DATA BUS MODE DECODE Figure 4-15 Data Bus Mode Select Conditioning Data bus mode select current is specified in APPENDIX A ELECTRICAL CHARACTERISTICS. Do not confuse pin function with pin electrical state. Refer to 4.6.5 Pin State During Reset for more information. DATA0 determines the function of the boot ROM chip-select signal (CSBOOT). Unlike other chip-select signals, CSBOOT is active at the release of reset. During reset exception processing, the MCU fetches initialization vectors beginning at address $000000 in supervisor program space. An external memory device containing vectors located at these addresses can be enabled by CSBOOT after a reset. The logic level of DATA0 during reset selects boot ROM port size for dynamic bus allocation. When DATA0 is held low, port size is eight bits; when DATA0 is held high, either by the weak internal pull-up driver or by an external pull-up, port size is 16 bits. Refer to 4.8.4 ChipSelect Reset Operation for more information. DATA1 and DATA2 determine the functions of CS[2:0] and CS[5:3], respectively. DATA[7:3] determine the functions of an associated chip select and all lower-numbered chip-selects down through CS6. For example, if DATA5 is pulled low during reset, CS[8:6] are assigned alternate function as ADDR[21:19], and CS[10:9] remain chipselects. Refer to 4.8.4 Chip-Select Reset Operation for more information. DATA8 determines the function of the DSACK[1:0], AVEC, DS, AS, and SIZE pins. If DATA8 is held low during reset, these pins are assigned to I/O port E. DATA9 determines the function of interrupt request pins IRQ[7:0] and the clock mode select pin (MODCLK). When DATA9 is held low during reset, these pins are assigned to I/O port F. DATA11 determines whether the SIM operates in test mode out of reset. This capability is used for factory testing of the MCU. SYSTEM INTEGRATION MODULE 4-40 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. 4.6.3.2 Clock Mode Selection The state of the clock mode (MODCLK) pin during reset determines what clock source the MCU uses. When MODCLK is held high during reset, the clock signal is generated from a reference frequency. When MODCLK is held low during reset, the clock synthesizer is disabled, and an external system clock signal must be applied. Refer to 4.3 System Clock for more information. Freescale Semiconductor, Inc... NOTE The MODCLK pin can also be used as parallel I/O pin PF0. To prevent inadvertent clock mode selection by logic connected to port F, use an active device to drive MODCLK during reset. 4.6.3.3 Breakpoint Mode Selection The MCU uses internal and external breakpoint (BKPT) signals. During reset exception processing, at the release of the RESET signal, the CPU32 samples these signals to determine how to handle breakpoints. If either BKPT signal is at logic level zero when sampled, an internal BDM flag is set, and the CPU32 enters background debugging mode whenever either BKPT input is subsequently asserted. If both BKPT inputs are at logic level one when sampled, breakpoint exception processing begins whenever either BKPT signal is subsequently asserted. Refer to SECTION 5 CENTRAL PROCESSING UNIT for more information on background debugging mode and exceptions. Refer to 4.5.4 CPU Space Cycles for information concerning breakpoint acknowledge bus cycles. 4.6.4 MCU Module Pin Function During Reset Usually, module pins default to port functions, and input/output ports are set to input state. This is accomplished by disabling pin functions in the appropriate control registers, and by clearing the appropriate port data direction registers. Refer to individual module sections in this manual for more information. Table 4-17 is a summary of module pin function out of reset. Refer to APPENDIX D REGISTER SUMMARY for register function and reset state. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-41 Freescale Semiconductor, Inc. Table 4-17 Module Pin Functions Module CPU32 GPT Freescale Semiconductor, Inc... QSM Pin Mnemonic DSI/IFETCH DSO/IPIPE BKPT/DSCLK PGP7/IC4/OC5 PGP[6:3]/OC[4:1] PGP[2:0]/IC[3:1] PAI PCLK PWMA, PWMB PQS7/TXD PQS[6:4]/PCS[3:1] PQS3/PCS0/SS PQS2/SCK PQS1/MOSI PQS0/MISO RXD Function DSI/IFETCH DSO/IPIPE BKPT/DSCLK Discrete Input Discrete Input Discrete Input Discrete Input Discrete Input Discrete Output Discrete Input Discrete Input Discrete Input Discrete Input Discrete Input Discrete Input RXD 4.6.5 Pin State During Reset It is important to keep the distinction between pin function and pin electrical state clear. Although control register values and mode select inputs determine pin function, a pin driver can be active, inactive or in high-impedance state while reset occurs. During power-up reset, pin state is subject to the constraints discussed in 4.6.7 Power-On Reset. NOTE Pins that are not used should either be configured as outputs, or (if configured as inputs) pulled to the appropriate inactive state. This decreases additional IDD caused by digital inputs floating near mid-supply level. 4.6.5.1 Reset States of SIM Pins Generally, while RESET is asserted, SIM pins either go to an inactive high-impedance state or are driven to their inactive states. After RESET is released, mode selection occurs, and reset exception processing begins. Pins configured as inputs during reset become active high-impedance loads after RESET is released. Inputs must be driven to the desired active state. Pull-up or pull-down circuitry may be necessary. Pins configured as outputs begin to function after RESET is released. Table 4-18 is a summary of SIM pin states during reset. SYSTEM INTEGRATION MODULE 4-42 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Table 4-18 SIM Pin Reset States Freescale Semiconductor, Inc... Mnemonic CS10/ADDR23 CS[9:6]/ADDR[22:19]/PC[6:3] ADDR[18:0] AS/PE5 AVEC/PE2 BERR CSM/BG CSE/BGACK CS0/BR CLKOUT CSBOOT DATA[15:0] DS/PE4 DSACK0/PE0 DSACK1/PE1 CS5/FC2/PC2 FC1/PC1 CS3/FC0/PC0 HALT IRQ[7:1]/PF[7:1] MODCLK/PF0 R/W RESET RMC SIZ[1:0]/PE[7:6] TSC State While RESET Asserted 1 1 High-Z Output High-Z Output Disabled Disabled 1 1 1 Output 1 Mode Select Disabled Disabled Disabled 1 1 1 Disabled Disabled Mode Select Disabled Asserted Disabled Disabled Mode Select Pin State After RESET Released Pin Pin State Pin Function Function CS10 1 ADDR23 CS[9:6] 1 ADDR[22:19] ADDR[18:0] Unknown ADDR[18:0] AS Output PE5 AVEC Input PE2 BERR Input BERR CSM 1 BG CSE 1 BGACK CS0 1 BR CLKOUT Output CLKOUT CSBOOT 0 CSBOOT DATA[15:0] Input DATA[15:0] DS Output PE4 DSACK0 Input PE0 DSACK1 Input PE1 CS5 1 FC2 FC1 1 FC1 CS3 1 FC0 HALT Input HALT IRQ[7:1] Input PF[7:1] MODCLK Input PF0 R/W Output R/W RESET Input RESET RMC Output PE3 SIZ[1:0] Unknown PE[7:6] TSC Input TSC Pin State Unknown Unknown Unknown Input Input Input 1 Input Input Output 0 Input Input Input Input Unknown Unknown Unknown Input Input Input Output Input Input Input Input 4.6.5.2 Reset States of Pins Assigned to Other MCU Modules As a rule, module pins that are assigned to general-purpose I/O ports go to active highimpedance state following reset. Other pin states are determined by individual module control register settings. Refer to sections concerning modules for details. However, during power-up reset, module port pins may be in an indeterminate state for a short period. Refer to 4.6.7 Power-On Reset for more information. 4.6.6 Reset Timing The RESET input must be asserted for a specified minimum period for reset to occur. External RESET assertion can be delayed internally for a period equal to the longest bus cycle time (or the bus monitor time-out period) in order to protect write cycles from being aborted by reset. While RESET is asserted, SIM pins are either in an inactive, high impedance state or are driven to their inactive states. When an external device asserts RESET for the proper period, reset control logic clocks the signal into an internal latch. The control logic drives the RESET pin low for an additional 512 CLKOUT cycles after it detects that the RESET signal is no longer being externally driven, to guarantee this length of reset to the entire system. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-43 Freescale Semiconductor, Inc. If an internal source asserts a reset signal, the reset control logic asserts RESET for a minimum of 512 cycles. If the reset signal is still asserted at the end of 512 cycles, the control logic continues to assert RESET until the internal reset signal is negated. Freescale Semiconductor, Inc... After 512 cycles have elapsed, the reset input pin goes to an inactive, high-impedance state for ten cycles. At the end of this 10-cycle period, the reset input is tested. When the input is at logic level one, reset exception processing begins. If, however, the reset input is at logic level zero, the reset control logic drives the pin low for another 512 cycles. At the end of this period, the pin again goes to high-impedance state for ten cycles, then it is tested again. The process repeats until RESET is released. 4.6.7 Power-On Reset When the SIM clock synthesizer is used to generate system clocks, power-on reset involves special circumstances related to application of system and clock synthesizer power. Regardless of clock source, voltage must be applied to clock synthesizer power input pin VDDSYN for the MCU to operate. The following discussion assumes that VDDSYN is applied before and during reset, which minimizes crystal start-up time. When VDDSYN is applied at power-on, start-up time is affected by specific crystal parameters and by oscillator circuit design. VDD ramp-up time also affects pin state during reset. Refer to APPENDIX A ELECTRICAL CHARACTERISTICS for voltage and timing specifications. During power-on reset, an internal circuit in the SIM drives the IMB internal (MSTRST) and external (EXTRST) reset lines. The circuit releases MSTRST as VDD ramps up to the minimum specified value, and SIM pins are initialized as shown in Table 4-19. As VDD reaches specified minimum value, the clock synthesizer VCO begins operation and clock frequency ramps up to specified limp mode frequency. The external RESET line remains asserted until the clock synthesizer PLL locks and 512 CLKOUT cycles elapse. The SIM clock synthesizer provides clock signals to the other MCU modules. After the clock is running and MSTRST is asserted for at least four clock cycles, these modules reset. VDD ramp time and VCO frequency ramp time determine how long the four cycles take. Worst case is approximately 15 milliseconds. During this period, module port pins may be in an indeterminate state. While input-only pins can be put in a known state by external pull-up resistors, external logic on input/output or output-only pins during this time must condition the lines. Active drivers require high-impedance buffers or isolation resistors to prevent conflict. Figure 4-16 is a timing diagram of power-up reset. It shows the relationships between RESET, VDD, and bus signals. SYSTEM INTEGRATION MODULE 4-44 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. CLKOUT VCO LOCK VDD 512 CLOCKS 10 CLOCKS RESET Freescale Semiconductor, Inc... BUS CYCLES BUS STATE UNKNOWN ADDRESS AND CONTROL SIGNALS THREE-STATED 1 2 3 4 NOTES: 1. Internal start-up time. 2. SSP fetched. 3. PC fetched. 4. First instruction fetched. 32 POR TIM Figure 4-16 Power-On Reset 4.6.8 Reset Processing Summary To prevent write cycles in progress from being corrupted, a reset is recognized at the end of a bus cycle, and not at an instruction boundary. Any processing in progress at the time a reset occurs is aborted. After SIM reset control logic has synchronized an internal or external reset request, it asserts the MSTRST signal. The following events take place when MSTRST is asserted. A. Instruction execution is aborted. B. The status register is initialized. 1. The T0 and T1 bits are cleared to disable tracing. 2. The S bit is set to establish supervisor privilege level. 3. The interrupt priority mask is set to $7, disabling all interrupts below priority 7. C. The vector base register is initialized to $000000. The following events take place when MSTRST is negated after assertion. A. The CPU32 samples the BKPT input. B. The CPU32 fetches the reset vector: 1. The first long word of the vector is loaded into the interrupt stack pointer. 2. The second long word of the vector is loaded into the program counter. Vectors can be fetched from internal RAM or from external ROM enabled by the CSBOOT signal. C. The CPU32 fetches and begins decoding the first instruction to be executed. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-45 Freescale Semiconductor, Inc. 4.6.9 Reset Status Register The reset status register (RSR) contains a bit for each reset source in the MCU. When a reset occurs, a bit corresponding to the reset type is set. When multiple causes of reset occur at the same time, more than one bit in RSR may be set. The reset status register is updated by the reset control logic when the RESET signal is released. Refer to APPENDIX D REGISTER SUMMARY. Freescale Semiconductor, Inc... 4.7 Interrupts Interrupt recognition and servicing involve complex interaction between the system integration module, the central processing unit, and a device or module requesting interrupt service. This discussion provides an overview of the entire interrupt process. Chip-select logic can also be used to respond to interrupt requests. Refer to 4.8 Chip Selects for more information. 4.7.1 Interrupt Exception Processing The CPU32 processes resets as a type of asynchronous exception. An exception is an event that preempts normal processing. Each exception has an assigned vector in an exception vector table that points to an associated handler routine. The CPU uses vector numbers to calculate displacement into the table. During exception processing, the CPU fetches the appropriate vector and executes the exception handler routine to which the vector points. Out of reset, the exception vector table is located beginning at address $000000. This value can be changed by programming the vector base register (VBR) with a new value, and multiple vector tables can be used. Refer to SECTION 5 CENTRAL PROCESSING UNIT for more information concerning exceptions. 4.7.2 Interrupt Priority and Recognition The CPU32 provides eight levels of interrupt priority. All interrupts with priorities less than seven can be masked by the interrupt priority (IP) field in status register. There are seven interrupt request signals (IRQ[7:1]). These signals are used internally on the IMB, and are corresponding pins for external interrupt service requests. The CPU treats all interrupt requests as though they come from internal modules -- external interrupt requests are treated as interrupt service requests from the SIM. Each of the interrupt request signals corresponds to an interrupt priority level. IRQ1 has the lowest priority and IRQ7 the highest. Interrupt recognition is determined by interrupt priority level and interrupt priority mask value. The interrupt priority mask consists of three bits in the CPU32 status register. Binary values %000 to %111 provide eight priority masks. Masks prevent an interrupt request of a priority less than or equal to the mask value from being recognized and processed. IRQ7, however, is always recognized, even if the mask value is %111. IRQ[7:1] are active-low level-sensitive inputs. The low on the pin must remain asserted until an interrupt acknowledge cycle corresponding to that level is detected. SYSTEM INTEGRATION MODULE 4-46 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. IRQ7 is transition-sensitive as well as level-sensitive: a level-7 interrupt is not detected unless a falling edge transition is detected on the IRQ7 line. This prevents redundant servicing and stack overflow. A nonmaskable interrupt is generated each time IRQ7 is asserted as well as each time the priority mask changes from %111 to a lower number while IRQ7 is asserted. Freescale Semiconductor, Inc... Interrupt requests are sampled on consecutive falling edges of the system clock. Interrupt request input circuitry has hysteresis: to be valid, a request signal must be asserted for at least two consecutive clock periods. Valid requests do not cause immediate exception processing, but are left pending. Pending requests are processed at instruction boundaries or when exception processing of higher-priority exceptions is complete. The CPU32 does not latch the priority of a pending interrupt request. If an interrupt source of higher priority makes a service request while a lower priority request is pending, the higher priority request is serviced. If an interrupt request with a priority equal to or lower than the current IP mask value is made, the CPU32 does not recognize the occurrence of the request. If simultaneous interrupt requests of different priorities are made, and both have a priority greater than the mask value, the CPU32 recognizes the higher-level request. 4.7.3 Interrupt Acknowledge and Arbitration When the CPU32 detects one or more interrupt requests of a priority higher than the interrupt priority mask value, it places the interrupt request level on the address bus and initiates a CPU space read cycle. The request level serves two purposes: it is decoded by modules or external devices that have requested interrupt service, to determine whether the current interrupt acknowledge cycle pertains to them, and it is latched into the interrupt priority mask field in the CPU32 status register, to preclude further interrupts of lower priority during interrupt service. Modules or external devices that have requested interrupt service must decode the interrupt priority mask value placed on the address bus during the interrupt acknowledge cycle and respond if the priority of the service request corresponds to the mask value. However, before modules or external devices respond, interrupt arbitration takes place. Arbitration is performed by means of serial contention between values stored in individual module interrupt arbitration (IARB) fields. Each module that can make an interrupt service request, including the SIM, has an IARB field in its configuration register. IARB fields can be assigned values from %0000 to %1111. In order to implement an arbitration scheme, each module that can initiate an interrupt service request must be assigned a unique, non-zero IARB field value during system initialization. Arbitration priorities range from %0001 (lowest) to %1111 (highest) -- if the CPU recognizes an interrupt service request from a source that has an IARB field value of %0000, a spurious interrupt exception is processed. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-47 Freescale Semiconductor, Inc. WARNING Do not assign the same arbitration priority to more than one module. When two or more IARB fields have the same nonzero value, the CPU32 interprets multiple vector numbers at the same time, with unpredictable consequences. Freescale Semiconductor, Inc... Because the EBI manages external interrupt requests, the SIM IARB value is used for arbitration between internal and external interrupt requests. The reset value of IARB for the SIM is %1111, and the reset IARB value for all other modules is %0000. Although arbitration is intended to deal with simultaneous requests of the same priority, it always takes place, even when a single source is requesting service. This is important for two reasons: the EBI does not transfer the interrupt acknowledge read cycle to the external bus unless the SIM wins contention, and failure to contend causes the interrupt acknowledge bus cycle to be terminated early, by a bus error. When arbitration is complete, the module with the highest arbitration priority must terminate the bus cycle. Internal modules place an interrupt vector number on the data bus and generate appropriate internal cycle termination signals. In the case of an external interrupt request, after the interrupt acknowledge cycle is transferred to the external bus, the appropriate external device must decode the mask value and respond with a vector number, then generate data and size acknowledge (DSACK) termination signals, or it must assert the autovector (AVEC) request signal. If the device does not respond in time, the EBI bus monitor asserts the bus error signal BERR, and a spurious interrupt exception is taken. Chip-select logic can also be used to generate internal AVEC or DSACK signals in response to interrupt requests from external devices (refer to 4.8.3 Using Chip-Select Signals for Interrupt Acknowledge). Chip-select address match logic functions only after the EBI transfers an interrupt acknowledge cycle to the external bus following IARB contention. If a module makes an interrupt request of a certain priority, and the appropriate chip-select registers are programmed to generate AVEC or DSACK signals in response to an interrupt acknowledge cycle for that priority level, chip-select logic does not respond to the interrupt acknowledge cycle, and the internal module supplies a vector number and generates internal cycle termination signals. For periodic timer interrupts, the PIRQ field in the periodic interrupt control register (PICR) determines PIT priority level. A PIRQ value of %000 means that PIT interrupts are inactive. By hardware convention, when the CPU32 receives simultaneous interrupt requests of the same level from more than one SIM source (including external devices), the periodic interrupt timer is given the highest priority, followed by the IRQ pins. 4.7.4 Interrupt Processing Summary A summary of the entire interrupt processing sequence follows. When the sequence begins, a valid interrupt service request has been detected and is pending. A. The CPU finishes higher priority exception processing or reaches an instruction boundary. SYSTEM INTEGRATION MODULE 4-48 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc... Freescale Semiconductor, Inc. B. The processor state is stacked. The S bit in the status register is set, establishing supervisor access level, and bits T1 and T0 are cleared, disabling tracing. C. The interrupt acknowledge cycle begins: 1. FC[2:0] are driven to %111 (CPU space) encoding. 2. The address bus is driven as follows: ADDR[23:20] = %1111; ADDR[19:16] = %1111, which indicates that the cycle is an interrupt acknowledge CPU space cycle; ADDR[15:4] = %111111111111; ADDR[3:1] = the priority of the interrupt request being acknowledged; and ADDR0 = %1. 3. The request level is latched from the address bus into the interrupt priority mask field in the status or condition code register. D. Modules that have requested interrupt service decode the priority value in ADDR[3:1]. If request priority is the same as acknowledged priority, arbitration by IARB contention takes place. E. After arbitration, the interrupt acknowledge cycle is completed in one of the following ways: 1. When there is no contention (IARB = %0000), the spurious interrupt monitor asserts BERR, and the CPU generates the spurious interrupt vector number. 2. The dominant interrupt source supplies a vector number and DSACK signals appropriate to the access. The CPU acquires the vector number. 3. The AVEC signal is asserted (the signal can be asserted by the dominant interrupt source or the pin can be tied low), and the CPU generates an autovector number corresponding to interrupt priority. 4. The bus monitor asserts BERR and the CPU32 generates the spurious interrupt vector number. F. The vector number is converted to a vector address. G. The content of the vector address is loaded into the PC, and the processor transfers control to the exception handler routine. 4.7.5 Interrupt Acknowledge Bus Cycles Interrupt acknowledge bus cycles are CPU32 space cycles that are generated during exception processing. For further information about the types of interrupt acknowledge bus cycles determined by AVEC or DSACK, refer to APPENDIX A ELECTRICAL CHARACTERISTICS and the SIM Reference Manual (SIMRM/AD). 4.8 Chip Selects Typical microcontrollers require additional hardware to provide external chip-select and address decode signals. The MCU includes 12 programmable chip-select circuits that can provide 2- to 20-clock-cycle access to external memory and peripherals. Address block sizes of two Kbytes to one Mbyte can be selected. Figure 4-17 is a diagram of a basic system that uses chip selects. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-49 Freescale Semiconductor, Inc. 1 FC SIZ CLKOUT AS DSACK DS CS3 CS5 IRQ ADDR[23:0] DATA[15:0] SIZ CLK AS DSACK DS CS IACK IRQ 2 ADDR[15:0] DATA[15:0] MEMORY MCU Freescale Semiconductor, Inc... ASYNC BUS PERIPHERAL CSBOOT R/W ADDR[23:0] DATA[15:8] CS R/W 2 MEMORY ADDR[23:0] DATA[7:0] CS R/W 2 1. Can be decoded to provide additional address space. 2. Varies depending upon peripheral memory size. 32 EXAMPLE SYS BLOCK Figure 4-17 Basic MCU System Chip-select assertion can be synchronized with bus control signals to provide output enable, read/write strobe, or interrupt acknowledge signals. Chip select logic can also generate DSACK and AVEC signals internally. Each signal can also be synchronized with the ECLK signal available on ADDR23. When a memory access occurs, chip-select logic compares address space type, address, type of access, transfer size, and interrupt priority (in the case of interrupt acknowledge) to parameters stored in chip-select registers. If all parameters match, the appropriate chip-select signal is asserted. Select signals are active low. If a chip-select function is given the same address as a microcontroller module or an internal memory array, an access to that address goes to the module or array, and the chip-select signal is not asserted. The external address and data buses do not reflect the internal access. All chip-select circuits are configured for operation out of reset. However, all chip-select signals except CSBOOT are disabled, and cannot be asserted until the BYTE field SYSTEM INTEGRATION MODULE 4-50 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. Freescale Semiconductor, Inc... in the corresponding option register is programmed to a nonzero value, selecting a transfer size. The chip-select option must not be written until a base address has been written to a proper base address register. CSBOOT is automatically asserted out of reset. Alternate functions for chip-select pins are enabled if appropriate data bus pins are held low at the release of the reset signal (refer to 4.6.3.1 Data Bus Mode Selection for more information). Figure 4-18 is a functional diagram of a single chip-select circuit. INTERNAL SIGNALS BASE ADDRESS REGISTER ADDRESS ADDRESS COMPARATOR BUS CONTROL OPTION COMPARE TIMING AND CONTROL PIN OPTION REGISTER AVEC AVEC GENERATOR DSACK GENERATOR PIN ASSIGNMENT REGISTER PIN DATA REGISTER DSACK CHIP SEL BLOCK Figure 4-18 Chip-Select Circuit Block Diagram 4.8.1 Chip-Select Registers Each chip-select pin can have one or more functions. Chip-select pin assignment registers (CSPAR[0:1]) determine functions of the pins. Pin assignment registers also determine port size (8- or 16-bit) for dynamic bus allocation. A pin data register (PORTC) latches data for chip-select pins that are used for discrete output. Blocks of addresses are assigned to each chip-select function. Block sizes of two Kbytes to one Mbyte can be selected by writing values to the appropriate base address register (CSBAR[0:10], CSBARBT). Address blocks for separate chip-select functions can overlap. Chip select option registers (CSOR[0:10], CSORBT) determine timing of and conditions for assertion of chip-select signals. Eight parameters, including operating mode, access size, synchronization, and wait state insertion can be specified. Initialization software usually resides in a peripheral memory device controlled by the chip-select circuits. A set of special chip-select functions and registers (CSORBT, CSBARBT) is provided to support bootstrap operation. Comprehensive address maps and register diagrams are provided in APPENDIX D REGISTER SUMMARY. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-51 Freescale Semiconductor, Inc. 4.8.1.1 Chip-Select Pin Assignment Registers The pin assignment registers contain twelve 2-bit fields (CS[10:0] and CSBOOT) that determine the functions of the chip-select pins. Each pin has two or three possible functions, as shown in Table 4-19. Freescale Semiconductor, Inc... Table 4-19 Chip-Select Pin Functions 16-Bit Chip Select CSBOOT CS0 CS1 CS2 CS3 CS4 CS5 CS6 CS7 CS8 CS9 CS10 8-Bit Chip Select CSBOOT CS0 CS1 CS2 CS3 CS4 CS5 CS6 CS7 CS8 CS9 CS10 Alternate Function CSBOOT BR BG BGACK FC0 FC1 FC2 ADDR19 ADDR20 ADDR21 ADDR22 ADDR23 Discrete Output -- -- -- -- PC0 PC1 PC2 PC3 PC4 PC5 PC6 ECLK Table 4-20 shows pin assignment field encoding. Pins that have no discrete output function do not use the %00 encoding. Table 4-20 Pin Assignment Field Encoding Bit Field 00 01 10 11 Description Discrete Output Alternate Function Chip Select (8-Bit Port) Chip Select (16-Bit Port) Port size determines the way in which bus transfers to an external address are allocated. Port size of eight bits or sixteen bits can be selected when a pin is assigned as a chip select. Port size and transfer size affect how the chip-select signal is asserted. Refer to 4.8.1.3 Chip-Select Option Registers for more information. Out of reset, chip-select pin function is determined by the logic level on a corresponding data bus pin. These pins have weak internal pull-up drivers, but can be held low by external devices. (Refer to 4.6.3.1 Data Bus Mode Selection for more information.) Either 16-bit chip-select function (%11) or alternate function (%01) can be selected during reset. All pins except the boot ROM select pin (CSBOOT) are disabled out of reset. There are twelve chip-select functions and only eight associated data bus pins. There is not a one-to-one correspondence. Refer to 4.8.4 Chip-Select Reset Operation for more detailed information. The CSBOOT signal is normally enabled out of reset. The state of the DATA0 line during reset determines what port width CSBOOT uses. If DATA0 is held high (either by the weak internal pull-up driver or by an external pull-up device), 16-bit width is selected. If DATA0 is held low, 8-bit port size is selected. SYSTEM INTEGRATION MODULE 4-52 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. A pin programmed as a discrete output drives an external signal to the value specified in the pin data register. No discrete output function is available on pins CSBOOT, BR, BG, or BGACK. ADDR23 provides ECLK output rather than a discrete output signal. When a pin is programmed for discrete output or alternate function, internal chip-select logic still functions and can be used to generate DSACK or AVEC internally on an address and control signal match. Freescale Semiconductor, Inc... 4.8.1.2 Chip-Select Base Address Registers Each chip select has an associated base address register. A base address is the lowest address in the block of addresses enabled by a chip select. Block size is the extent of the address block above the base address. Block size is determined by the value contained in a BLKSZ field. Block addresses for different chip selects can overlap. The BLKSZ field determines which bits in the base address field are compared to corresponding bits on the address bus during an access. Provided other constraints determined by option register fields are also satisfied, when a match occurs, the associated chip-select signal is asserted. Table 4-21 shows BLKSZ encoding. Table 4-21 Block Size Encoding BLKSZ[2:0] 000 001 010 011 100 101 110 111 Block Size 2 Kbyte 8 Kbyte 16 Kbyte 64 Kbyte 128 Kbyte 256 Kbyte 512 Kbyte 1 Mbyte Address Lines Compared ADDR[23:11] ADDR[23:13] ADDR[23:14] ADDR[23:16] ADDR[23:17] ADDR[23:18] ADDR[23:19] ADDR[23:20] The chip-select address compare logic uses only the most significant bits to match an address within a block. The value of the base address must be a multiple of block size. Base address register diagrams show how base register bits correspond to address lines. After reset, the MCU fetches the initialization routine from the address contained in the reset vector, located beginning at address $000000 of program space. To support bootstrap operation from reset, the base address field in chip-select base address register boot (CSBARBT) has a reset value of all zeros. A memory device containing the reset vector and initialization routine can be automatically enabled by CSBOOT after a reset. The block size field in CSBARBT has a reset value of 512 Kbytes. Refer to 4.8.4 Chip-Select Reset Operation for more information. 4.8.1.3 Chip-Select Option Registers Option register fields determine timing of and conditions for assertion of chip-select signals. To assert a chip-select signal, and to provide DSACK or autovector support, other constraints set by fields in the option register and in the base address register must also be satisfied. Table 4-22 is a summary of option register functions. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-53 Freescale Semiconductor, Inc. Table 4-22 Option Register Function Summary Freescale Semiconductor, Inc... MODE 0 = ASYNC* 1 = SYNC BYTE 00 = Disable 01 = Lower 10 = Upper *11 = Both R/W STRB 00 = Rsvd 0 = AS 01 = Read 1 = DS 10 = Write 11 = Both DSACK 0000 = 0 WAIT 0001 = 1 WAIT 0010 = 2 WAIT 0011 = 3 WAIT 0100 = 4 WAIT 0101 = 5 WAIT 0110 = 6 WAIT 0111 = 7 WAIT 1000 = 8 WAIT 1001 = 9 WAIT 1010 = 10 WAIT 1011 = 11 WAIT 1100 = 12 WAIT 1101 = 13 WAIT 1110 = F term 1111 = External SPACE 00 = CPU SP 01 = User SP 10 = Supv SP 11 = S/U SP* IPL 000 = All* 001 = Priority 1 010 = Priority 2 011 = Priority 3 100 = Priority 4 101 = Priority 5 110 = Priority 6 111 = Priority 7 AVEC 0 = Off* 1 = On *Use this value when function is not required for chip-select operation. The MODE bit determines whether chip-select assertion simulates an asynchronous bus cycle, or is synchronized to the M6800-type bus clock signal (ECLK) available on ADDR23 (refer to 4.3 System Clock for more information on ECLK). The BYTE field controls bus allocation for chip-select transfers. Port size, set when a chip select is enabled by a pin assignment register, affects signal assertion. When an 8-bit port is assigned, any BYTE field value other than %00 enables the chip select signal. When a 16-bit port is assigned, however, BYTE field value determines when the chip select is enabled. The BYTE fields for CS[10:0] are cleared during reset. However, both bits in the boot ROM option register (CSORBT) BYTE field are set (%11) when the reset signal is released. The R/W field causes a chip-select signal to be asserted only for a read, only for a write, or for both read and write. Use this field in conjunction with the STRB bit to generate asynchronous control signals for external devices. The STRB bit controls the timing of a chip-select assertion in asynchronous mode. Selecting address strobe causes a chip-select signal to be asserted synchronized with the address strobe. Selecting data strobe causes a chip-select signal to be asserted synchronized with the data strobe. This bit has no effect in synchronous mode. The DSACK field specifies the source of data strobe acknowledge signals used in asynchronous mode. It also allows the user to optimize bus speed in a particular application by controlling the number of wait states that are inserted. The SPACE field determines the address space in which a chip select is asserted. An access must have the space type represented by SPACE encoding in order for a chipselect signal to be asserted. The IPL field contains an interrupt priority mask that is used when chip-select logic is set to trigger on external interrupt acknowledge cycles. When the SPACE field is set SYSTEM INTEGRATION MODULE 4-54 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. to %00 (CPU space), interrupt priority (ADDR[3:1]) is compared to IPL value. If the values are the same, and other option register constraints are satisfied, a chip select signal is asserted. This field only affects the response of chip selects and does not affect interrupt recognition by the CPU. Encoding %000 causes a chip-select signal to be asserted regardless of interrupt acknowledge cycle priority, provided all other constraints are met. Freescale Semiconductor, Inc... The AVEC bit selects one of two methods of acquiring an interrupt vector during an external interrupt acknowledge cycle. The internal autovector signal is generated only in response to interrupt requests from the SIM IRQ pins. 4.8.1.4 PORTC Data Register The PORTC data register latches data for PORTC pins programmed as discrete outputs. When a pin is assigned as a discrete output, the value in this register appears at the output. PC[6:0] correspond to CS[9:3]. Bit 7 is not used. Writing to this bit has no effect, and it always reads zero. 4.8.2 Chip-Select Operation When the MCU makes an access, enabled chip-select circuits compare the following items: 1. Function codes to SPACE fields, and to the IPL field if the SPACE field encoding is not for CPU32 space. 2. Appropriate ADDR bits to base address fields. 3. Read/write status to R/W fields. 4. ADDR0 and/or SIZ bits to the BYTE field (16-bit ports only). 5. Priority of the interrupt being acknowledged (ADDR[3:1]) to IPL fields (when the access is an interrupt acknowledge cycle). When a match occurs, the chip-select signal is asserted. Assertion occurs at the same time as AS or DS assertion in asynchronous mode. Assertion is synchronized with ECLK in synchronous mode. In asynchronous mode, the value of the DSACK field determines whether DSACK is generated internally.DSACK also determines the number of wait states inserted before internal DSACK assertion. The speed of an external device determines whether internal wait states are needed. Normally, wait states are inserted into the bus cycle during S3 until a peripheral asserts DSACK. If a peripheral does not generate DSACK, internal DSACK generation must be selected and a predetermined number of wait states can be programmed into the chip-select option register. Refer to the SIM Reference Manual (SIMRM/AD) for further information. 4.8.3 Using Chip-Select Signals for Interrupt Acknowledge Ordinary I/O bus cycles use supervisor space access, but interrupt acknowledge bus cycles use CPU space access. Refer to 4.5.4 CPU Space Cycles and 4.7 Interrupts for more information. There are no differences in flow for chip selects in each type of space, but base and option registers must be properly programmed for each type of external bus cycle. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-55 Freescale Semiconductor, Inc. During a CPU space cycle, bits [15:3] of the appropriate base register must be configured to match ADDR[23:11], as the address is compared to an address generated by the CPU. Figure 4-19 shows CPU space encoding for an interrupt acknowledge cycle. FC[2:0] are set to %111, designating CPU space access. ADDR[3:1] indicate interrupt priority, and the space type field (ADDR[19:16]) is set to %1111, the interrupt acknowledge code. The rest of the address lines are set to one. Freescale Semiconductor, Inc... INTERRUPT ACKNOWLEDGE FUNCTION CODE ADDRESS BUS 2 0 1 1 1 23 19 16 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 LEVEL 1 CPU SPACE TYPE FIELD CPU SPACE IACK TIM Figure 4-19 CPU Space Encoding for Interrupt Acknowledge Because address match logic functions only after the EBI transfers an interrupt acknowledge cycle to the external address bus following IARB contention, chip-select logic generates AVEC or DSACK signals only in response to interrupt requests from external IRQ pins. If an internal module makes an interrupt request of a certain priority, and the chip-select base address and option registers are programmed to generate AVEC or DSACK signals in response to an interrupt acknowledge cycle for that priority level, chip-select logic does not respond to the interrupt acknowledge cycle, and the internal module supplies a vector number and generates an internal DSACK signal to terminate the cycle. Perform the following operations before using a chip select to generate an interrupt acknowledge signal. 1. Program the base address field to all ones. 2. Program block size to no more than 64 Kbytes, so that the address comparator checks ADDR[19:16] against the corresponding bits in the base address register. (The CPU32 places the CPU32 space type on ADDR[19:16].) 3. Set the R/W field to read only. An interrupt acknowledge cycle is performed as a read cycle. 4. Set the BYTE field to lower byte when using a 16-bit port, as the external vector for a 16-bit port is fetched from the lower byte. Set the BYTE field to upper byte when using an 8-bit port. If an interrupting device does not provide a vector number, an autovector acknowledge must be generated. Asserting AVEC, either by asserting the AVEC pin or by generating AVEC internally using the chip-select option register, terminates the bus cycle. 4.8.4 Chip-Select Reset Operation The least significant bits of each of the 2-bit CS[10:0] pin assignment fields in CSPAR0 and CSPAR1 each have a reset value of one. The reset values of the most significant bits of each field are determined by the states of DATA[7:1] during reset. There are SYSTEM INTEGRATION MODULE 4-56 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. weak internal pull-up drivers for each of the data lines, so that chip-select operation will be selected by default out of reset. However, the internal pull-up drivers can be overcome by bus loading effects -- to insure a particular configuration out of reset, use an active device to put the data lines in a known state during reset. The base address fields in chip-select base address registers CSBAR[0:10] and chip select option registers CSOR[0:10] have the reset values shown in Table 4-23. The BYTE fields of CSOR[0:10] have a reset value of "disable", so that a chip-select signal cannot be asserted until the base and option registers are initialized. Freescale Semiconductor, Inc... Table 4-23 Chip Select Base and Option Register Reset Values Fields Base Address Block Size Async/Sync Mode Upper/Lower Byte Read/Write AS/DS DSACK Address Space IPL Autovector Reset Values $000000 2 Kbyte Asynchronous Mode Disabled Reserved AS No Wait States CPU Space Any Level External Interrupt Vector Following reset, the MCU fetches initial stack pointer and program counter values from the exception vector table, beginning at $000000 in supervisor program space. The CSBOOT chip-select signal is used to select an external boot ROM mapped to a base address of $000000. In order to do this, the reset values of the fields that control CSBOOT must be different from those of other chip select signals. The MSB of the CSBOOT field in CSPAR0 has a reset value of one, so that chip-select function is selected by default out of reset. The BYTE field in option register CSORBT has a reset value of "both bytes" so that the select signal is enabled out of reset. The LSB value of the CSBOOT field, determined by the logic level of DATA0 during reset, selects boot ROM port size. When DATA0 is held low during reset, port size is eight bits. When DATA0 is held high during reset, port size is 16 bits. DATA0 has a weak internal pull-up driver, so that a 16-bit port will be selected by default out of reset. However, the internal pull-up driver can be overcome by bus loading effects --to insure a particular configuration out of reset, use an active device to put DATA0 in a known state during reset. The base address field in chip-select base address register boot (CSBARBT) has a reset value of all zeros, so that when the initial access to address $000000 is made, an address match occurs, and the CSBOOT signal is asserted. The block size field in CSBARBT has a reset value of 1 Mbyte. Table 4-24 shows CSBOOT reset values. MC68332 USER'S MANUAL SYSTEM INTEGRATION MODULE For More Information On This Product, Go to: www.freescale.com 4-57 Freescale Semiconductor, Inc. Table 4-24 CSBOOT Base and Option Register Reset Values Freescale Semiconductor, Inc... Fields Base Address Block Size Async/Sync Mode Upper/Lower Byte Read/Write AS/DS DSACK Address Space IPL Autovector Reset Values $000000 1 Mbyte Asynchronous Mode Both Bytes Read/Write AS 13 Wait States Supervisor/User Space Any Level Interrupt Vector Externally 4.9 Parallel Input/Output Ports Fifteen SIM pins can be configured for general-purpose discrete input and output. Although these pins are organized into two ports, port E and port F, function assignment is by individual pin. Pin assignment registers, data direction registers, and data registers are used to implement discrete I/O. 4.9.1 Pin Assignment Registers Bits in the port E and port F pin assignment registers (PEPAR and PFPAR) control the functions of the pins in each port. Any bit set to one defines the corresponding pin as a bus control signal. Any bit cleared to zero defines the corresponding pin as an I/O pin. 4.9.2 Data Direction Registers Bits in the port E and port F data direction registers (DDRE and DDRF) control the direction of the pin drivers when the pins are configured as I/O. Any bit in a register set to one configures the corresponding pin as an output. Any bit in a register cleared to zero configures the corresponding pin as an input. These registers can be read or written at any time. Writes have no effect. 4.9.3 Data Registers A write to the port E and port F data registers (PORTE and PORTF) is stored in an internal data latch, and if any pin in the corresponding port is configured as an output, the value stored for that bit is driven out on the pin. A read of a data register returns the value at the pin only if the pin is configured as a discrete input. Otherwise, the value read is the value stored in the register. Both data registers can be accessed in two locations. Registers can be read or written at any time. 4.10 Factory Test The test submodule supports scan-based testing of the various MCU modules. It is integrated into the SIM to support production test. Test submodule registers are intended for Freescale use only. Register names and addresses are provided in APPENDIX D REGISTER SUMMARY to show the user that these addresses are occupied. The QUOT pin is also used for factory test. SYSTEM INTEGRATION MODULE 4-58 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. SECTION 5 CENTRAL PROCESSING UNIT Freescale Semiconductor, Inc... The CPU32, the instruction processing module of the M68300 family, is based on the industry-standard MC68000 processor. It has many features of the MC68010 and MC68020, as well as unique features suited for high-performance controller applications. This section is an overview of the CPU32. For detailed information concerning CPU operation, refer to the CPU32 Reference Manual (CPU32RM/AD). 5.1 General Ease of programming is an important consideration in using a microcontroller. The CPU32 instruction format reflects a philosophy emphasizing register-memory interaction. There are eight multifunction data registers and seven general-purpose addressing registers. All data resources are available to all operations requiring those resources. The data registers readily support 8-bit (byte), 16-bit (word), and 32-bit (long-word) operand lengths for all operations. Word and long-word operations support address manipulation. Although the program counter (PC) and stack pointers (SP) are special-purpose registers, they are also available for most data addressing activities. Ease of program checking and diagnosis is further enhanced by trace and trap capabilities at the instruction level. A block diagram of the CPU32 is shown in Figure 5-1. The major blocks operate in a highly independent fashion that maximizes concurrence of operation while managing the essential synchronization of instruction execution and bus operation. The bus controller loads instructions from the data bus into the decode unit. The sequencer and control unit provide overall chip control, managing the internal buses, registers, and functions of the execution unit. MC68332 USER'S MANUAL CENTRAL PROCESSING UNIT For More Information On This Product, Go to: www.freescale.com 5-1 Freescale Semiconductor, Inc. DECODE BUFFER STAGE C STAGE B STAGE A INSTRUCTION PIPELINE Freescale Semiconductor, Inc... CONTROL STORE PROGRAM COUNTER SECTION DATA SECTION CONTROL LOGIC EXECUTION UNIT MICROSEQUENCER AND CONTROL WRITE PENDING BUFFER PREFETCH CONTROLLER MICROBUS CONTROLLER ADDRESS BUS BUS CONTROL SIGNALS DATA BUS 1127A Figure 5-1 CPU32 Block Diagram 5.2 CPU32 Registers The CPU32 programming model consists of two groups of registers that correspond to the user and supervisor privilege levels. User programs can use only the registers of the user model. The supervisor programming model, which supplements the user programming model, is used by CPU32 system programmers who wish to protect sensitive operating system functions. The supervisor model is identical to that of the MC68010 and later processors. The CPU32 has eight 32-bit data registers, seven 32-bit address registers, a 32-bit program counter, separate 32-bit supervisor and user stack pointers, a 16-bit status register, two alternate function code registers, and a 32-bit vector base register (see Figure 5-2 and Figure 5-3). CENTRAL PROCESSING UNIT 5-2 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. 31 16 15 8 7 0 D0 D1 D2 D3 D4 D5 D6 D7 Freescale Semiconductor, Inc... 31 16 15 0 A0 A1 A2 A3 A4 A5 A6 31 DATA REGISTERS 16 15 ADDRESS REGISTERS 0 A7 (USP) USER STACK POINTER 31 0 7 PC PROGRAM COUNTER CCR CONDITION CODE REGISTER 0 Figure 5-2 User Programming Model 31 16 15 0 A7' (SSP) SUPERVISOR STACK POINTER 15 8 7 0 (CCR) 31 SR STATUS REGISTER VBR VECTOR BASE REGISTER SFC DFC ALTERNATE FUNCTION CODE REGISTERS 0 2 0 Figure 5-3 Supervisor Programming Model Supplement 5.2.1 Data Registers The eight data registers can store data operands of 1, 8, 16, 32, and 64 bits and addresses of 16 or 32 bits. The following data types are supported: * Bits * Packed Binary-Coded Decimal Digits * Byte Integers (8 bits) * Word Integers (16 bits) * Long-Word Integers (32 bits) * Quad-Word Integers (64 bits) MC68332 USER'S MANUAL CENTRAL PROCESSING UNIT For More Information On This Product, Go to: www.freescale.com 5-3 Freescale Semiconductor, Inc. Each of data registers D7-D0 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. When a data register is used as either a source or destination operand, only the appropriate low-order byte or word (in byte or word operations, respectively) is used or changed; the remaining high-order portion is unaffected. The least significant bit (LSB) of a long-word integer is addressed as bit zero, and the most significant bit (MSB) is addressed as bit 31. Figure 5-4 shows the organization of various types of data in the data registers. Freescale Semiconductor, Inc... Quad-word data consists of two long words and represents the product of 32-bit multiply or the dividend of 32-bit divide operations (signed and unsigned). Quad-words may be organized in any two data registers without restrictions on order or pairing. There are no explicit instructions for the management of this data type, although the MOVEM instruction can be used to move a quad-word into or out of the registers. Binary-coded decimal (BCD) data represents decimal numbers in binary form. CPU32 BCD instructions use a format in which a byte contains two digits. The four LSB contain the least significant digit, and the four MSB contain the most significant digit. The ABCD, SBCD, and NBCD instructions operate on two BCD digits packed into a single byte. 31 MSB 30 1 0 LSB BYTE 31 24 23 16 15 8 7 0 HIGH-ORDER BYTE MIDDLE HIGH BYTE MIDDLE LOW BYTE LOW-ORDER BYTE 16-BIT WORD 31 16 15 HIGH-ORDER BYTE 0 LOW-ORDER WORD LONG-WORD 31 LONG-WORD 0 QUAD-WORD 63 62 MSB 32 ANY Dy 31 1 ANY Dy 0 LSB Figure 5-4 Data Organization in Data Registers CENTRAL PROCESSING UNIT 5-4 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. 5.2.2 Address Registers Each address register and stack pointer is 32 bits wide and holds a 32-bit address. Address registers cannot be used for 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 source operand is a word size, it is sign-extended to 32 bits. Address registers are used primarily for addresses and to support address computation. The instruction set includes instructions that add to, subtract from, compare, and move the contents of address registers. Figure 5-5 shows the organization of addresses in address registers. Freescale Semiconductor, Inc... 31 16 SIGN EXTENDED 150 16-BIT ADDRESS OPERAND 31 0 FULL 32-BIT ADDRESS OPERAND Figure 5-5 Address Organization in Address Registers 5.2.3 Program Counter The PC contains the address of the next instruction to be executed by the CPU32. During instruction execution and exception processing, the processor automatically increments the contents of the PC or places a new value in the PC as appropriate. 5.2.4 Control Registers The control registers described in this section contain control information for supervisor functions and vary in size. With the exception of the condition code register (the user portion of the status register), they are accessed only by instructions at the supervisor privilege level. 5.2.4.1 Status Register The status register (SR) stores the processor status. It contains the condition codes that reflect the results of a previous operation and can be used for conditional instruction execution in a program. The condition codes are extend (X), negative (N), zero (Z), overflow (V), and carry (C). The user (low-order) byte containing the condition codes is the only portion of the SR information available at the user privilege level; it is referenced as the condition code register (CCR) in user programs. At the supervisor privilege level, software can access the full status register. The upper byte of this register includes the interrupt priority (IP) mask (three bits), two bits for placing the processor in one of two tracing modes or disabling tracing, and the supervisor/user bit for placing the processor at the desired privilege level. Undefined bits in the status register are reserved by Freescale for future definition. The undefined bits are read as zeros and should be written as zeros for future compatibility. MC68332 USER'S MANUAL CENTRAL PROCESSING UNIT For More Information On This Product, Go to: www.freescale.com 5-5 Freescale Semiconductor, Inc. All operations to the SR and CCR are word-size operations, but for all CCR operations, the upper byte is read as all zeros and is ignored when written, regardless of privilege level. Freescale Semiconductor, Inc... Refer to APPENDIX D REGISTER SUMMARY for bit/field definitions and a diagram of the status register. 5.2.4.2 Alternate Function Code Registers Alternate function code registers (SFC and DFC) contain 3-bit function codes. Function codes can be considered extensions of the 24-bit linear address that optionally provide as many as eight 16-Mbyte address spaces. The processor automatically generates function codes to select address spaces for data and programs at the user and supervisor privilege levels and to select a CPU address space used for processor functions (such as breakpoint and interrupt acknowledge cycles). Registers SFC and DFC are used by the MOVES instruction to specify explicitly the function codes of the memory address. The MOVEC instruction is used to transfer values to and from the alternate function code registers. This is a long-word transfer; the upper 29 bits are read as zeros and are ignored when written. 5.2.5 Vector Base Register (VBR) The VBR contains the base address of the 1024-byte exception vector table, consisting of 256 exception vectors. Exception vectors contain the memory addresses of routines that begin execution at the completion of exception processing. Refer to 5.9 Exception Processing for more information on the VBR and exception processing. 5.3 Memory Organization Memory is organized on a byte-addressable basis in which lower addresses correspond to higher order bytes. For example, the address N of a long-word data item corresponds to the address of the most significant byte of the highest order word. The address of the most significant byte of the low-order word is N + 2, and the address of the least significant byte of the long word is N + 3. The CPU32 requires long-word and word data and instructions to be aligned on word boundaries (refer to Figure 5-6). Data misalignment is not supported. CENTRAL PROCESSING UNIT 5-6 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. 7 6 5 BIT DATA 1 BYTE = 8 BITS 4 3 2 1 0 INTEGER DATA 1 BYTE = 8 BITS 8 7 15 MSB BYTE 0 0 LSB BYTE 1 BYTE 2 BYTE 3 WORD = 16 BITS 15 0 WORD 0 Freescale Semiconductor, Inc... MSB LSB WORD 1 WORD 2 LONG WORD = 32 BITS 15 MSB 0 HIGH ORDER LONG WORD 0 LOW ORDER LSB LONG WORD 1 LONG WORD 2 ADDRESS 1 ADDRESS = 32 BITS 0 15 MSB HIGH ORDER ADDRESS 0 LSB LOW ORDER ADDRESS 1 ADDRESS 2 MSB = Most Significant Bit LSB = Least Significant Bit DECIMAL DATA 15 BCD DIGITS = 1 BYTE 8 7 12 11 BCD 0 MSD BCD 4 BCD 1 BCD 5 LSD 4 3 0 BCD 2 BCD 3 BCD 6 BCD 7 MSD = Most Significant Digit LSD = Least Significant Digit 1125A Figure 5-6 Memory Operand Addressing MC68332 USER'S MANUAL CENTRAL PROCESSING UNIT For More Information On This Product, Go to: www.freescale.com 5-7 Freescale Semiconductor, Inc. 5.4 Virtual Memory The full addressing range of the CPU32 on the MC68331 is 16 Mbytes in each of eight address spaces. Even though most systems implement a smaller physical memory, the system can be made to appear to have a full 16 Mbytes of memory available to each user program by using virtual memory techniques. Freescale Semiconductor, Inc... A system that supports virtual memory has a limited amount of high-speed physical memory that can be accessed directly by the processor and maintains an image of a much larger virtual memory on a secondary storage device. When the processor attempts to access a location in the virtual memory map that is not resident in physical memory, a page fault occurs. The access to that location is temporarily suspended while the necessary data is fetched from secondary storage and placed in physical memory. The suspended access is then restarted or continued. The CPU32 uses instruction restart, which requires that only a small portion of the internal machine state be saved. After correcting the fault, the machine state is restored, and the instruction is fetched and started again. This process is completely transparent to the application program. 5.5 Addressing Modes Addressing in the CPU32 is register-oriented. Most instructions allow the results of the specified operation to be placed either in a register or directly in memory. There is no need for extra instructions to store register contents in memory. There are seven basic addressing modes: * Register Direct * Register Indirect * Register Indirect with Index * Program Counter Indirect with Displacement * Program Counter Indirect with Index * Absolute * Immediate The register indirect addressing modes include postincrement, predecrement, and offset capability. The program counter indirect mode also has index and offset capabilities. In addition to these addressing modes, many instructions implicitly specify the use of the status register, stack pointer, and/or program counter. 5.6 Processing States The processor is always in one of four processing states: normal, exception, halted, or background. The normal processing state is associated with instruction execution; the bus is used to fetch instructions and operands and to store results. The exception processing state is associated with interrupts, trap instructions, tracing, and other exception conditions. The exception may be internally generated explicitly by an instruction or by an unusual condition arising during the execution of an instruction. Exception processing can be forced externally by an interrupt, a bus error, or a CENTRAL PROCESSING UNIT 5-8 For More Information On This Product, Go to: www.freescale.com MC68332 USER'S MANUAL Freescale Semiconductor, Inc. The halted processing state is an indication of catastrophic hardware failure. For example, if during the exception processing of a bus error another bus error occurs, the processor assumes that the system is unusable and halts. Freescale Semiconductor, Inc... The background processing state is initiated by breakpoints, execution of special instructions, or a double bus fault. Background processing is enabled by pulling BKPT low during RESET. Background processing allows interactive debugging of the system via a simple serial interface. 5.7 Privilege Levels The processor operates at one of two levels of privilege: user or supervisor. Not all instructions are permitted to execute at the user level, but all instructions are available at the supervisor level. Effective use of privilege level can protect system resources from uncontrolled access. The state of the S bit in the status register determines the privilege level and whether the user stack pointer (USP) or supervisor stack pointer (SSP) is used for stack operations. 5.8 Instructions The CPU32 instruction set is summarized in Table 5-1. The instruction set of the CPU32 is very similar to that of the MC68020. Two new instructions have been added to facilitate controller applications: low-power stop (LPSTOP) and table lookup and interpolate (TBLS, TBLSN, TBLU, TBLUN). The following MC68020 instructions are not implemented on the CPU32: BFxxx -- Bit Field Instructions (BFCHG, BFCLR, BFEXTS, BFEXTU, BFFFO, BFINS, BFSET, BFTST) CALLM, RTM -- Call Module, Return Module CAS, CAS2 -- Compare and Swap (Read-Modify-Write Instructions) cpxxx -- Coprocessor Instructions (cpBcc, cpDBcc, cpGEN, cpRESTORE, cpSAVE, cpScc, cpTRAPcc) PACK, UNPK -- Pack, Unpack BCD Instructions Memory Memory Indirect Addressing Modes -- The CPU32 traps on unimplemented instructions or illegal effective addressing modes, allowing user-supplied code to emulate unimplemented capabilities or to define special purpose functions. However, Freescale reserves the right to use all currently unimplemented instruction operation codes for future M68000 core enhancements. MC68332 USER'S MANUAL CENTRAL PROCESSING UNIT For More Information On This Product, Go to: www.freescale.com 5-9 Freescale Semiconductor, Inc. Table 5-1 Instruction Set Summary Instruction ABCD Syntax Dn, Dn - (An), - (An) Dn, , Dn , An #, #, Dn, Dn - (An), - (An) , Dn Dn, #, #, CCR #, SR Operand Size 8 8 8, 16, 32 8, 16, 32 16, 32 8, 16, 32 8, 16, 32 8, 16, 32 8, 16, 32 8, 16, 32 8, 16, 32 8, 16, 32 8 16 Dn, Dn #, Dn I 8, 16, 32 8, 16, 32 16 Dn, Dn #, Dn I 8, 16, 32 8, 16, 32 16 BGND