OMC 932723248 Hitachi Single-Chip Microcomputer H8/534, H8/536 HD6475348R, HD6435348R HD6475368R, HD6435368R HD6475348S, HD6435348S HD6475368S, HD6435368S Hardware Manual ADE-602-038B Preface The H8/534 and H8/536 are high-performance single-chip Hitachi-original microcomputers, featuring a high-speed CPU with 16-bit internal data paths and a full complement of on-chip supporting modules. They are ideal microcontrollers for a wide variety of medium-scale devices, including both office and industrial equipment and consumer products. The CPU has a general-register architecture. Its instruction set is highly orthogonal and is optimized for fast execution of programs coded in the high-level C language. For further speed, the existing 10-MHz lineup has been extended to include high-speed versions that operate at 16 MHz. Low-voltage versions that operate at 3 V and 2.7 V have also been developed. On-chip facilities include large RAM and ROM memories, numerous timers, serial I/O, an A/D converter, I/O ports, and other functions for compact implementation of high-performance application systems. H8/534 and H8/536 are available in both a ZTAT version* with on-chip PROM, ideal for the early stages of production or for products with frequently-changing specifications, and a maskedROM version suitable for volume production. This manual gives a hardware description of the H8/534 and H8/536. For details of the instruction set, refer to the H8/500 Series Programming Manual, which applies to all chips in the H8/500 Series. * ZTAT (Zero Turn-Around Time) is a trademark of Hitachi, Ltd. 2 Contents Section 1 Overview 1.1 1.2 1.3 Features ··································································································································1 Block Diagram ·······················································································································5 Pin Arrangements and Functions ···························································································6 1.3.1 Pin Arrangement ·········································································································6 1.3.2 Pin Functions ··············································································································9 Section 2 MCU Operating Modes and Address Space 2.1 2.2 2.3 2.4 Overview ······························································································································23 Mode Descriptions ···············································································································24 Address Space Map ··············································································································25 2.3.1 Page Segmentation ····································································································25 2.3.2 Page 0 Address Allocations ······················································································26 Mode Control Register (MDCR) ·························································································27 Section 3 CPU 3.1 3.2 3.3 3.4 3.5 Overview ······························································································································31 3.1.1 Features ·····················································································································31 3.1.2 Address Space ···········································································································32 3.1.3 Register Configuration ······························································································33 CPU Register Descriptions ··································································································34 3.2.1 General Registers ······································································································34 3.2.2 Control Registers ······································································································35 3.2.3 Initial Register Values ·······························································································40 Data Formats ························································································································41 3.3.1 Data Formats in General Registers ···········································································41 3.3.2 Data Formats in Memory ··························································································42 Instructions ···························································································································44 3.4.1 Basic Instruction Formats ·························································································44 3.4.2 Addressing Modes ····································································································45 3.4.3 Effective Address Calculation ··················································································47 Instruction Set ······················································································································50 3.5.1 Overview ···················································································································50 3.5.2 Data Transfer Instructions ·························································································52 3.5.3 Arithmetic Instructions ·····························································································53 3.5.4 Logic Operations ·······································································································54 3.5.5 Shift Operations ········································································································55 3.5.6 Bit Manipulations ······································································································56 3.5.7 Branching Instructions ······························································································57 3.6 3.7 3.8 3.9 3.5.8 System Control Instructions ······················································································59 3.5.9 Short-Format Instructions ·························································································62 Operating Modes ··················································································································62 3.6.1 Minimum Mode ········································································································62 3.6.2 Maximum Mode ········································································································63 Basic Operational Timing ····································································································63 3.7.1 Overview ···················································································································63 3.7.2 On-Chip Memory Access Cycle ···············································································64 3.7.3 Pin States during On-Chip Memory Access ·····························································65 3.7.4 Register Field Access Cycle (Addresses H'FE80 to H'FFFF) ··································66 3.7.5 Pin States during Register Field Access (Addresses H'FE80 to H'FFFF) ················67 3.7.6 External Access Cycle ······························································································ 68 CPU States ···························································································································69 3.8.1 Overview ···················································································································69 3.8.2 Program Execution State ···························································································71 3.8.3 Exception-Handling State ·························································································71 3.8.4 Bus-Released State ····································································································72 3.8.5 Reset State ·················································································································77 3.8.6 Power-Down State ····································································································77 Programming Notes ·············································································································78 3.9.1 Restriction on Address Location ···············································································78 Section 4 Exception Handling 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 Overview ······························································································································79 4.1.1 Types of Exception Handling and Their Priority ······················································79 4.1.2 Hardware Exception-Handling Sequence ·································································80 4.1.3 Exception Factors and Vector Table ·········································································80 Reset ····································································································································83 4.2.1 Overview ···················································································································83 4.2.2 Reset Sequence ·········································································································83 4.2.3 Stack Pointer Initialization ························································································84 Address Error ·······················································································································87 4.3.1 Illegal Instruction Prefetch ························································································87 4.3.2 Word Data Access at Odd Address ···········································································87 4.3.3 Off-Chip Address Access in Single-Chip Mode ·······················································87 Trace ····································································································································88 Interrupts ······························································································································88 Invalid Instruction ················································································································91 Trap Instructions and Zero Divide ·······················································································91 Cases in Which Exception Handling is Deferred ·································································91 4.8.1 Instructions that Disable Interrupts ···········································································91 4.8.2 Disabling of Exceptions Immediately after a Reset ··················································92 4.8.3 Disabling of Interrupts after a Data Transfer Cycle ··················································92 4.9 Stack Status after Completion of Exception Handling ························································93 4.9.1 PC Value Pushed on Stack for Trace, Interrupts, Trap Instructions, and Zero Divide Exceptions ·······································95 4.9.2 PC Value Pushed on Stack for Address Error and Invalid Instruction Exceptions ······························································································95 4.10 Notes on Use of the Stack ····································································································95 Section 5 Interrupt Controller 5.1 5.2 5.3 5.4 5.5 5.6 Overview ······························································································································97 5.1.1 Features ·····················································································································97 5.1.2 Block Diagram ··········································································································98 5.1.3 Register Configuration ······························································································99 Interrupt Types ·····················································································································99 5.2.1 External Interrupts ····································································································99 5.2.2 Internal Interrupts ····································································································101 5.2.3 Interrupt Vector Table ·····························································································102 Register Descriptions ·········································································································104 5.3.1 Interrupt Priority Registers A to F (IPRA to IPRF) ················································104 5.3.2 Timing of Priority Setting ·······················································································105 Interrupt Handling Sequence ·····························································································105 5.4.1 Interrupt Handling Flow ·························································································105 5.4.2 Stack Status after Interrupt Handling Sequence ·····················································108 5.4.3 Timing of Interrupt Exception-Handling Sequence ················································109 Interrupts During Operation of the Data Transfer Controller ············································109 Interrupt Response Time ····································································································112 Section 6 Data Transfer Controller 6.1 6.2 6.3 Overview ····························································································································113 6.1.1 Features ···················································································································113 6.1.2 Block Diagram ········································································································113 6.1.3 Register Configuration ····························································································114 Register Descriptions ·········································································································115 6.2.1 Data Transfer Mode Register (DTMR) ···································································115 6.2.2 Data Transfer Source Address Register (DTSR) ····················································116 6.2.3 Data Transfer Destination Register (DTDR) ·························································116 6.2.4 Data Transfer Count Register (DTCR) ···································································116 6.2.5 Data Transfer Enable Registers A to F (DTEA to DTEF) ······································117 Data Transfer Operation ·····································································································118 6.3.1 Data Transfer Cycle ································································································118 6.4 6.5 6.3.2 DTC Vector Table ···································································································120 6.3.3 Location of Register Information in Memory ·························································122 6.3.4 Length of Data Transfer Cycle ················································································122 Procedure for Using the DTC ····························································································124 Example ·····························································································································125 Section 7 Wait-State Controller 7.1 7.2 7.3 Overview ····························································································································127 7.1.1 Features ···················································································································127 7.1.2 Block Diagram ········································································································128 7.1.3 Register Configuration ····························································································128 Wait-State Control Register ·······························································································129 Operation in Each Wait Mode ····························································································130 7.3.1 Programmable Wait Mode ······················································································130 7.3.2 Pin Wait Mode ········································································································131 7.3.3 Pin Auto-Wait Mode ·······························································································133 Section 8 Clock Pulse Generator 8.1 8.2 8.3 Overview ····························································································································135 8.1.1 Block Diagram ········································································································135 Oscillator Circuit ················································································································135 System Clock Divider ········································································································139 Section 9 I/O Ports 9.1 9.2 9.3 9.4 9.5 Overview ····························································································································141 Port 1 ··································································································································144 9.2.1 Overview ·················································································································144 9.2.2 Port 1 Registers ·······································································································144 9.2.3 Pin Functions in Each Mode ···················································································147 Port 2 ··································································································································150 9.3.1 Overview ·················································································································150 9.3.2 Port 2 Registers ·······································································································151 9.3.3 Pin Functions in Each Mode ···················································································152 Port 3 ··································································································································153 9.4.1 Overview ·················································································································153 9.4.2 Port 3 Registers ·······································································································154 9.4.3 Pin Functions in Each Mode ···················································································155 Port 4 ··································································································································156 9.5.1 Overview ·················································································································156 9.5.2 Port 4 Registers ·······································································································157 9.5.3 Pin Functions in Each Mode ···················································································158 9.6 Port 5 9.6.1 9.6.2 9.6.3 9.6.4 9.7 Port 6 9.7.1 9.7.2 9.7.3 9.7.4 9.8 Port 7 9.8.1 9.8.2 9.8.3 9.9 Port 8 9.9.1 9.9.2 9.10 Port 9 9.10.1 9.10.2 9.10.3 ··································································································································159 Overview ·················································································································159 Port 5 Registers ·······································································································160 Pin Functions in Each Mode ···················································································161 Built-In MOS Pull-Up ·····························································································163 ··································································································································165 Overview ·················································································································165 Port 6 Registers ·······································································································166 Pin Functions in Each Mode ···················································································170 Built-In MOS Pull-Up ·····························································································172 ··································································································································173 Overview ·················································································································173 Port 7 Registers ·······································································································173 Pin Functions ··········································································································174 ··································································································································177 Overview ·················································································································177 Port 8 Registers ·······································································································177 ··································································································································178 Overview ·················································································································178 Port 9 Registers ·······································································································178 Pin Functions ··········································································································179 Section 10 16-Bit Free-Running Timers 10.1 Overview ····························································································································183 10.1.1 Features ···················································································································183 10.1.2 Block Diagram ········································································································184 10.1.3 Input and Output Pins ·····························································································185 10.1.4 Register Configuration ····························································································186 10.2 Register Descriptions ·········································································································187 10.2.1 Free-Running Counter (FRC)—H'FE92, H'FEA2, H'FEB2 ···································187 10.2.2 Output Compare Registers A and B (OCRA and OCRB)—H'FE94 and H'FE96, H'FEA4 and H'FEA6, H'FEB4 and H'FEB6 ······································188 10.2.3 Input Capture Register (ICR)—H'FE98, H'FEA8, H'FEB8 ···································188 10.2.4 Timer Control Register (TCR) ················································································189 10.2.5 Timer Control/Status Register (TCSR) ···································································191 10.3 CPU Interface ·····················································································································194 10.4 Operation ····························································································································196 10.4.1 FRC Incrementation Timing ···················································································196 10.4.2 Output Compare Timing ·························································································197 10.4.3 Input Capture Timing ······························································································199 10.4.4 Setting of FRC Overflow Flag (OVF) ····································································201 10.5 CPU Interrupts and DTC Interrupts ···················································································201 10.6 Synchronization of Free-Running Timers 1 to 3 ································································202 10.6.1 Synchronization after a Reset ·················································································202 10.6.2 Synchronization by Writing to FRCs ······································································202 10.7 Sample Application ············································································································206 10.8 Application Notes ··············································································································206 Section 11 8-Bit Timer 11.1 Overview ····························································································································213 11.1.1 Features ···················································································································213 11.1.2 Block Diagram ········································································································214 11.1.3 Input and Output Pins ·····························································································215 11.1.4 Register Configuration ····························································································215 11.2 Register Descriptions ·········································································································215 11.2.1 Timer Counter (TCNT)—H'FED4 ··········································································215 11.2.2 Time Constant Registers A and B (TCORA and TCORB)—H'FED2 and H'FED3 ·····················································216 11.2.3 Timer Control Register (TCR)—H'FED0 ·······························································216 11.2.4 Timer Control/Status Register (TCSR)—H'FED1 ··················································218 11.3 Operation ····························································································································220 11.3.1 TCNT Incrementation Timing ················································································220 11.3.2 Compare Match Timing ··························································································221 11.3.3 External Reset of TCNT ·························································································223 11.3.4 Setting of TCNT Overflow Flag ·············································································224 11.4 CPU Interrupts and DTC Interrupts ···················································································224 11.5 Sample Application ············································································································225 11.6 Application Notes ··············································································································226 Section 12 PWM Timer 12.1 Overview ····························································································································233 12.1.1 Features ···················································································································233 12.1.2 Block Diagram ········································································································233 12.1.3 Input and Output Pins ·····························································································234 12.1.4 Register Configuration ····························································································235 12.2 Register Descriptions ·········································································································235 12.2.1 Timer Counter (TCNT)—H'FEC2, H'FEC4, H'FECA ···········································235 12.2.2 Duty Register (DTR)—H'FEC1, H'FEC5, H'FEC9 ················································236 12.2.3 Timer Control Register (TCR)—H'FEC0, H'FEC4, H'FEC8 ·································236 12.3 Operation ····························································································································238 12.4 Application Notes ··············································································································240 Section 13 Watchdog Timer 13.1 Overview ····························································································································241 13.1.1 Features ···················································································································241 13.1.2 Block Diagram ········································································································242 13.1.3 Register Configuration ····························································································242 13.2 Register Descriptions ·········································································································243 13.2.1 Timer Counter TCNT—H'FEEC (Write), H'FEED (Read) ····································243 13.2.2 Timer Control/Status Register (TCSR)—H'FEEC ·················································243 13.2.3 Reset Control/Status Register (RSTCSR)—H'FF14 (Write), H'FF15 (Read) ········245 13.2.4 Notes on Register Access ························································································246 13.3 Operation ····························································································································248 13.3.1 Watchdog Timer Mode ···························································································248 13.3.2 Interval Timer Mode ·······························································································249 13.3.3 Operation in Software Standby Mode ·····································································250 13.3.4 Setting of Overflow Flag ························································································250 13.3.5 Setting of Watchdog Timer Reset (WRST) Bit ·······················································251 13.4 Application Notes ··············································································································252 Section 14 Serial Communication Interface 14.1 Overview ····························································································································255 14.1.1 Features ···················································································································255 14.1.2 Block Diagram ········································································································256 14.1.3 Input and Output Pins ·····························································································257 14.1.4 Register Configuration ····························································································257 14.2 Register Descriptions ·········································································································258 14.2.1 Receive Shift Register (RSR) ·················································································258 14.2.2 Receive Data Register (RDR)—H'FEDD, H'FEF5 ················································258 14.2.3 Transmit Shift Register (TSR) ················································································258 14.2.4 Transmit Data Register (TDR)—H'FEDB, H'FEF3 ···············································259 14.2.5 Serial Mode Register (SMR)—H'FED8, H'FEF0 ···················································259 14.2.6 Serial Control Register (SCR)—H'FEDA, H'FEF2 ················································261 14.2.7 Serial Status Register (SSR)—H'FEDC, H'FEF4 ···················································263 14.2.8 Bit Rate Register (BRR)—H'FED9, H'FEF1 ··························································265 14.3 Operation ····························································································································270 14.3.1 Overview ·················································································································270 14.3.2 Asynchronous Mode ·······························································································271 14.3.3 Synchronous Mode ·································································································275 14.4 CPU Interrupts and DTC Interrupts ···················································································279 14.5 Application Notes ··············································································································280 Section 15 A/D Converter 15.1 Overview ····························································································································283 15.1.1 Features ···················································································································283 15.1.2 Block Diagram ········································································································284 15.1.3 Input Pins ················································································································285 15.1.4 Register Configuration ····························································································285 15.2 Register Descriptions ·········································································································286 15.2.1 A/D Data Registers (ADDR)—H'FEE0 to H'FEE7 ················································286 15.2.2 A/D Control/Status Register (ADCSR)—H'FEE8 ·················································287 15.2.3 A/D Control Register (ADCR)—H'FEE9 ·······························································289 15.3 CPU Interface ·····················································································································290 15.4 Operation ····························································································································291 15.4.1 Single Mode (SCAN = 0) ·······················································································291 15.4.2 Scan Mode (SCAN = 1) ··························································································294 15.4.3 Input Sampling Time and A/D Conversion Time ···················································296 15.4.4 External Triggering of A/D Conversion ·································································297 15.5 Interrupts and the Data Transfer Controller ·······································································298 Section 16 RAM 16.1 Overview ····························································································································299 16.1.1 Block Diagram ········································································································299 16.1.2 Register Configuration ····························································································300 16.2 RAM Control Register (RAMCR) ·····················································································300 16.3 Operation ····························································································································300 16.3.1 Expanded Modes (Modes 1, 2, 3, and 4) ································································300 16.3.2 Single-Chip Mode (Mode 7) ···················································································301 Section 17 ROM 17.1 Overview ····························································································································303 17.1.1 Block Diagram ········································································································303 17.2 PROM Mode ······················································································································304 17.2.1 PROM Mode Setup ·································································································304 17.2.2 Socket Adapter Pin Arrangements and Memory Map ············································305 17.3 H8/534 Programming ·········································································································308 17.3.1 Writing and Verifying ·····························································································308 17.3.2 Notes on Writing ·····································································································311 17.4 H8/536 Programming ·········································································································312 17.4.1 Writing and Verifying ·····························································································312 17.4.2 Notes on Programming ···························································································315 17.5 Reliability of Written Data ·································································································317 17.6 Erasing of Data ···················································································································318 17.7 Handling of Windowed Packages ······················································································319 Section 18 Power-Down State 18.1 Overview ····························································································································321 18.2 Sleep Mode ························································································································322 18.2.1 Transition to Sleep Mode ························································································322 18.2.2 Exit from Sleep Mode ·····························································································322 18.3 Software Standby Mode ·····································································································322 18.3.1 Transition to Software Standby Mode ····································································322 18.3.2 Software Standby Control Register (SBYCR) ························································323 18.3.3 Exit from Software Standby Mode ·········································································324 18.3.4 Sample Application of Software Standby Mode ····················································324 18.3.5 Application Notes ···································································································325 18.4 Hardware Standby Mode ···································································································325 18.4.1 Transition to Hardware Standby Mode ···································································325 18.4.2 Recovery from Hardware Standby Mode ·······························································326 18.4.3 Timing Sequence of Hardware Standby Mode ·······················································326 Section 19 E Clock Interface 19.1 Overview ····························································································································327 Section 20 Electrical Specifications 20.1 Absolute Maximum Ratings ······························································································331 20.2 Electrical Characteristics ····································································································331 20.2.1 DC Characteristics ··································································································331 20.2.2 AC Characteristics ··································································································340 20.2.3 A/D Converter Characteristics ················································································349 20.3 MCU Operational Timing ··································································································350 20.3.1 Bus Timing ··············································································································351 20.3.2 Control Signal Timing ····························································································354 20.3.3 Clock Timing ··········································································································355 20.3.4 I/O Port Timing ·······································································································357 20.3.5 16-Bit Free-Running Timer Timing ········································································358 20.3.6 8-Bit Timer Timing ·································································································359 20.3.7 Pulse Width Modulation Timer Timing ··································································360 20.3.8 Serial Communication Interface Timing ·································································360 20.3.9 A/D Trigger Signal Input Timing ···········································································361 Appendix A Instructions A.1 A.2 Instruction Set ····················································································································363 Instruction Codes ···············································································································368 A.3 A.4 Operation Code Map ··········································································································379 Instruction Execution Cycles ·····························································································384 A.4.1 Calculation of Instruction Execution States ····························································384 A.4.2 Tables of Instruction Execution Cycles ··································································385 Appendix B Register Field B.1 B.2 Register Addresses and Bit Names ····················································································393 Register Descriptions ·········································································································398 Appendix C I/O Port Schematic Diagrams C.1 C.2 C.3 C.4 C.5 C.6 C.7 C.8 C.9 Schematic Diagram of Port 1 Schematic Diagram of Port 2 Schematic Diagram of Port 3 Schematic Diagram of Port 4 Schematic Diagram of Port 5 Schematic Diagram of Port 6 Schematic Diagram of Port 7 Schematic Diagram of Port 8 Schematic Diagram of Port 9 ·····························································································437 ·····························································································444 ·····························································································445 ·····························································································446 ·····························································································447 ·····························································································448 ·····························································································450 ·····························································································455 ·····························································································456 Appendix D Memory Maps ·······························································································463 Appendix E Pin States E.1 E.2 Port State of Each Pin State ·······························································································465 Pin States in Reset State ·····································································································468 Appendix F Timing of Transition to and Recovery from Hardware Standby Mode ················································································475 Appendix G Package Dimensions ····················································································476 Figures 1-1 1-2 1-3 1-4 2-1 2-2 3-1 3-2 3-3 3-4 3-5 3-6 3-7 3-8 3-9 3-10 (a) 3-10 (b) 3-11 3-12 3-13 3-14 3-15 4-1 4-2 4-3 4-4 4-5 5-1 5-2 5-3 (a) 5-3 (b) 5-4 5-5 6-1 6-2 6-3 6-4 6-5 6-6 7-1 Block Diagram ···················································································································5 Pin Arrangement (CP-84, Top View) ················································································6 Pin Arrangement (CG-84, Top View) ················································································7 Pin Arrangement (FP-80A, TFP-80C, Top View) ·····························································8 H8/534 Memory Map in Each Operating Mode ······························································28 H8/536 Memory Map in Each Operating Mode ······························································29 CPU Operating Modes ·····································································································32 Registers in the CPU ········································································································33 Stack Pointer ····················································································································34 Combinations of Page Registers with Other Registers ····················································38 Short Absolute Addressing Mode and Base Register ······················································39 On-Chip Memory Access Timing ····················································································64 Pin States during Access to On-Chip Memory ································································65 Register Field Access Timing ··························································································66 Pin States during Register Field Access ··········································································67 External Access Cycle (Read Access) ·············································································68 External Access Cycle (Write Access) ············································································69 Operating States ···············································································································70 State Transitions ··············································································································71 Bus-Right Release Cycle (During On-chip Memory Access Cycle) ·······························73 Bus-Right Release Cycle (During External Access Cycle) ·············································74 Bus-Right Release Cycle (During Internal CPU Operation) ···········································75 Types of Factors Causing Exception Handling ·······························································81 Reset Vector ·····················································································································84 Reset Sequence (Minimum Mode, On-Chip Memory) ···················································85 Reset Sequence (Maximum Mode, External Memory) ···················································86 Interrupt Sources (and Number of Interrupt Types) ························································90 Interrupt Controller Block Diagram ················································································98 Interrupt Handling Flowchart ························································································107 Stack before and after Interrupt Exception-Handling (Minimum Mode) ······················108 Stack before and after Interrupt Exception-Handling (Maximum Mode) ·····················109 Interrupt Sequence (Minimum Mode, On-Chip Memory) ············································110 Interrupt Sequence (Maximum Mode, External Memory) ············································111 Block Diagram of Data Transfer Controller ··································································114 Flowchart of Data Transfer Cycle ··················································································119 DTC Vector Table ··········································································································120 DTC Vector Table Entry ································································································121 Order of Register Information ·······················································································122 Use of DTC to Receive Data via Serial Communication Interface 1 ····························126 Block Diagram of Wait-State Controller ·······································································128 7-2 7-3 7-4 8-1 8-2 8-3 8-4 8-5 8-6 8-7 9-1 9-2 9-3 9-4 9-5 9-6 9-7 9-8 9-9 9-10 9-11 9-12 9-13 9-14 9-15 9-16 9-17 9-18 9-19 9-20 9-21 10-1 10-2 (a) 10-2 (b) 10-3 10-4 10-5 10-6 10-7 10-8 10-9 Programmable Wait Mode ·····························································································131 Pin Wait Mode ···············································································································132 Pin Auto-Wait Mode ······································································································133 Block Diagram of Clock Pulse Generator ·····································································135 Connection of Crystal Oscillator (Example) ·································································136 Crystal Oscillator Equivalent Circuit ·············································································136 Notes on Board Design around External Crystal ···························································137 External Clock Input (Example) ····················································································137 External Clock Input (Examples) ··················································································138 Phase Relationship of ø Clock and E clock ···································································139 Pin Functions of Port 1 ··································································································144 Pin Functions of Port 2 ··································································································150 Port 2 Pin Functions in Expanded Modes ······································································152 Port 2 Pin Functions in Single-Chip Mode ····································································153 Pin Functions of Port 3 ··································································································153 Port 3 Pin Functions in Expanded Modes ······································································155 Port 3 Pin Functions in Single-Chip Mode ····································································156 Pin Functions of Port 4 ··································································································156 Port 4 Pin Functions in Expanded Modes ······································································158 Port 4 Pin Functions in Single-Chip Mode ····································································159 Pin Functions of Port 5 ··································································································159 Port 5 Pin Functions in Modes 1 and 3 ··········································································161 Port 5 Pin Functions in Modes 2 and 4 ··········································································162 Port 5 Pin Functions in Single-Chip Mode ····································································162 Pin Functions of Port 6 ··································································································166 Port 6 Pin Functions in Mode 3 ·····················································································170 Port 6 Pin Functions in Mode 4 ·····················································································170 Port 6 Pin Functions in Modes 7, 2, and 1 ·····································································171 Pin Functions of Port 7 ··································································································173 Pin Functions of Port 8 ··································································································177 Pin Functions of Port 9 ··································································································178 Block Diagram of 16-Bit Free-Running Timer ·····························································184 Write Access to FRC (When CPU Writes H'AA55) ·····················································195 Read Access to FRC (When FRC Contains H'AA55) ···················································196 Increment Timing for External Clock Input ··································································197 Setting of Output Compare Flags ··················································································198 Timing of Output Compare A ························································································198 Clearing of FRC by Compare-Match A ·········································································199 Input Capture Timing (Usual Case) ···············································································199 Input Capture Timing (1-State Delay) ···········································································200 Setting of Input Capture Flag ························································································200 10-10 10-11 10-12 10-13 10-14 11-1 11-2 11-3 11-4 11-5 11-6 11-7 11-8 11-9 11-10 11-11 12-1 12-2 13-1 13-2 13-3 13-4 13-5 13-6 13-7 13-8 13-9 14-1 14-2 14-3 14-4 14-5 15-1 15-2 15-3 15-4 15-5 15-6 16-1 17-1 17-2 (a) Setting of Overflow Flag (OVF) ····················································································201 Square-Wave Output (Example) ····················································································206 FRC Write-Clear Contention ·························································································207 FRC Write-Increment Contention ·················································································208 Contention between OCR Write and Compare-Match ··················································209 Block Diagram of 8-Bit Timer ·······················································································214 Count Timing for External Clock Input ·········································································221 Setting of Compare-Match Flags ···················································································222 Timing of Timer Output ·································································································222 Timing of Compare-Match Clear ··················································································223 Timing of External Reset ·······························································································223 Setting of Overflow Flag (OVF) ····················································································224 Example of Pulse Output ·······························································································225 TCNT Write-Clear Contention ······················································································226 TCNT Write-Increment Contention ···············································································227 Contention between TCOR Write and Compare-Match ················································228 Block Diagram of PWM Timer ·····················································································234 PWM Timing ·················································································································239 Block Diagram of Timer Counter ··················································································242 Writing to TCNT and TCSR ··························································································247 Writing to RSTCSR ·······································································································247 Operation in Watchdog Timer Mode ·············································································249 Operation in Interval Timer Mode ·················································································249 Setting of OVF Bit ·········································································································250 Setting of WRST Bit and Internal Reset Signal ····························································251 TCNT Write-Increment Contention ···············································································252 Reset Circuit (Example) ································································································253 Block Diagram of Serial Communication Interface ······················································256 Data Format in Asynchronous Mode ·············································································271 Phase Relationship between Clock Output and Transmit Data ·····································272 Data Format in Synchronous Mode ···············································································276 Sampling Timing (Asynchronous Mode) ······································································282 Block Diagram of A/D Converter ··················································································284 Read Access to A/D Data Register (When Register Contains H'AA40) ·······················290 A/D Operation in Single Mode (When Channel 1 is Selected) ·····································293 A/D Operation in Scan Mode (When Channels 0 to 2 are Selected) ·····························295 A/D Conversion Timing ································································································296 Timing of Setting of ADST Bit ·····················································································297 Block Diagram of On-Chip RAM ·················································································299 Block Diagram of On-Chip ROM ·················································································304 Socket Adapter Pin Arrangements (H8/534) ·································································306 17-2 (b) 17-3 17-4 17-5 17-6 17-7 17-8 18-1 18-2 19-1 19-2 20-1 20-2 20-3 20-4 20-5 20-6 20-7 20-8 20-9 20-10 20-11 20-12 20-13 20-14 20-15 20-16 20-17 20-18 20-19 20-20 20-21 20-22 C-1 (a) C-1 (b) C-1 (c) C-1 (d) C-1 (e) C-1 (f) Socket Adapter Pin Arrangements (H8/536) ·································································307 Memory Map in PROM Mode ······················································································308 High-Speed Programming Flowchart (H8/534) ····························································309 PROM Write/Verify Timing (H8/534) ···········································································311 High-Speed Programming Flowchart (H8/536) ····························································313 PROM Write/Verify Timing (H8/536) ···········································································315 Recommended Screening Procedure ·············································································317 NMI Timing of Software Standby Mode (Application Example) ·································325 Hardware Standby Sequence ·························································································326 Execution Cycle of Instruction Synchronized with E Clock in Expanded Modes (Maximum Synchronization Delay) ··············································································328 Execution Cycle of Instruction Synchronized with E Clock in Expanded Modes (Minimum Synchronization Delay) ···············································································329 Example of Circuit for Driving a Darlington Transistor Pair ········································339 Example of Circuit for Driving an LED ········································································339 Output Load Circuit ·······································································································347 Basic Bus Cycle (without Wait States) in Expanded Modes ·········································351 Basic Bus Cycle (with 1 Wait State) in Expanded Modes ·············································352 Bus Cycle Synchronized with E Clock ··········································································353 Reset Input Timing ········································································································ 354 Reset Output Timing ······································································································354 Interrupt Input Timing ···································································································354 Bus Release State Timing ······························································································355 E Clock Timing ··············································································································355 Clock Oscillator Stabilization Timing ···········································································356 I/O Port Input/Output Timing ························································································357 Free-Running Timer Input/Output Timing ····································································358 External Clock Input Timing for Free-Running Timers ················································358 8-Bit Timer Output Timing ····························································································359 8-Bit Timer Clock Input Timing ····················································································359 8-Bit Timer Reset Input Timing ····················································································359 PWM Timer Output Timing ··························································································360 SCI Input Clock Timing ································································································360 SCI Input/Output Timing (Synchronous Mode) ····························································360 A/D Trigger Signal Input Timing ··················································································361 Schematic Diagram of Port 1, Pin P10 ··········································································437 Schematic Diagram of Port 1, Pin P11 ··········································································437 Schematic Diagram of Port 1, Pin P12 ···········································································438 Schematic Diagram of Port 1, Pin P13 ··········································································439 Schematic Diagram of Port 1, Pin P14 ···········································································440 Schematic Diagram of Port 1, Pin P15 ··········································································441 C-1 (g) C-1 (h) C-2 C-3 C-4 C-5 C-6 (a) C-6 (b) C-7 (a) C-7 (b) C-7 (c) C-7 (d) C-7 (e) C-8 C-9 (a) C-9 (b) C-9 (c) C-9 (d) C-9 (e) C-9 (f) C-9 (g) E-1 E-2 E-3 E-4 E-5 G-1 G-2 G-3 G-4 Schematic Diagram of Port 1, Pin P16 ··········································································442 Schematic Diagram of Port 1, Pin P17 ··········································································443 Schematic Diagram of Port 2 ·························································································444 Schematic Diagram of Port 3 ·························································································445 Schematic Diagram of Port 4 ·························································································446 Schematic Diagram of Port 5 ·························································································447 Schematic Diagram of Port 6, Pin P60 ··········································································448 Schematic Diagram of Port 6, Pin P61 to P63 ································································449 Schematic Diagram of Port 7, Pin P70 ··········································································450 Schematic Diagram of Port 7, Pins P71 and P72 ···························································451 Schematic Diagram of Port 7, Pin P73 ··········································································452 Schematic Diagram of Port 7, Pins P74, P75 and P76 ····················································453 Schematic Diagram of Port 7, Pin P77 ··········································································454 Schematic Diagram of Port 8 ·························································································455 Schematic Diagram of Port 9, Pins P90 and P91 ···························································456 Schematic Diagram of Port 9, Pin P92 ··········································································457 Schematic Diagram of Port 9, Pin P93 ··········································································458 Schematic Diagram of Port 9, Pin P94 ··········································································459 Schematic Diagram of Port 9, Pin P95 ··········································································460 Schematic Diagram of Port 9, Pin P96 ··········································································461 Schematic Diagram of Port 9, Pin P97 ··········································································462 Reset during Memory Access (Mode 1) ········································································469 Reset during Memory Access (Mode 2) ········································································470 Reset during Memory Access (Mode 3) ········································································472 Reset during Memory Access (Mode 4) ········································································473 Reset during Memory Access (Mode 7) ········································································474 Package Dimensions (CP-84) ························································································476 Package Dimensions (CG-84) ·······················································································476 Package Dimensions (FP-80A) ······················································································477 Package Dimensions (TFP-80C) ···················································································477 Tables 1-1 1-2 1-3 1-4 2-1 2-2 3-1 3-2 3-3 Features ······························································································································2 Pin Arrangements in Each Operating Mode (CP-84, CG-84) ···········································9 Pin Arrangements in Each Operating Mode (FP-80A, TFP-80C) ···································13 Pin Functions ···················································································································17 Operating Modes ·············································································································23 Mode Control Register ····································································································27 Interrupt Mask Levels ······································································································36 Interrupt Mask Bits after an Interrupt is Accepted ··························································36 Initial Values of Registers ································································································41 3-4 3-5 3-6 3-7 3-8 3-9 3-10 3-11 3-12 3-13 3-14 3-15 3-16 3-17 4-1 (a) 4-1 (b) 4-2 4-3 5-1 5-2 5-3 5-4 6-1 6-2 6-3 6-4 6-5 6-6 6-7 7-1 7-2 8-1 (1) General Register Data Formats ························································································42 Data Formats in Memory ·································································································43 Data Formats on the Stack ·······························································································44 Addressing Modes ···········································································································46 Effective Address Calculation ·························································································47 Instruction Classification ·································································································50 Data Transfer Instructions ·······························································································52 Arithmetic Instructions ····································································································53 Logic Operation Instructions ···························································································54 Shift Instructions ··············································································································55 Bit-Manipulation Instructions ··························································································56 Branching Instructions ·····································································································57 System Control Instructions ····························································································59 Short-Format Instructions and Equivalent General Formats ···········································62 Exceptions and Their Priority ··························································································79 Instruction Exceptions ·····································································································79 Exception Vector Table ····································································································82 Stack after Exception Handling Sequence ·······································································93 Interrupt Controller Registers ··························································································99 Interrupts, Vectors, and Priorities ··················································································103 Assignment of Interrupt Priority Registers ····································································104 Number of States before Interrupt Service ····································································112 Internal Control Registers of the DTC ···········································································114 Data Transfer Enable Registers ······················································································115 Assignment of Data Transfer Enable Registers ·····························································117 Addresses of DTC Vectors ·····························································································121 Number of States per Data Transfer ··············································································123 Number of States before Interrupt Service ····································································124 DTC Control Register Information Set in RAM ···························································125 Register Configuration ···································································································128 Wait Modes ····················································································································130 External Crystal Parameters (HD6475368R, HD6475348R, HD6435368R, HD6435348R) ·····································136 8-1 (2) External Crystal Parameters (HD6475368S, HD6475348S, HD6435368S, HD6435348S) ·······································136 9-1 Input/Output Port Summary ··························································································142 9-2 Port 1 Registers ··············································································································144 9-3 Port 1 Pin Functions in Expanded Modes ······································································147 9-4 Port 1 Pin Functions in Single-Chip Modes ··································································149 9-5 Port 2 Registers ··············································································································151 9-6 Port 3 Registers ··············································································································154 9-7 9-8 9-9 9-10 9-11 9-12 9-13 9-14 9-15 9-16 9-17 10-1 10-2 10-3 10-4 10-5 11-1 11-2 11-3 11-4 11-5 12-1 12-2 12-3 13-1 13-2 14-1 14-2 14-3 14-4 14-5 14-6 14-7 14-8 14-9 14-10 15-1 15-2 15-3 15-4 16-1 Port 4 Registers ··············································································································157 Port 5 Registers ··············································································································160 Status of MOS Pull-Ups for Port 5 ················································································163 Port 6 Registers ··············································································································166 Port 6 Pin Functions in Modes 7, 2, and 1 ·····································································171 Status of MOS Pull-Ups for Port 5 ················································································172 Port 7 Registers ··············································································································173 Port 7 Pin Functions ·······································································································175 Port 8 Registers ··············································································································177 Port 9 Registers ··············································································································178 Port 9 Pin Functions ·······································································································180 Input and Output Pins of Free-Running Timer Module ················································185 Register Configuration ···································································································186 Free-Running Timer Interrupts ······················································································201 Synchronization by Writing to FRCs ·············································································202 Effect of Changing Internal Clock Sources ···································································210 Input and Output Pins of 8-Bit Timer ············································································215 8-Bit Timer Registers ·····································································································215 8-Bit Timer Interrupts ····································································································224 Priority Order of Timer Output ······················································································229 Effect of Changing Internal Clock Sources ···································································229 Output Pins of PWM Timer Module ·············································································234 PWM Timer Registers ···································································································235 PWM Timer Parameters for 10 MHz System Clock ·····················································238 Register Configuration ···································································································242 Read Addresses of TCNT and TCSR ············································································248 SCI Input/Output Pins ····································································································257 SCI Registers ·················································································································257 Examples of BRR Settings in Asynchronous Mode·······················································265 Examples of BRR Settings in Synchronous Mode ························································269 Communication Formats Used by SCI ··········································································270 SCI Clock Source Selection ···························································································270 Data Formats in Asynchronous Mode ···········································································272 Receive Errors ···············································································································275 SCI Interrupts ·················································································································280 SSR Bit States and Data Transfer When Multiple Receive Errors Occur ·····················281 A/D Input Pins ···············································································································285 A/D Registers ·················································································································285 Assignment of Data Registers to Analog Input Channels ·············································286 A/D Conversion Time (Single Mode) ···········································································297 RAM Control Register ···································································································300 17-1 17-2 17-3 17-4 17-5 17-6 17-7 17-8 17-9 17-10 17-11 17-12 18-1 18-2 20-1 20-2 20-3 20-4 20-5 20-6 20-7 20-8 (1) 20-8 (2) 20-9 (1) 20-9 (2) 20-10 20-11 20-12 A-1 (a) A-1 (b) A-1 (c) A-1 (d) A-2 A-3 A-4 A-5 ROM Usage in Each MCU Mode ··················································································303 Selection of PROM Mode ·····························································································304 Socket Adapter ···············································································································305 Selection of Sub-Modes in PROM Mode (H8/534) ······················································308 DC Characteristics (H8/534) (When VCC = 6.0 V ±0.25 V, VPP = 12.5 V ±0.3 V, VSS = 0 V, Ta = 25˚C ±5˚C) ········310 AC Characteristics (H8/534) (When VCC = 6.0 V ±0.25 V, VPP = 12.5 V ±0.3 V, Ta = 25˚C ±5˚C) ··························310 Selection of Sub-Modes in PROM Mode (H8/536) ······················································312 DC Characteristics (H8/536) (When VCC = 6.0 V ±0.25 V, VPP = 12.5 V ±0.3 V, VSS = 0 V, Ta = 25˚C ±5˚C) ········314 AC Characteristics (H8/536) (When VCC = 6.0 V ±0.25 V, VPP = 12.5 V ±0.3 V, Ta = 25˚C ±5˚C) ··························314 PROM Writers ···············································································································316 Erasing Conditions ·········································································································318 Socket for 84-Pin LCC Package ····················································································319 Power-Down State ·········································································································321 Software Standby Control Register ···············································································323 Absolute Maximum Ratings ··························································································331 DC Characteristics (5-V Versions) ·················································································332 DC Characteristics (3-V S-Mask Versions)····································································334 DC Characteristics (2.7-V S-Mask Versions)·································································336 Allowable Output Current Values (5-V Versions) ··························································338 Allowable Output Current Values (3-V S-Mask Versions)·············································338 Allowable Output Current Values (2.7-V S-Mask Versions)··········································339 Bus Timing (R-Mask Versions) ······················································································340 Bus Timing (S-Mask Versions)·······················································································342 Control Signal Timing (R-Mask Versions)·····································································344 Control Signal Timing (S-Mask Versions) ·····································································345 Timing Conditions of On-Chip Supporting Modules ·····················································346 A/D Converter Characteristics (5-V Versions) ·······························································349 A/D Converter Characteristics························································································350 Machine Language Coding [General Format] ·······························································372 Machine Language Coding [Special Format: Short Format] ········································376 Machine Language Coding [Special Format: Branch Instruction] ································377 Machine Language Coding [Special Format: System Control Instructions] ·················378 Operation Codes in Byte 1 ·····························································································379 Operation Codes in Byte 2 (Axxx) ················································································380 Operation Codes in Byte 2 (05xx, 15xx, 0Dxx, 1Dxx, Bxxx, Cxxx, Dxxx, Exxx, Fxxx) ···················································································································381 Operation Codes in Byte 2 (04xx, 0Cxx) ······································································382 A-6 A-7 A-7 A-7 A-7 A-7 A-7 A-8 (a) A-8 (b) C-1 (a) C-1 (b) C-1 (c) C-1 (d) C-1 (e) C-1 (f) C-1 (g) C-1 (h) C-2 C-3 C-4 C-5 C-6 (a) C-6 (b) C-7 (a) C-7 (b) C-7 (c) C-7 (d) C-7 (e) C-9 (a) C-9 (b) C-9 (c) C-9 (d) C-9 (e) C-9 (f) C-9 (g) D-1 D-2 E-1 E-2 Operation Codes in Bytes 2 and 3 (11xx, 01xx, 06xx, 07xx, xx00xx) ··························383 Instruction Execution Cycles (1) ···················································································387 Instruction Execution Cycles (2) ····················································································388 Instruction Execution Cycles (3) ····················································································389 Instruction Execution Cycles (4) ····················································································390 Instruction Execution Cycles (5) ····················································································391 Instruction Execution Cycles (6) ····················································································392 Adjusted Value (Branch Instruction) ·············································································392 Adjusted Value (Other Instructions by Addressing Modes) ··········································392 Port 1 Port Read (Pin P10) ·····························································································437 Port 1 Port Read (Pin P11) ·····························································································438 Port 1 Port Read (Pin P12) ·····························································································438 Port 1 Port Read (Pin P13) ·····························································································439 Port 1 Port Read (Pin P14) ·····························································································440 Port 1 Port Read (Pin P15) ·····························································································441 Port 1 Port Read (Pin P16) ·····························································································442 Port 1 Port Read (Pin P17) ·····························································································443 Port 2 Port Read ·············································································································444 Port 3 Port Read ·············································································································445 Port 4 Port Read ·············································································································446 Port 5 Port Read ·············································································································447 Port 6 Port Read (Pin P60) ·····························································································448 Port 6 Port Read (Pin P61 to P63) ··················································································449 Port 7 Port Read (Pin P70) ·····························································································450 Port 7 Port Read (Pins P71, P72) ····················································································451 Port 7 Port Read (Pin P73) ·····························································································452 Port 7 Port Read (Pins P74 to P76) ················································································453 Port 7 Port Read (Pin P77) ·····························································································454 Port 9 Port Read (Pins P90, P91) ····················································································456 Port 9 Port Read (Pin P92) ·····························································································457 Port 9 Port Read (Pin P93) ·····························································································458 Port 9 Port Read (Pin P94) ·····························································································459 Port 9 Port Read (Pin P95) ·····························································································460 Port 9 Port Read (Pin P96) ·····························································································461 Port 9 Port Read (Pin P97) ·····························································································462 H8/534 Memory Map ····································································································463 H8/536 Memory Map ····································································································464 Port State ························································································································465 MOS Pull-Up State ········································································································467 Section 1 Overview 1.1 Features The H8/534 and H8/536 are CMOS microcomputer units (MCUs) comprising a CPU core plus a full range of supporting functions—an entire system integrated onto a single chip. The CPU features a highly orthogonal instruction set that permits addressing modes and data sizes to be specified independently in each instruction. An internal 16-bit architecture and 16-bit access to on-chip memory enhance the CPU’s data-processing capability and provide the speed needed for realtime control applications. The on-chip supporting functions include RAM, ROM, timers, a serial communication interface (SCI), A/D conversion, and I/O ports. An on-chip data transfer controller (DTC) can transfer data in either direction between memory and I/O independently of the CPU. For the on-chip ROM, a choice is offered between masked ROM and programmable ROM (PROM). The PROM version can be programmed by the user with a general-purpose PROM writer. Table 1-1 lists the main features of the H8/534 and H8/536. 1 Table 1-1 Features Feature CPU Memory (H8/534) Memory (H8/536) 16-Bit freerunning timer (FRT) (3 channels) 8-Bit timer (1 channel) PWM timer (3 channels) Watchdog timer (WDT) (1 channel) Description General-register machine • Eight 16-bit general registers • Five 8-bit and two 16-bit control registers High speed • Maximum clock rate: 10 MHz (oscillator frequency: 20 MHz, R-mask versions) 16 MHz (oscillator frequency: 32 MHz, S-mask versions) Expanded operating modes supporting external memory • Minimum mode: up to 64-kbyte address space • Maximum mode: up to 1 M-byte address space Highly orthogonal instruction set • Addressing modes and data size can be specified independently for each instruction 1.5 Addressing modes • Register-register operations • Register-memory operations Instruction set optimized for C language • Special short formats for frequently-used instructions and addressing modes • 2-kbyte high-speed RAM on-chip • 32-kbyte programmable or masked ROM on-chip • 2-kbyte high-speed RAM on-chip • 62-kbyte programmable or masked ROM on-chip Each channel provides: • 1 free-running counter (which can count external events) • 2 output-compare registers • 1 input capture register • One 8-bit up-counter (which can count external events) • 2 time constant registers • Generates pulses with any duty ratio from 0 to 100% • Resolution: 1/250 • An overflow generates a nonmaskable interrupt • Can also be used as an interval timer 2 Table 1-1 Features (cont) Feature Serial communication interface (SCI) (2 channels) A/D converter Description • Asynchronous or synchronous mode (selectable) • Full duplex: can send and receive simultaneously • Built-in baud rate generator Product line-up (H8/534 R-mask versions) Model Name Package Options ROM HD6475348RCG 84-Pin windowed LCC (CG-84) PROM HD6475348RCP 84-Pin PLCC (CP-84) HD6475348RF 80-Pin QFP (FP-80A) HD6435348RCP 84-Pin PLCC (CP-84) Mask HD6435348RF 80-Pin QFP (FP-80A) ROM Model Name Package Options ROM HD6475348SCG 84-Pin windowed LCC (CG-84) PROM HD6475348SCP 84-Pin PLCC (CP-84) HD6475348SF 80-Pin QFP (FP-80A) HD6475348STF 80-Pin TQFP (TFP-80C) • 10-Bit resolution • 8 channels, controllable in single mode or scan mode (selectable) • Sample-and-hold function • Start of A/D conversion can be externally triggered I/O ports • 57 Input/output pins (six 8-bit ports, one 5-bit port, one 4-bit port) • 8 Input-only pins (one 8-bit port) Interrupt • 7 external interrupt pins (NMI, IRQ0, IRQ1 to IRQ5) controller • 23 internal interrupts (INTC) • 8 priority levels Data transfer Performs bidirectional data transfer between memory and I/O independently controller (DTC) of the CPU Wait-state Can insert wait states in access to external memory or I/O controller (WSC) Operating 5 MCU operating modes modes • Expanded minimum modes, supporting up to 64 kbytes external memory with or without using on-chip ROM (Modes 1 and 2) • Expanded maximum modes, supporting up to 1 Mbyte external memory with or without using on-chip ROM (Modes 3 and 4) • Single-chip mode (Mode 7) 3 power-down modes • Sleep mode • Software standby mode • Hardware standby mode Other features • E clock output available • Clock generator on-chip Product line-up (H8/534 S-mask versions) HD6435348SCP 84-Pin PLCC (CP-84) Mask HD6435348SF 80-Pin QFP (FP-80A) ROM HD6435348STF 80-Pin TQFP (TFP-80C) 3 Table 1-1 Features (cont) Feature Description Product line-up (H8/536 R-mask versions) Model Name Package Options ROM HD6475368RCG 84-Pin windowed LCC (CG-84) PROM HD6475368RCP 84-Pin PLCC (CP-84) HD6475368RF 80-Pin QFP (FP-80A) HD6435368RCP 84-Pin PLCC (CP-84) Mask HD6435368RF 80-Pin QFP (FP-80A) ROM Model Name Package Options ROM HD6475368SCG 84-Pin windowed LCC (CG-84) PROM HD6475368SCP 84-Pin PLCC (CP-84) HD6475368SF 80-Pin QFP (FP-80A) HD6475368STF 80-Pin TQFP (TFP-80C) Product line-up (H8/536 S-mask versions) HD6435368SCP 84-Pin PLCC (CP-84) Mask HD6435368SF 80-Pin QFP (FP-80A) ROM HD6435368STF 80-Pin TQFP (TFP-80C) Product line-up Model name Regular Versions 16-MHz High- 3-V Speed Low-Voltage Versions Versions* 2.7-V Low-Voltage Versions* PROM HD6475368R HD6475348R HD6475368S HD6475348S HD6475368SV HD6475348SV HD6475368SV HD6475348SV Mask ROM HD6435368R HD6435348R HD6435368S HD6435348S HD6435368SV HD6435348SV HD6435368SV HD6435348SV 0.5 MHz to 10 MHz 5 V ± 10% 2 MHz to 16 MHz 5 V ± 10% 2 MHz to 10 MHz 3 V to 5.5 V 2 MHz to 8 MHz 2.7 V to 5.5 V Clock speed Supply voltage Notes: The product codes of the 3-V and 2.7-V low-voltage versions include a suffix that identifies the clock speed. Examples are shown below for the H8/536 PROM version in an 80-pin QFP package. Examples: 3-V versions: HD6475368SVF10 2.7-V versions: HD6475368SVF8 * Under development 4 1.2 Block Diagram P2 4 /WR P2 3 /RD P2 2 /DS P2 1 /R/W P2 0 /AS P3 7 /D 7 P3 6 /D 6 P3 5 /D 5 P3 4 /D 4 P3 3 /D 3 P3 2 /D 2 P3 1 /D 1 P3 0 /D 0 Port 2 Port 3 NMI Serial Communication Interface PWM Timer (x 3 channels) 10-bit A/D Converter P6 3 /PW 3 /IRQ 5 /A 19 P6 2 /PW 2 /IRQ 4 /A 18 P6 1 /PW 1 /IRQ 3 /A 17 P6 0 /IRQ 2 /A 16 16-bit Free Running Timer (x 3 channels) Watchdog Timer Port 8 Port 7 P77 /FTOA1 P76 /FTOB 3 /FTCI 3 P7 5 /FTOB 2 /FTCI 2 P74 /FTOB 1 /FTCI 1 P73 /FTI 3 /TMRI P72 /FTI 2 P71 /FTI 1 P70 /TMCI P9 7 /SCK 1 P9 6 /RXD 1 P9 5 /TXD 1 P9 4 /SCK 2 /PW 3 P9 3/RXD 2 /PW 2 P92 /TXD 2 /PW 1 P9 1/FTOA 3 P9 0/FTOA 2 Port 9 8-bit Timer P8 7 /AN 7 P8 6 /AN 6 P8 5 /AN 5 P8 4 /AN 4 P8 3 /AN 3 P8 2 /AN 2 P8 1 /AN 1 P8 0 /AN 0 AV cc AV ss P5 7 /A 15 P5 6 /A 14 P5 5 /A 13 P5 4 /A 12 P5 3 /A 11 P5 2 /A 10 P5 1 /A 9 P5 0 /A 8 CPU Data Transfer Controller V cc V cc V ss V ss V ss V ss * V ss V ss Port 4 Interrupt Controller Port 5 PROM/Mask ROM 32 kbytes (H8/534) 62 kbytes (H8/536) RAM 2 kbyte P4 7 /A 7 P4 6 /A 6 P4 5 /A 5 P4 4 /A 4 P4 3 /A 3 P4 2 /A 2 P4 1 /A 1 P4 0 /A 0 Port 6 WaitState Controller Address bus Clock Generator Data bus (High) RES STBY MD0 MD1 MD2 Port 1 Data bus (Low) EXTAL XTAL P1 7 /TMO P1 6 /IRQ 1 /ADTRG P1 5 /IRQ 0 P1 4 /WAIT P1 3 /BREQ P1 2 /BACK P1 1 /E P1 0 /ø Figure 1-1 shows a block diagram of the H8/534 and H8/536. * CP-84 and CG-84 only Figure 1-1 Block Diagram 5 1.3 Pin Arrangements and Functions 1.3.1 Pin Arrangement P20 /AS P17 /TMO P16 /IRQ 1 /ADTRG P15 /IRQ 0 P14 /WAIT P13 /BREQ P12 /BACK P11 /E P10 /ø Vss XTAL EXTAL Vss P97 /SCK 1 P96 /RXD 1 P95 /TXD 1 P94 /SCK 2 /PW 3 P93 /RXD2 /PW 2 P92 /TXD 2 /PW 1 P91 /FTOA3 P90 /FTOA2 Figure 1-2 shows the pin arrangement of the CP-84 package. Figure 1-3 shows the pin arrangement of the CG-84 package. Figure 1-4 shows the pin arrangement of the FP-80A package. These pin arrangements apply to both the H8/534 and H8/536. 11 10 9 8 7 6 5 4 3 2 1 84 83 82 81 80 79 78 77 76 75 12 74 13 73 14 72 15 71 16 70 17 69 18 68 19 67 20 66 21 22 65 64 PLCC-84 23 63 24 62 25 61 26 60 27 59 28 58 29 57 30 56 31 55 32 54 AVcc P87 /AN7 P86 /AN6 P85 /AN5 P84 /AN4 P83 /AN3 P82 /AN2 P81 /AN1 P80 /AN0 AVss Vss P77 /FTOA1 P76 /FTOB 3 /FTCI 3 P75 /FTOB 2 /FTCI 2 P74 /FTOB 1 /FTCI 1 P73 /FTI 3 /TMRI P72 /FTI 2 P71 /FTI 1 P70 /TMCI Vcc P63 /PW3 /IRQ 5 /A19 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 P40 /A 0 P41 /A 1 P42 /A 2 P43 /A 3 P44 /A 4 P45 /A 5 P46 /A 6 P47 /A 7 Vss Vss P50 /A 8 P51 /A 9 P5 2 /A 10 P5 3 /A 11 P5 4 /A 12 P5 5 /A 13 P5 6 /A 14 P5 7 /A 15 P6 0 /IRQ 2/A 16 P6 1/PW 1 /IRQ 3/A 17 P6 2/PW 2 /IRQ 4/A 18 P21 /R/W P22 /DS P23 /RD P24 /WR Vcc MD0 MD1 MD2 STBY RES NMI NC Vss P30 /D0 P31 /D1 P32 /D2 P33 /D3 P34 /D4 P35 /D5 P36 /D6 P37 /D7 1 pin 1 pin H8/534 HD6475348CP H8/536 HD6475368CP Figure 1-2 Pin Arrangement (CP-84, Top View) 6 JAPAN JAPAN P20 /AS P17 /TMO P16 /IRQ 1 /ADTRG P15 /IRQ 0 P14 /WAIT P13 /BREQ P12 /BACK P11 /E P10 /ø Vss XTAL EXTAL Vss P97 /SCK 1 P96 /RXD1 P95 /TXD 1 P94 /SCK 2 /PW 3 P93 /RXD2 /PW2 P92 /TXD 2 /PW 1 P91 /FTOA3 P90 /FTOA2 11 10 9 8 7 6 5 4 3 2 1 84 83 82 81 80 79 78 77 76 75 12 74 13 73 14 72 15 71 16 70 17 69 18 68 19 67 20 66 21 22 65 LCC-84 64 23 63 24 62 25 61 26 60 27 59 28 58 29 57 30 56 31 55 32 54 AVcc P87 /AN7 P86 /AN6 P85 /AN5 P84 /AN4 P83 /AN3 P82 /AN2 P81 /AN1 P80 /AN0 AVss Vss P77 /FTOA1 P76 /FTOB 3 /FTCI 3 P75 /FTOB 2 /FTCI 2 P74 /FTOB 1 /FTCI 1 P73 /FTI 3 /TMRI P72 /FTI 2 P71 /FTI 1 P70 /TMCI Vcc P63 /PW3 /IRQ 5 /A19 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 P40 /A 0 P41 /A 1 P42 /A 2 P43 /A 3 P44 /A 4 P45 /A 5 P46 /A 6 P47 /A 7 Vss Vss P50 /A 8 P51 /A 9 P5 2 /A 10 P5 3 /A 11 P5 4 /A 12 P5 5 /A 13 P5 6 /A 14 P5 7 /A 15 P6 0/IRQ 2 /A 16 P6 1/PW 1 /IRQ 3 /A 17 P6 2/PW 2 /IRQ 4 /A 18 P21 /R/W P22 /DS P23 /RD P24 /WR Vcc MD0 MD1 MD2 STBY RES NMI NC Vss P30 /D0 P31 /D1 P32 /D2 P33 /D3 P34 /D4 P35 /D5 P36 /D6 P37 /D7 Index Index H8/534 HD6475348CG JAPAN Figure 1-3 Pin Arrangement (CG-84, Top View) 7 H8/536 HD6475368CG JAPAN P20 /AS P17 /TMO P16 /IRQ 1 /ADTRG P15 /IRQ 0 P14 /WAIT P13 /BREQ P12 /BACK P11 /E P10 /ø Vss XTAL EXTAL P97 /SCK 1 P96 /RXD1 P95 /TXD 1 P94 /SCK 2 /PW 3 P93 /RXD2 /PW2 P92 /TXD 2 /PW 1 P91 /FTOA3 P90 /FTOA2 1 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 2 59 3 58 4 57 5 56 6 55 7 54 8 53 9 52 10 51 QFP-80A TQFP-80C 11 12 AVcc P87 /AN7 P86 /AN6 P85 /AN5 P84 /AN4 P83 /AN3 P82 /AN2 P81 /AN1 P80 /AN0 AVss P77 /FTOA1 P76 /FTOB 3 /FTCI 3 P75 /FTOB 2 /FTCI 2 P74 /FTOB 1 /FTCI 1 P73 /FTI 3 /TMRI P72 /FTI 2 P71 /FTI 1 P70 /TMCI Vcc P63 /PW3 /IRQ 5 /A19 50 49 13 48 14 47 15 46 16 45 17 44 18 43 19 42 20 41 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 P40 /A 0 P41 /A 1 P42 /A 2 P43 /A 3 P44 /A 4 P45 /A 5 P46 /A 6 P47 /A 7 Vss P50 /A 8 P51 /A 9 P5 2 /A 10 P5 3 /A 11 P5 4 /A 12 P5 5 /A 13 P5 6 /A 14 P5 7 /A 15 P6 0 /IRQ 2 /A 16 P6 1 /PW1 /IRQ 3 /A 17 P6 2 /PW2 /IRQ 4 /A 18 P21 /R/W P22 /DS P23 /RD P24 /WR Vcc MD0 MD1 MD2 STBY RES NMI Vss P30 /D0 P31 /D1 P32 /D2 P33 /D3 P34 /D4 P35 /D5 P36 /D6 P37 /D7 TQFP-80C H8/534 HD6475348TF H8/536 HD6475368TF JAPAN Pin 1 QFP-80A H8/534 HD6475348F H8/536 HD6475368F JAPAN JAPAN Pin 1 Pin 1 JAPAN Pin 1 Figure 1-4 Pin Arrangement (FP-80A, TFP-80C, Top View) 8 1.3.2 Pin Functions Pin Arrangements in Each Operating Mode: Table 1-2 lists the arrangements of the pins of the CP-84 and CG-84 packages in each operating mode. Table 1-3 lists the arrangements for the FP-80A package. Table 1-2 Pin Arrangements in Each Operating Mode (CP-84, CG-84) Pin No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 Expanded Minimum Modes Mode 1 Mode 2 XTAL XTAL VSS VSS P10/ø P10/ø P11/E P11/E P12 / BACK P12 / BACK P13 / BREQ P13 / BREQ P14 / WAIT P14 / WAIT P15 / IRQ0 P15 / IRQ0 P16 / IRQ1 / P16 / IRQ1 / ADTRG ADTRG P17 / TMO P17 / TMO AS AS R/W R/W DS DS RD RD WR WR VCC VCC MD0 MD0 MD1 MD1 Pin Name Expanded Maximum Modes Mode 3 Mode 4 XTAL XTAL VSS VSS P10/ø P10/ø P11/E P11/E P12 / BACK P12 / BACK P13 / BREQ P13 / BREQ P14 / WAIT P14 / WAIT P15 / IRQ0 P15 / IRQ0 P16 / IRQ1 / P16 / IRQ1 / ADTRG ADTRG P17 / TMO P17 / TMO AS AS R/W R/W DS DS RD RD WR WR VCC VCC MD0 MD0 MD1 MD1 Notes: 1. For the PROM mode, see section 17, “ROM.” 2. Pins marked NC should be left unconnected. 9 Single-Chip Mode Mode 7 XTAL VSS P10/ø P11/E P12 P13 P14 P15 / IRQ0 P16 / IRQ1 / ADTRG P17 / TMO P20 P21 P22 P23 P24 VCC MD0 MD1 PROM Mode H8/534 H8/536 NC VSS NC NC NC NC NC NC NC NC VSS NC NC NC NC A15 A16 PGM NC NC NC NC NC NC VCC VSS VSS NC NC NC NC NC NC VCC VSS VSS Table 1-2 Pin Arrangements in Each Operating Mode (CP-84, CG-84) (cont) Pin No. 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 Expanded Minimum Modes Mode 1 Mode 2 MD2 MD2 STBY STBY RES RES NMI NMI NC NC VSS VSS D0 D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6 D7 D7 A0 A0 A1 A1 A2 A2 A3 A3 A4 A4 A5 A5 A6 A6 A7 A7 VSS VSS Pin Name Expanded Maximum Modes Mode 3 Mode 4 MD2 MD2 STBY STBY RES RES NMI NMI NC NC VSS VSS D0 D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6 D7 D7 A0 A0 A1 A1 A2 A2 A3 A3 A4 A4 A5 A5 A6 A6 A7 A7 VSS VSS Notes: 1. For the PROM mode, see section 17, “ROM.” 2. Pins marked NC should be left unconnected. 10 Single-Chip Mode Mode 7 MD2 STBY RES NMI NC VSS P30 P31 P32 P33 P34 P35 P36 P37 P40 P41 P42 P43 P44 P45 P46 P47 VSS PROM Mode H8/534 H8/536 VSS VSS VPP A9 NC VSS O0 O1 O2 O3 O4 O5 O6 O7 A0 A1 A2 A3 A4 A5 A6 A7 VSS VSS VSS VPP A9 NC VSS O0 O1 O2 O3 O4 O5 O6 O7 A0 A1 A2 A3 A4 A5 A6 A7 VSS Table 1-2 Pin Arrangements in Each Operating Mode (CP-84, CG-84) (cont) Pin No. 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 Pin Name Expanded Maximum Modes Mode 3 Mode 4 VSS VSS A8 P50 / A8 A9 P51 / A9 A10 P52 / A10 A11 P53 / A11 A12 P54 / A12 A13 P55 / A13 A14 P56 / A14 A15 P57 / A15 A16 P60 / IRQ2 / A16 P61 / PW1 / A17 P61 / IRQ3 / IRQ3 A17 P62 / PW2 / A18 P62 / IRQ4 / IRQ4 A18 P63 / PW3 / A19 P63 / IRQ5 / IRQ5 A19 VCC VCC VCC P70 / TMCI P70 / TMCI P70 / TMCI P71 / FTI1 P71 / FTI1 P71 / FTI1 P72 / FTI2 P72 / FTI2 P72 / FTI2 P73 / FTI3 / P73 / FTI3 / P73 / FTI3 / TMRI TMRI TMRI P74 / FTOB1 / P74 / FTOB1 / P74 / FTOB1 / FTCI1 FTCI1 FTCI1 P75 / FTOB2 / P75 / FTOB2 / P75 / FTOB2 / FTCI2 FTCI2 FTCI2 Expanded Minimum Modes Mode 1 Mode 2 VSS VSS A8 P50 / A8 A9 P51 / A9 A10 P52 / A10 A11 P53 / A11 A12 P54 / A12 A13 P55 / A13 A14 P56 / A14 A15 P57 / A15 P60 / IRQ2 P60 / IRQ2 Single-Chip Mode Mode 7 VSS P50 P51 P52 P53 P54 P55 P56 P57 P60 / IRQ2 P61 / PW1 / IRQ3 P62 / PW2 / IRQ4 P63 / PW3 / IRQ5 VCC P70 / TMCI P71 / FTI1 P72 / FTI2 P73 / FTI3 / TMRI P74 / FTOB1 / FTCI1 P75 / FTOB2 / FTCI2 P61 / PW1 / IRQ3 P62 / PW2 / IRQ4 P63 / PW3 / IRQ5 VCC P70 / TMCI P71 / FTI1 P72 / FTI2 P73 / FTI3 / TMRI P74 / FTOB1 / FTCI1 P75 / FTOB2 / FTCI2 Notes: 1. For the PROM mode, see section 17, “ROM.” 2. Pins marked NC should be left unconnected. 11 PROM Mode H8/534 H8/536 VSS A8 OE A10 A11 A12 A13 A14 CE VCC VSS A8 OE A10 A11 A12 A13 A14 CE VCC VCC VCC NC NC NC NC VCC NC NC NC NC VCC NC NC NC NC NC NC NC NC Table 1-2 Pin Arrangements in Each Operating Mode (CP-84, CG-84) (cont) Pin No. 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 Pin Name Expanded Minimum Expanded Maximum Modes Modes Mode 1 Mode 2 Mode 3 Mode 4 P76 / FTOB3 / P76 / FTOB3 / P76 / FTOB3 / P76 / FTOB3 / FTCI3 FTCI3 FTCI3 FTCI3 P77 / FTOA1 P77 / FTOA1 P77 / FTOA1 P77 / FTOA1 VSS VSS VSS VSS AVSS AVSS AVSS AVSS P80 / AN0 P80 / AN0 P80 / AN0 P80 / AN0 P81 / AN1 P81 / AN1 P81 / AN1 P81 / AN1 P82 / AN2 P82 / AN2 P82 / AN2 P82 / AN2 P83 / AN3 P83 / AN3 P83 / AN3 P83 / AN3 P84 / AN4 P84 / AN4 P84 / AN4 P84 / AN4 P85 / AN5 P85 / AN5 P85 / AN5 P85 / AN5 P86 / AN6 P86 / AN6 P86 / AN6 P86 / AN6 P87 / AN7 P87 / AN7 P87 / AN7 P87 / AN7 AVCC AVCC AVCC AVCC P90 / FTOA2 P90 / FTOA2 P90 / FTOA2 P90 / FTOA2 P91 / FTOA3 P91 / FTOA3 P91 / FTOA3 P91 / FTOA3 P92 / TXD2 / P92 / TXD2 / P92 / TXD2 / P92 / TXD2 / PW1 PW1 PW1 PW1 P93 / RXD2 / P93 / RXD2 / P93 / RXD2 / P93 / RXD2 / PW2 PW2 PW2 PW2 P94 / SCK2 / P94 / SCK2 / P94 / SCK2 / P94 / SCK2 / PW3 PW3 PW3 PW3 P95 / TXD1 P95 / TXD1 P95 / TXD1 P95 / TXD1 P96 / RXD1 P96 / RXD1 P96 / RXD1 P96 / RXD1 P97 / SCK1 P97 / SCK1 P97 / SCK1 P97 / SCK1 VSS VSS VSS VSS EXTAL EXTAL EXTAL EXTAL Notes: 1. For the PROM mode, see section 17, “ROM.” 2. Pins marked NC should be left unconnected. 12 Single-Chip Mode Mode 7 P76/ FTOB3 / FTCI3 P77 / FTOA1 VSS AVSS P80 / AN0 P81 / AN1 P82 / AN2 P83 / AN3 P84 / AN4 P85 / AN5 P86 / AN6 P87 / AN7 AVCC P90 / FTOA2 P91 / FTOA3 P92 / TXD2 / PW1 P93 / RXD2 / PW2 P94 / SCK2 / PW3 P95 / TXD1 P96 / RXD1 P97 / SCK1 VSS EXTAL PROM Mode H8/534 H8/536 NC NC NC VSS VSS NC NC NC NC NC NC NC NC VCC NC NC NC NC VSS VSS NC NC NC NC NC NC NC NC VCC NC NC NC NC NC NC NC NC NC NC VSS NC NC NC NC VSS NC Table 1-3 Pin Arrangements in Each Operating Mode (FP-80A, TFP-80C) Pin No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 Expanded Minimum Modes Mode 1 Mode 2 R/W R/W DS DS RD RD WR WR VCC VCC MD0 MD0 MD1 MD1 MD2 MD2 STBY STBY RES RES NMI NMI VSS VSS D0 D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6 D7 D7 A0 A0 Pin Name Expanded Maximum Modes Mode 3 Mode 4 R/W R/W DS DS RD RD WR WR VCC VCC MD0 MD0 MD1 MD1 MD2 MD2 STBY STBY RES RES NMI NMI VSS VSS D0 D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6 D7 D7 A0 A0 Notes: 1. For the PROM mode, see section 17, “ROM.” 2. Pins marked NC should be left unconnected. 13 Single-Chip Mode Mode 7 P21 P22 P23 P24 VCC MD0 MD1 MD2 STBY RES NMI VSS P30 P31 P32 P33 P34 P35 P36 P37 P40 PROM Mode H8/534 H8/536 NC NC NC NC VCC VSS VSS VSS VSS VPP A9 VSS O0 O1 O2 O3 O4 O5 O6 O7 A0 NC NC NC NC VCC VSS VSS VSS VSS VPP A9 VSS O0 O1 O2 O3 O4 O5 O6 O7 A0 Table 1-3 Pin Arrangements in Each Operating Mode (FP-80A, TFP-80C) (cont) Pin No. 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 Expanded Minimum Modes Mode 1 Mode 2 A1 A1 A2 A2 A3 A3 A4 A4 A5 A5 A6 A6 A7 A7 VSS VSS A8 P50 / A8 A9 P51 / A9 A10 P52 / A10 A11 P53 / A11 A12 P54 / A12 A13 P55 / A13 A14 P56 / A14 A15 P57 / A15 P60 / IRQ2 P60 / IRQ2 P61 / PW1 / IRQ3 P62 / PW2 / IRQ4 P63 / PW3 / IRQ5 VCC P61 / PW1 / IRQ3 P62 / PW2 / IRQ4 P63 / PW3 / IRQ5 VCC Pin Name Expanded Maximum Modes Mode 3 Mode 4 A1 A1 A2 A2 A3 A3 A4 A4 A5 A5 A6 A6 A7 A7 VSS VSS A8 P50/ A8 A9 P51/ A9 A10 P52/ A10 A11 P53 / A11 A12 P54 / A12 A13 P55 / A13 A14 P56 / A14 A15 P57 / A15 A16 P60 / IRQ2 / A16 A17 P61 / IRQ3 / A17 A18 P62 / IRQ4 / A18 A19 P63 / IRQ5 / A19 VCC VCC Notes: 1. For the PROM mode, see section 17, “ROM.” 2. Pins marked NC should be left unconnected. 14 Single-Chip Mode Mode 7 P41 P42 P43 P44 P45 P46 P47 VSS P50 P51 P52 P53 P54 P55 P56 P57 P60 / IRQ2 P61 / PW1 / IRQ3 P62 / PW2 / IRQ4 P63 / PW3 / IRQ5 VCC PROM Mode H8/534 H8/536 A1 A2 A3 A4 A5 A6 A7 VSS A8 OE A10 A11 A12 A13 A14 CE VCC A1 A2 A3 A4 A5 A6 A7 VSS A8 OE A10 A11 A12 A13 A14 CE VCC VCC VCC NC NC NC NC VCC VCC Table 1-3 Pin Arrangements in Each Operating Mode (FP-80A, TFP-80C) (cont) Pin No. 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 Expanded Minimum Modes Mode 1 Mode 2 P70 / TMCI P70/ TMCI P71 / FTI1 P71/ FTI1 P72 / FTI2 P72 / FTI2 P73 / FTI3 / P73 / FTI3 / TMRI TMRI P74 / FTOB1 / P74 / FTOB1 / FTCI1 FTCI1 P75 / FTOB2 / P75 / FTOB2 / FTCI2 FTCI2 P76 / FTOB3 / P76 / FTOB3 / FTCI3 FTCI3 P77 / FTOA1 P77 / FTOA1 AVSS AVSS P80 / AN0 P80 / AN0 P81 / AN1 P81 / AN1 P82 / AN2 P82 / AN2 P83 / AN3 P83 / AN3 P84 / AN4 P84 / AN4 P85 / AN5 P85 / AN5 P86 / AN6 P86 / AN6 P87 / AN7 P87 / AN7 Pin Name Expanded Maximum Modes Mode 3 Mode 4 P70/ TMCI P70/ TMCI P71/ FTI1 P71/ FTI1 P72 / FTI2 P72 / FTI2 P73 / FTI3 / P73 / FTI3 / TMRI TMRI P74 / FTOB1 / P74/ FTOB1 / FTCI1 FTCI1 P75 / FTOB2 / P75 / FTOB2 / FTCI2 FTCI2 P76 / FTOB3 / P76 / FTOB3 / FTCI3 FTCI3 P77 / FTOA1 P77 / FTOA1 AVSS AVSS P80 / AN0 P80 / AN0 P81 / AN1 P81 / AN1 P82 / AN2 P82 / AN2 P83 / AN3 P83 / AN3 P84 / AN4 P84 / AN4 P85 / AN5 P85 / AN5 P86 / AN6 P86 / AN6 P87 / AN7 P87 / AN7 Notes: 1. For the PROM mode, see section 17, “ROM.” 2. Pins marked NC should be left unconnected. 15 Single-Chip Mode Mode 7 P70/ TMCI P71/ FTI1 P72 / FTI2 P73 / FTI3 / TMRI P74 / FTOB1 / FTCI1 P75 / FTOB2 / FTCI2 P76 / FTOB3 / FTCI3 P77 / FTOA1 AVSS P80 / AN0 P81 / AN1 P82 / AN2 P83 / AN3 P84 / AN4 P85 / AN5 P86 / AN6 P87 / AN7 PROM Mode H8/534 H8/536 NC NC NC NC NC NC NC NC NC NC NC NC NC NC NC VSS NC NC NC NC NC NC NC NC NC VSS NC NC NC NC NC NC NC NC Table 1-3 Pin Arrangements in Each Operating Mode (FP-80A, TFP-80C) (cont) Pin No. 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 Expanded Minimum Modes Mode 1 Mode 2 AVCC AVCC P90 / FTOA2 P90 / FTOA2 P91 / FTOA3 P91 / FTOA3 P92 / PW1 P92 / PW1 P93 / PW2 P93 / PW2 P94 / PW3 P94 / PW3 P95 / TXD P95 / TXD P96 / RXD P96 / RXD P97 / SCK P97 / SCK EXTAL EXTAL XTAL XTAL VSS VSS P10 / ø P10 / ø P11 / E P11 / E P12 / BACK P12 / BACK P13 / BREQ P13 / BREQ P14 / WAIT P14 / WAIT P15 / IRQ0 P15 / IRQ0 P16 / IRQ1 / P16 / IRQ1 / ADTRG ADTRG P17 / TMO P17 / TMO AS AS Pin Name Expanded Maximum Modes Mode 3 Mode 4 AVCC AVCC P90 / FTOA2 P90 / FTOA2 P91 / FTOA3 P91 / FTOA3 P92 / PW1 P92 / PW1 P93 / PW2 P93 / PW2 P94 / PW3 P94 / PW3 P95 / TXD P95 / TXD P96 / RXD P96 / RXD P97 / SCK P97 / SCK EXTAL EXTAL XTAL XTAL VSS VSS P10 / ø P10 / ø P11 / E P11 / E P12 / BACK P12 / BACK P13 / BREQ P13 / BREQ P14 / WAIT P14 / WAIT P15 / IRQ0 P15 / IRQ0 P16 / IRQ1 / P16 / IRQ1 / ADTRG ADTRG P17 / TMO P17 / TMO AS AS Notes: 1. For the PROM mode, see section 17, “ROM.” 2. Pins marked NC should be left unconnected. 16 Single-Chip Mode Mode 7 AVCC P90 / FTOA2 P91 / FTOA3 P92 / PW1 P93 / PW2 P94 / PW3 P95 / TXD P96 / RXD P97 / SCK EXTAL XTAL VSS P10 / ø P11 / E P12 P13 P14 P15 / IRQ0 P16 / IRQ1 / ADTRG P17 / TMO P20 PROM Mode H8/534 H8/536 VCC NC NC NC NC NC NC NC NC NC NC VSS NC NC NC NC NC NC NC VCC NC NC NC NC NC NC NC NC NC NC VSS NC NC NC NC A15 A16 PGM NC NC NC NC Pin Functions: Table 1-4 gives a concise description of the function of each pin. Table 1-4 Pin Functions Type Power Clock System control Symbol VCC Pin No. CP-84, FP-80A, CG-84 TFP-80C 16, 55 5, 42 I/O I VSS 2, 24 41, 42 64, 83 12, 29 71 I XTAL 1 70 I EXTAL 84 69 I ø 3 72 O E 4 73 O BACK 5 74 O Name and Function Power: Connected to the power supply (+5 V). Connect both VCC pins to the system power supply (+5 V). The chip will not operate if either pin is left unconnected. Ground: Connected to ground (0 V). Connect all VSS pins to the system power supply (0 V). The chip will not operate if any VSS pin is left unconnected. Crystal: Connected to a crystal oscillator. The crystal frequency should be double the desired ø clock frequency. If an external clock is input at the EXTAL pin, leave the XTAL pin unconnected. External Crystal: Connected to a crystal oscillator or external clock. The frequency of the external clock should be double the desired ø clock frequency. See section 8.2, “Oscillator Circuit” for examples of connections to a crystal and external clock. System Clock: Supplies the ø clock to peripheral devices. Enable Clock: Supplies an E clock to E clock based peripheral devices. Bus Request Acknowledge: Indicates that the bus right has been granted to an external device. Notifies an external device that issued a BREQ signal that it now has control of the bus. 17 Table 1-4 Pin Functions (cont) Type System control Address bus Data bus Bus control Symbol BREQ Pin No. CP-84, FP-80A, CG-84 TFP-80C 6 75 I/O I STBY 20 9 I RES 21 10 I/O A19 – A8 A7 – A0 D7 – D0 WAIT 54 – 43 40 – 33 32 – 25 7 41 – 30 28 – 21 20 – 13 76 O I/O I AS 11 80 O R/W 12 1 O DS 13 2 O RD 14 3 O WR 15 4 O Name and Function Bus Request: Sent by an external device to the H8/534 or H4/536 to request the bus right. Standby: A transition to the hardware standby mode (a power-down state) occurs when a Low input is received at the STBY pin. Reset: Low input or low output due to watchdog timer overflow causes the H8/534 or H8/536 chip to reset. Address Bus: Address output pins. Data Bus: 8-Bit bidirectional data bus. Wait: Requests the CPU to insert one or more Tw states when accessing an off-chip address. Address Strobe: Goes Low to indicate that there is a valid address on the address bus. Read/Write: Indicates whether the CPU is reading or writing data on the bus. • High—Read • Low—Write Data Strobe: Goes Low to indicate the presence of valid data on the data bus. Read: Goes Low to indicate that the CPU is reading an external address. Write: Goes Low to indicate that the CPU is writing to an external address. 18 Table 1-4 Pin Functions (cont) Type Symbol Interrupt NMI Pin No. CP-84, FP-80A, CG-84 TFP-80C 22 11 IRQ0 IRQ1 IRQ2 IRQ3 IRQ4 IRQ5 OperatingMD2 mode MD1 control MD0 8 9 51 52 53 54 19 18 17 77 78 38 39 40 41 8 7 6 I/O I I I Name and Function NonMaskable Interrupt: Highest-priority interrupt request. The port 1 control register (P1CR) determines whether the interrupt is requested on the rising or falling edge of the NMI input. Interrupt Request 0 and 1: Maskable interrupt request pins. Mode: Input pins for setting the MCU operating mode according to the table below. MD2 MD1 MD0 Mode 0 0 0 Mode 0 0 0 1 Mode 1 0 1 0 Mode 2 0 1 1 Mode 3 1 0 0 Mode 4 1 1 1 0 1 1 1 0 1 Mode 5 Mode 6 Mode 7 Description — Expanded minimum mode (ROM disabled) Expanded minimum mode (ROM enabled) Expanded maximum mode (ROM disabled) Expanded maximum mode (ROM enabled) — — Single-chip mode The inputs at these pins must not be changed while the chip is operating. 19 Table 1-4 Pin Functions (cont) Type 16-Bit freerunning timer (FRT) 8-Bit timer PWM timer Symbol FTOA1 FTOA2 FTOA3 FTOB1 FTOB2 FTOB3 FTCI1 FTCI2 FTCI3 Pin No. CP-84, FP-80A, CG-84 TFP-80C 63 50 75 61 76 62 60 47 61 48 62 49 60 47 61 48 62 49 FTI1 FTI2 FTI3 TMO 57 58 59 10 44 45 46 79 I TMCI 56 43 I TMRI 59 46 I PW1 PW2 PW3 77 78 79 63 64 65 O I/O O O I O Name and Function FRT Output Compare A (channels 1, 2, and 3): Output pins for the output compare A function of free-running timer channels 1, 2, and 3. FRT Output Compare B (channels 1, 2, and 3): Output pins for the output compare B function of free-running timer channels 1, 2, and 3. FRT Counter Clock Input (channels 1, 2, and 3): External clock input pins for the free-running counters (FRCs) of free-running timer channels 1, 2, and 3. FRT Input Capture (channels 1, 2, and 3): Input capture pins for free-running timer channels 1, 2, and 3. 8-bit Timer Output: Compare-match output pin for the 8-bit timer. 8-bit Timer Clock Input: External clock input pin for the 8-bit timer counter. 8-bit Timer Counter Reset Input: A high input at this pin resets the 8-bit timer counter. PWM Timer Output (channels 1, 2, and 3): Pulse-width modulation timer output pulses. 20 Table 1-4 Pin Functions (cont) Type Serial communication interface signals A/D converter Parallel I/O Symbol TXD1 TXD2 RXD1 RXD2 SCK1 SCK2 AN7 – AN0 Pin No. CP-84, FP-80A, CG-84 TFP-80C 80 66 77 63 81 67 78 64 82 68 79 65 73 – 66 59 – 52 I/O Name and Function O Transmit Data: Data output pins for serial communication interfaces 1 and 2. I Receive Data: Data input pins for serial communication interfaces 1 and 2. I/O Serial Clock: Input/output pins for the serial clock of serial interface 1 and 2. I Analog Input: Analog signal input pins. AVCC 74 60 I AVSS 65 51 I ADTRG 9 78 I P17 – P10 10 – 3 79 – 72 I/O P24 – P20 15 – 11 4 – 1, 80 I/O P37 – P30 32 – 25 20 – 13 I/O P47 – P40 40 – 33 28 – 21 I/O 21 Analog Reference Voltage: Reference voltage and power supply pin for the A/D converter. Analog Ground: Ground pin for the A/D converter. External Trigger: External trigger input pin for the A/D converter. Port 1: An 8-bit input/output port. The direction of each bit is determined by the port 1 data direction register (P1DDR). Port 2: A 5-bit input/output port. The direction of each bit is determined by the port 2 data direction register (P2DDR). Port 3: An 8-bit input/output port. The direction of each bit is determined by the port 3 data direction register (P3DDR). Port 4: An 8-bit input/output port. The direction of each bit is determined by the port 4 data direction register (P4DDR). These pins can drive LED indicators. Table 1-4 Pin Functions (cont) Type Parallel I/O Symbol P57 – P50 P63 – P60 P77 – P70 P87 – P80 P97 – P90 Pin No. CP-84, FP-80A, CG-84 TFP-80C I/O Name and Function 50 – 43 37 – 30 I/O Port 5: An 8-bit input/output port. The direction of each bit is determined by the port 5 data direction register (P5DDR). These pins have built-in MOS input pull-ups. 54 – 51 41 – 38 I/O Port 6: A 4-bit input/output port. The direction of each bit is determined by the port 6 data direction register (P6DDR). These pins have built-in MOS input pull-ups. 63 – 56 50 – 43 I/O Port 7: An 8-bit input/output port. The direction of each bit is determined by the port 7 data direction register (P7DDR). These pins have Schmitt inputs. 73 – 66 59 – 52 I Port 8: An 8-bit input port 82 – 75 68 – 61 I/O Port 9: An 8-bit input/output port. The direction of each bit is determined by the port 9 data direction register (P9DDR). 22 Section 2 MCU Operating Modes and Address Space 2.1 Overview The H8/534 or H8/536 microcomputer unit (MCU) operates in five modes numbered 1, 2, 3, 4, and 7. The mode is selected by the inputs at the mode pins (MD2 to MD0) at the instant when the chip comes out of a reset. As indicated in table 2-1, the MCU mode determines the size of the address space, the usage of on-chip ROM, and the operating mode of the CPU. The MCU mode also affects the functions of I/O pins. Table 2-1 Operating Modes MD2 0 0 0 0 1 1 1 1 MD1 0 0 1 1 0 0 1 1 MD0 0 1 0 1 0 1 0 1 MCU Mode — Mode 1 Mode 2 Mode 3 Mode 4 — — Mode 7 Address Space — Expanded minimum Expanded minimum Expanded maximum Expanded maximum — — Single-chip only On-Chip ROM — Disabled Enabled Disabled Enabled — — Enabled CPU Mode — Minimum mode Minimum mode Maximum mode Maximum mode — — Minimum mode Notation: 0: Low level 1: High level —: Cannot be used Modes 1 to 4 are referred to as “expanded” because they permit access to off-chip memory and peripheral addresses. The expanded minimum modes (modes 1 and 2) support a maximum address space of 64 kbytes. The expanded maximum modes (modes 3 and 4) support a maximum address space of 1 Mbyte. Interrupt service is slightly slower in the expanded maximum modes than in the other modes because the CPU has to save its code page register. In single-chip mode all ports are available for general-purpose input and output, but off-chip addresses cannot be accessed. The H8/534 and H8/536 cannot be set to modes 0, 5, and 6. The mode pins should never be set to these values. The inputs at the mode pins must not be changed while the chip is operating. 23 2.2 Mode Descriptions The five MCU modes are described below. For further information on the I/O pin functions in each mode, see section 9, “I/O Ports.” Mode 1 (Expanded Minimum Mode): Mode 1 supports a maximum 64-kbyte address space which does not include any on-chip ROM. Ports 1 to 5 are used for bus lines and bus control signals as follows: Control signals: Ports 1* and 2 Data bus: Port 3 Address bus: Ports 4 and 5 * The functions of individual pins of port 1 are software-selectable. Mode 2 (Expanded Minimum Mode): Mode 2 supports a maximum 64-kbyte address space of which the first part is in on-chip ROM. Ports 1 to 5 are used for bus lines and bus control signals as follows: Control signals: Ports 1* and 2 Data bus: Port 3 Address bus: Ports 4 and 5* * The functions of individual pins in ports 1 and 5 are software-selectable. Note: In mode 2, port 5 is initially a general-purpose input port. Software must change it to output before using it for the address bus. See section 9.6, “Port 5” for details. The following instruction makes all pins of port 5 into output pins: MOV.B #H'FF, @H'FE88* * H'xx or H'xxxx express the hexadecimal number. Mode 3 (Expanded Maximum Mode): Mode 3 supports a maximum 1-Mbyte address space which does not include any on-chip ROM. Ports 1 to 6 are used for bus lines and bus control signals as follows: Control signals: Ports 1* and 2 Data bus: Port 3 Address bus: Ports 4, 5, and 6 * The functions of individual pins of port 1 are software-selectable. 24 Mode 4 (Expanded Maximum Mode): Mode 4 supports a maximum 1-Mbyte address space of which the first part is in on-chip ROM. Ports 1 to 6 are used for bus lines and bus control signals as follows: Control signals: Ports 1* and 2 Data bus: Port 3 Address bus: Ports 4, 5*, and 6* * The functions of individual pins in ports 1, 5, and 6 are software-selectable. Note: In mode 4, ports 5 and 6 are initially general-purpose input ports. Software must change them to output before using them for the address bus. See section 9.6, “Port 5” and 10.7, “Port 6” for details. The following instruction sets all pins of ports 5 and 6 to output: MOV.W #H'FFFF, @H'FE88 Mode 7 (Single-Chip Mode): In this mode all memory is on-chip. It is not possible to access off-chip addresses. The single-chip mode provides the maximum number of ports. All the pins associated with the address and data buses in the expanded modes are available as general-purpose input/output ports in the single-chip mode. 2.3 Address Space Map 2.3.1 Page Segmentation The address space is segmented into 64-kbyte pages. In the single-chip mode and expanded minimum modes there is just one page: page 0. In the expanded maximum modes there can be up to 16 pages. Figure 2-1 shows the address space of the H8/534 in each mode and indicates which parts are on- and off-chip. Figure 2-2 shows the address space of the H8/536. 25 2.3.2 Page 0 Address Allocations The high and low address areas in page 0 are reserved for registers and vector tables. Vector Tables: The low address area contains the exception vector table and DTC vector table. The CPU accesses the exception vector table to obtain the addresses of user-coded exceptionhandling routines. The DTC vector table contains pointers to tables of register information used by the on-chip chip data transfer controller. The size of these tables depends on the CPU operating mode. Details are given in section 4.1.3, “Exception Factors and Vector Table,” section 5.2.3, “Interrupt Vector Table,” and section 6.3.2, “DTC Vector Table.” In modes 2 and 4 the vector tables are located in on-chip ROM. In modes 1, 3, and 7 the vector tables are in external memory. Register Field: The highest 384 addresses in page 0 (addresses H'FE80 to H'FFFF) belong to control, status, and data registers used by the I/O ports and on-chip supporting modules. Program code cannot be located at these addresses. The CPU accesses addresses in this register field like other addresses in the address space. By reading and writing at these addresses the CPU controls the on-chip supporting modules and communicates via the I/O ports. A complete map of the register field is given in appendix B. On-Chip RAM: One of the control registers in the register field is a RAM control register (RAMCR) containing a RAM enable bit (RAME) that enables or disables the 2-kbyte on-chip RAM. When this bit is set to 1 (its default value), addresses H'F680 to H'FE7F are located onchip. When this bit is cleared to 0, these addresses are located in external memory and the on-chip RAM is not used. See section 16, “RAM” for further information. The RAME bit is bit 7 at address H'FF11. Coding Example: To enable on-chip RAM: BSET.B #7, @H'FF11 To disable on-chip RAM: BCLR.B #7, @H'FF11 Note: If on-chip RAM is disabled in the single-chip mode, access to addresses H'F680 to H'FE7F causes an address error. 26 2.4 Mode Control Register (MDCR) Another control register in the register field in page 0 is the mode control register (MDCR). The mode control register can be read by the CPU, but not written. Table 3-2 lists the attributes of this register. Table 2-2 Mode Control Register Name Mode control register Abbreviation MDCR Read/Write Read only Address H'FF12 The bit configuration of this register is shown below. Bit 7 6 5 4 3 2 1 0 — — — — — MDS2 MDS1 MDS0 Initial value 1 1 0 0 0 * * * Read/Write — — — — — R R R * Initialized according to MD2 to MD0. Bits 7 and 6—Reserved: These bits cannot be modified and are always read as 1. Bits 5 to 3—Reserved: These bits cannot be modified and are always read as 0. Bits 2 to 0—Mode Select 2 to 0 (MDS2 to MDS0): These bits indicate the values of the mode pins (MD2 to MD0) latched on the rising edge of the signal. MDS2 corresponds to MD2, MDS1 to MD1, and MDS0 to MD0. These bits can be read but not written. Coding Example: To test whether the MCU is operating in mode 1: CMP:G.B #H'C1, @H'FF12 The comparison is with H'C1 instead of H'01 because bits 7 and 6 are always read as 1. 27 H'0000 H'00FF H'0100 H'F67F H'F680 H'FE7F H'FE80 H'FFFF Page 0 H'0000 H'00FF H'0100 H'7FFF H'8000 H'F67F H'F680 H'FE7F H'FE80 Register field 384 bytes On-chip RAM 2 kbytes External memory On-chip ROM 32 kbytes Vector tables Expanded Minimum Mode Mode 1 Mode 2 Vector tables External memory On-chip RAM 2 kbytes Register field 384 bytes H'FFFF Page 0 H'00000 H'001FF H'00200 H'0F67F H'0F680 H'0FE7F H'0FE80 H'0FFFF H'10000 H'1FFFF H'F0000 H'FFFFF Page 1 Page 0 H'00000 H'001FF H'00200 H'07FFF H'08000 H'0F67F H'0F680 H'0FE7F H'0FE80 H'0FFFF H'10000 H'1FFFF H'F0000 External memory Register field 384 bytes On-chip RAM 2 kbytes External memory On-chip ROM 32 kbytes Vector tables Expanded Maximum Mode Mode 3 Mode 4 Vector tables External memory On-chip RAM 2 kbytes Register field 384 bytes External memory Page 15 H'FFFFF Page 0 Page 1 Page 15 Figure 2-1 H8/534 Memory Map in Each Operating Mode Register field 384 bytes On-chip RAM 2 kbytes On-chip ROM 32 kbytes Vector tables Single-Chip Mode Mode 7 H'0000 H'00FF H'0100 H'7FFF H'F680 H'FE7F H'FE80 H'FFFF Page 0 H'0000 H'00FF H'0100 H'F67F H'F680 H'FE7F H'FE80 H'FFFF H'0000 H'00FF H'0100 H'EE7F Page 0 H'EE80 H'F67F H'F680 H'FE7F H'FE80 Register field 384 bytes On-chip RAM 2 kbytes External memory On-chip ROM 60 kbytes Vector tables Expanded Minimum Mode Mode 1 Mode 2 Vector tables External memory On-chip RAM 2 kbytes Register field 384 bytes H'FFFF Page 0 H'00000 H'001FF H'00200 H'0F67F H'0F680 H'0FE7F H'0FE80 H'0FFFF H'10000 H'1FFFF H'F0000 H'FFFFF Page 1 Page 0 H'00000 H'001FF H'00200 H'0F67F H'0F680 H'0FE7F H'0FE80 H'0FFFF H'10000 H'1FFFF H'F0000 External memory Register field 384 bytes On-chip RAM 2 kbytes On-chip ROM 62 kbytes Vector tables Expanded Maximum Mode Mode 3 Mode 4 Vector tables External memory On-chip RAM 2 kbytes Register field 384 bytes External memory Page 15 H'FFFFF Page 0 Page 1 Page 15 Figure 2-2 H8/536 Memory Map in Each Operating Mode Register field 384 bytes On-chip RAM 2 kbytes On-chip ROM 62 kbytes Vector tables Single-Chip Mode Mode 7 H'0000 H'00FF H'0100 H'F67F H'F680 H'FE7F H'FE80 H'FFFF Page 0 Section 3 CPU 3.1 Overview The H8/534 and H8/536 have the H8/500 Family CPU: a high-speed central processing unit designed for realtime control of a wide range of medium-scale office and industrial equipment. Its Hitachi-original architecture features eight 16-bit general registers, internal 16-bit data paths, and an optimized instruction set. Section 3 summarizes the CPU architecture and instruction set. 3.1.1 Features The main features of the H8/500 CPU are listed below. • General-register machine — Eight 16-bit general registers — Seven control registers (two 16-bit registers, five 8-bit registers) • High speed: maximum 16 MHz (S-mask versions) At 16 MHz a register-register add operation takes only 125 ns. • Address space managed in 64-kbyte pages, expandable to 1 Mbyte* Page registers make four pages available simultaneously: a code page, stack page, data page, and extended page. • Two CPU operating modes: — Minimum mode: Maximum 64-kbyte address space — Maximum mode: Maximum 1 Mbyte address space* • Highly orthogonal instruction set Addressing modes and data sizes can be specified independently within each instruction. • 1.5 Addressing modes Register-register and register-memory operations are supported. • Optimized for efficient programming in C language In addition to the general registers and orthogonal instruction set, the CPU has special short formats for frequently-used instructions and addressing modes. * The CPU architecture supports up to 16 Mbytes of external memory, but the H8/534 and H8/536 have only enough address pins to address 1 Mbyte. 31 3.1.2 Address Space The address space size depends on the operating mode. The H8/534 or H8/536 MCU has five operating modes, which are selected by the input to the mode pins (MD2 to MD0) when the chip comes out of a reset. The CPU, however, has only two operating modes. The MCU operating mode determines the CPU operating mode, which in turn determines the maximum address space size as indicated in figure 3-1. Minimum mode Maximum address space: 64 kbytes Hightest address: H'FFFF Maximum mode Maximum address space: 1 Mbyte Hightest address: H'FFFFF CPU operating mode Figure 3-1 CPU Operating Modes 32 3.1.3 Register Configuration Figure 3-2 shows the register structure of the CPU. There are two groups of registers: the general registers (Rn) and control registers (CR). General registers (Rn) 15 0 R0 R1 R2 R3 R4 R5 R6 R7 (FP) (SP) FP: Frame Pointer SP: Stack Pointer Control registers (CR) 15 0 PC PC: Program Counter SR CCR 15 T 8 7 I2 I1 I0 0 N Z V C SR: Status Register CCR: Condition Code Register CP CP: Code Page register DP DP: Data Page register EP EP: Extended Page register TP TP: sTack Page register BR BR: Base Register Figure 3-2 Registers in the CPU 33 3.2 CPU Register Descriptions 3.2.1 General Registers All eight of the 16-bit general registers are functionally alike; there is no distinction between data registers and address registers. When these registers are accessed as data registers, either byte or word size can be selected. R6 and R7, in addition to functioning as general registers, have special assignments. R7 is the stack pointer, used implicitly in exception handling and subroutine calls. It can be designated by the name SP, which is synonymous with R7. As indicated in figure 3-3, it points to the top of the stack. It is also used implicitly by the LDM and STM instructions, which load and store multiple registers from and to the stack and pre-decrement or post-increment R7 accordingly. R6 functions as a frame pointer (FP). The LINK and UNLK instructions use R6 implicitly to reserve or release a stack frame. Unused area SP Stack area Figure 3-3 Stack Pointer Fig. 3-3 34 3.2.2 Control Registers The CPU control registers (CR) include a 16-bit program counter (PC), a 16-bit status register (SR), four 8-bit page registers, and one 8-bit base register (BR). Program Counter (PC): This 16-bit register indicates the address of the next instruction the CPU will execute. Status Register (SR): This 16-bit register contains internal status information. The lower half of the status register is referred to as the condition code register (CCR): it can be accessed as a separate condition code byte. CCR Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 T — — — — I2 I1 I0 — — — — N Z V C Bit 15—Trace (T): When this bit is set to 1, the CPU operates in trace mode and generates a trace exception after every instruction. See section 4.4, “Trace” for a description of the trace exception-handling sequence. When the value of this bit is 0, instructions are executed in normal continuous sequence. This bit is cleared to 0 at a reset. Bits 14 to 11—Reserved: These bits cannot be modified and are always read as 0. Bits 10 to 8—Interrupt Mask (I2, I1, I0): These bits indicate the interrupt request mask level (0 to 7). As shown in table 3-1, an interrupt request is not accepted unless it has a higher level than the value of the mask. A nonmaskable interrupt (NMI), which has level 8, is accepted at any mask level. After an interrupt is accepted, I2, I1, and I0 are changed to the level of the interrupt. Table 3-2 indicates the values of the I bits after an interrupt is accepted. A reset sets all three bits (I2, I1, and I0) to 1, masking all interrupts except NMI. 35 Table 3-1 Interrupt Mask Levels Priority High Low Mask Level 7 6 5 4 3 2 1 0 Mask Bits I2 I1 I0 1 1 1 1 1 0 1 0 1 1 0 0 0 1 1 0 1 0 0 0 1 0 0 0 Interrupts Accepted NMI Level 7 and NMI Levels 6 to 7 and NMI Levels 5 to 7 and NMI Levels 4 to 7 and NMI Levels 3 to 7 and NMI Levels 2 to 7 and NMI Levels 1 to 7 and NMI Table 3-2 Interrupt Mask Bits after an Interrupt is Accepted Level of Interrupt Accepted NMI (8) 7 6 5 4 3 2 1 I2 1 1 1 1 1 0 0 0 I1 1 1 1 0 0 1 1 0 36 I0 1 1 0 1 0 1 0 1 Bits 7 to 4—Reserved: These bits cannot be modified and are always read as 0. Bit 3—Negative (N): This bit indicates the most significant bit (sign bit) of the result of an instruction. Bit 2—Zero (Z): This bit is set to 1 to indicate a zero result and cleared to 0 to indicate a nonzero result. Bit 1—Overflow (V): This bit is set to 1 when an arithmetic overflow occurs, and cleared to 0 at other times. Bit 0—Carry (C): This bit is set to 1 when a carry or borrow occurs at the most significant bit, and is cleared to 0 (or left unchanged) at other times. The specific changes that occur in the condition code bits when each instruction is executed are listed in appendix A.1 “Instruction Tables.” See the H8/500 Series Programming Manual for further details. Page Registers: The code page register (CP), data page register (DP), extended page register (EP), and stack page register (TP) are 8-bit registers that are used only in the maximum mode. No use of their contents is made in the minimum mode. In the maximum mode, the page registers combine with the program counter and general registers to generate 24-bit effective addresses as shown in figure 3-4, thereby expanding the program area, data area, and stack area. 37 Page register PC or general register 8 Bits 16 Bits PC CP R0 R1 R2 DP R3 @ aa : 16 R4 EP R5 R6 TP R7 24 Bits (effective address) Figure 3-4 Combinations of Page Registers with Other Registers Code Page Register (CP): The code page register and the program counter combine to generate a 24-bit program code address. In the maximum mode, the code page register is initialized at a reset to a value loaded from the vector table, and both the code page register and program counter 38 are saved and restored in exception handling. Data Page Register (DP): The data page register combines with general registers R0 to R3 to generate a 24-bit effective address. The data page register contains the upper 8 bits of the address. It is used to calculate effective addresses in the register indirect addressing mode using R0 to R3, and in the 16-bit absolute addressing mode (@aa:16). The data page register is rewritten by the LDC instruction. Extended Page Register (EP): The extended page register combines with general register R4 or R5 to generate a 24-bit operand address. The extended page register contains the upper 8 bits of the address. It is used to calculate effective addresses in the register indirect addressing mode using R4 or R5. The extended page can be used as an additional data page. Stack Page Register (TP): The stack page register combines with R6 (FP) or R7 (SP) to generate a 24-bit stack address. The stack page register contains the upper 8 bits of the address. It is used to calculate effective addresses in the register indirect addressing mode using R6 or R7, in exception handling, and subroutine calls. Base Register (BR): This 8-bit register stores the base address used in the short absolute addressing mode (@aa:8). In this addressing mode a 16-bit effective address in page 0 is generated by using the contents of the base register as the upper 8 bits and an address given in the instruction code as the lower 8 bits. See figure 3-5. In the short absolute addressing mode the address is always located in page 0. 8 Bits 8 Bits BR @ aa : 8 16 Bits (effective address) Figure 3-5 Short Absolute Addressing Mode and Base Register 39 3.2.3 Initial Register Values When the CPU is reset, its internal registers are initialized as shown in table 3-3. Note that the stack pointer (R7) and base register (BR) are not initialized to fixed values. Also, of the page registers used in maximum mode, only the code page register (CP) is initialized; the other three page registers come out of the reset state with undetermined values. Accordingly, in the minimum mode the first instruction executed after a reset should initialize the stack pointer. The base register must also be initialized before the short absolute addressing mode (@aa:8) is used. In the maximum mode, the first instruction executed after a reset should initialize the stack page register (TP) and the next instruction should initialize the stack pointer. Later instructions should initialize the base register and the other page registers as necessary. 40 Table 3-3 Initial Values of Registers Register General registers 15 R7 – R0 Minimum Mode Control registers 15 Initial Value Maximum Mode 0 Undetermined Undetermined 0 Loaded from vector table Loaded from vector table H'070x (x: undetermined) H'070x (x: undetermined) Undetermined Loaded from vector table Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined PC SR CCR 15 87 0 T– – – – I2I1I0 – – – – NZVC 7 0 CP 7 0 DP 7 0 EP 7 0 TP 7 0 BR 3.3 Data Formats The H8/500 CPU can process 1-bit data, 4-bit BCD data, 8-bit (byte) data, 16-bit (word) data, and 32-bit (longword) data. • Bit manipulation instructions operate on 1-bit data. • Decimal arithmetic instructions operate on 4-bit BCD data. • Almost all instructions operate on byte and word data. • Multiply and divide instructions operate on longword data. 3.3.1 Data Formats in General Registers Data of all the sizes above can be stored in general registers as shown in table 3-4. 41 Bit data locations are specified by bit number. Bit 15 is the most significant bit. Bit 0 is the least significant bit. BCD and byte data are stored in the lower 8 bits of a general register. Word data use all 16 bits of a general register. Longword data use two general registers: the upper 16 bits are stored in Rn (n must be an even number); the lower 16 bits are stored in Rn+1. Operations performed on BCD data or byte data do not affect the upper 8 bits of the register. Table 3-4 General Register Data Formats Data Type Register No. 1-Bit Data Structure 15 Rn 15 0 14 13 12 11 10 9 8 7 8 7 6 5 4 3 4 3 2 1 0 BCD 15 Rn Don’t-care Upper digit 0 Lower digit Byte 15 Rn 8 Don’t-care 7 MSB 0 LSB Word 15 Rn Longword 0 MSB LSB 31 Rn* Rn+1* 16 MSB Upper 16 bits Lower 16 bits LSB 15 0 * For longword data n must be even (0, 2, 4, or 6). 3.3.2 Data Formats in Memory Table 3-5 indicates the data formats in memory. Instructions that access bit data in memory have byte or word operands. The instruction specifies a bit number to indicate a specific bit in the operand. Access to word data in memory must always begin at an even address. Access to word data starting at an odd address causes an address error. The upper 8 bits of word data are stored in address n (where n is an even number); the lower 8 bits are stored in address n+1. 42 Table 3-5 Data Formats in Memory Data Type 1-Bit (in byte operand data) Data Format 7 Address n 0 7 6 5 4 3 2 1 0 Even address 15 14 13 12 11 10 9 8 Odd address 7 6 5 4 3 2 1 0 Address n MSB Even address MSB 1-Bit (in word operand data) Byte LSB Word Odd address Upper 8 bits Lower 8 bits LSB When the stack is accessed in exception processing (to save or restore the program counter, code page register, or status register), word access is always performed, regardless of the actual data size. Similarly, when the stack is accessed by an instruction using the pre-decrement or postincrement register indirect addressing mode specifying R7 (@–R7 or @R7+), which is the stack pointer, word access is performed regardless of the operand size specified in the instruction. An address error will therefore occur if the stack pointer indicates an odd address. Programs should be coded so that the stack pointer always indicates an even address. Table 3-6 shows the data formats on the stack. 43 Table 3-6 Data Formats on the Stack Data Type Byte data on stack Data Format Even address Don’t-care Odd address MSB Even address MSB LSB Word data on stack Odd address Upper 8 bits Lower 8 bits LSB 3.4 Instructions 3.4.1 Basic Instruction Formats There are two basic CPU instruction formats: the general format and the special format. General Format: This format consists of an effective address (EA) field, an effective address extension field, and an operation code (OP) field. The effective address is placed before the operation code because this results in faster execution of the instruction. Effective address field • Effective address field: Effective address extension Operation code One byte containing information used to calculate the effective address of an operand. • Effective address extension: Zero to two bytes containing a displacement value, immediate data, or an absolute address. The size of the effective address extension is specified in the effective address field. • Operation code: Defines the operation to be carried out on the operand located at the address calculated from the effective address information. Some instructions (DADD, DSUB, MOVFPE, MOVTPE) have an extended format in which the operand code is preceded by a one-byte prefix code. 44 • (Example of prefix code in DADD instruction) Effective address Prefix code Operation code 10100rrr 00000000 10100rrr Special Format: In this format the operation code comes first, followed by the effective address field and effective address extension. This format is used in branching instructions, system control instructions, and other instructions that can be executed faster if the operation is specified before the operand. Operation code Effective address field Effective address extension • Operation code: One or two bytes defining the operation to be performed by the instruction. • Effective address field and effective address extension: Zero to three bytes containing information used to calculate an effective address. 3.4.2 Addressing Modes The CPU supports 7 addressing modes: (1) register direct; (2) register indirect; (3) register indirect with displacement; (4) register indirect with pre-decrement or post-increment; (5) immediate; (6) absolute; and (7) PC-relative. Due to the highly orthogonal nature of the instruction set, most instructions having operands can use any applicable addressing mode from (1) through (6). The PC-relative mode (7) is used by branching instructions. In most instructions, the addressing mode is specified in the effective address field. The effectiveaddress extension, if present, contains a displacement, immediate data, or an absolute address. Table 3-7 indicates how the addressing mode is specified in the effective address field. 45 Table 3-7 Addressing Modes No. Addressing Mode Mnemonic EA Field 1 Register direct Rn 1 0 1 0 Sz r r r *1 EA Extension None *2 2 Register indirect @Rn 1 1 0 1 Sz r r r None 3 Register indirect with displacement @(d:8,Rn) 1 1 1 0 Sz r r r Displacement (1 byte) @(d:16,Rn) 1 1 1 1 Sz r r r Displacement (2 bytes) Register indirect with pre-decrement Register indirect with post-increment @–Rn 1 0 1 1 Sz r r r @Rn+ 1 1 0 0 Sz r r r Immediate #xx:8 00000100 Immediate data (1 byte) #xx:16 00001100 Immediate data (2 bytes) @aa:8 0 0 0 0 Sz 1 0 1 @aa:16 0 0 0 1 Sz 1 0 1 1-Byte absolute address (offset from BR) 2-Byte absolute address disp No EA field. Addressing mode is specified in the operation code. 4 5 6 7 Absolute *3 PC-relative None 1- or 2-byte displacement Notes: * 1 Sz: Specifies the operand size. When Sz = 0: byte operand When Sz = 1: word operand * 2 rrr: Register number field, specifying a general register number. 0 0 0 — R0 0 0 1 — R1 0 1 0 — R2 0 1 1 — R3 1 0 0 — R4 1 0 1 — R5 1 1 0 — R6 1 1 1 — R7 * 3 The @aa:8 addressing mode is also referred to as the short absolute addressing mode. 46 3.4.3 Effective Address Calculation Table 3-8 explains how the effective address is calculated in each addressing mode. Table 3-8 Effective Address Calculation No. 1 Addressing Mode Effective Address Calculation Effective Address Register direct — Operand is contents of Rn Rn 1010Sz rrr 2 Register indirect @Rn 1101Sz rrr — 23 15 DP *1 0 Rn Or TP or EP *2 3 Register indirect with displacement @(d:8,Rn) 1110Sz rrr @(d:16,Rn) 1111Sz rrr 8 Bits 15 0 23 15 0 Displacement with sign extension 16 Bits 15 + 0 23 Register indirect 15 with pre-decrement @–Rn 1011Sz 0 Result Or TP or EP *2 0 + 0 23 15 DP *1 Rn 1 or 2 rrr 15 DP *1 Displacement 4 0 Result Or TP or EP *2 Rn 15 15 DP *1 Rn – 0 Result Or TP or EP *2 Rn is decremented by –1 or –2 before instruction execution.*3*4*5 Register indirect — with post-increment @Rn+ Rn is incremented by +1 or +2 1100Sz rrr after instruction execution.*3*4*5 47 23 15 DP *1 Or TP or EP *2 0 Rn Table 3-8 Effective Address Calculation (cont) No. 5 6 7 Addressing Mode Effective Address Calculation Absolute address — @aa:8 0000Sz101 Effective Address 23 15 0 H'00 BR EA extension data @aa:16 0001Sz101 — 23 Immediate #xx:8 00000100 — Operand is 1-byte EA extension data. #xx:16 00001100 — Operand is 2-byte EA extension data. DP PC-relative 8 Bits disp:8 15 0 No EA code PC Specified in OP code 15 0 Displacement with sign extension disp:16 16 Bits No EA code 15 Specified in OP code PC 15 23 15 CP *1 0 Displacement 48 0 Result ⊕ 23 0 15 0 EA extension data 15 CP ⊕ *1 0 Result Notes: * 1 The page register is ignored in minimum mode. * 2 The page register used in addressing modes 2, 3, and 4 depends on the general register : DP for R0, R1, R2, or R3; EP for R4 or R5; TP for R6 or R7. * 3 Decrement by –1 for a byte operand, and by –2 for a word operand. * 4 The pre-decrement or post-increment is always ±2 when R7 is specified, even if the operand is byte size. * 5 The drawing below shows what happens when the @-SP and @ SP+ addressing modes are used to save and restore the stack pointer. SP Old SP–2 (upper byte) SP Old SP–2 (lower byte) SP MOV.W SP, @–SP MOV.W @SP+, SP 49 3.5 Instruction Set 3.5.1 Overview The main features of the CPU instruction set are: • A general-register architecture. • Orthogonality. Addressing modes and data sizes can be specified independently in each instruction. • 1.5 addressing modes (supporting register-register and register-memory operations) • Affinity for high-level languages, particularly C, with short formats for frequently-used instructions and addressing modes. The CPU instruction set includes 63 types of instructions, listed by function in table 3-9. Table 3-9 Instruction Classification Function Data transfer Arithmetic operations Logic operations Shift Bit manipulation Branch System control Instructions MOV, LDM, STM, XCH, SWAP, MOVTPE, MOVFPE ADD, SUB, ADDS, SUBS, ADDX, SUBX, DADD, DSUB, MULXU, DIVXU, CMP, EXTS, EXTU, TST, NEG, CLR, TAS AND, OR, XOR, NOT SHAL, SHAR, SHLL, SHLR, ROTL, ROTR, ROTXL, ROTXR BSET, BCLR, BTST, BNOT Bcc*, JMP, PJMP, BSR, JSR, PJSR, RTS, PRTD, PRTS, RTD, SCB (/F, /NE, /EQ) TRAPA, TRAP/VS, RTE, SLEEP, LDC, STC, ANDC, ORC, XORC, NOP, LINK, UNLK Total Types 7 17 4 8 4 11 12 63 * Bcc is a conditional branch instruction in which cc represents a condition code. Tables 3-10 to 3-16 give a concise summary of the instructions in each functional category. The MOV, ADD, and CMP instructions have special short formats, which are listed in table 3-17. For detailed descriptions of the instructions, refer to the H8/500 Series Programming Manual. The notation used in tables 3-10 to 3-17 is defined below. 50 Operation Notation Rd General register (destination) Rs General register (source) Rn General register (EAd) Destination operand (EAs) Source operand CCR Condition code register N N (negative) bit of CCR Z Z (zero) bit of CCR V V (overflow) bit of CCR C C (carry) bit of CCR CR Control register PC Program counter CP Code page register SP Stack pointer FP Frame pointer #IMM Immediate data disp Displacement + Addition – Subtraction × Multiplication ÷ Division ∧ AND logical ∨ OR logical ⊕ Exclusive OR logical → Move ↔ Exchange ¬ Not 51 3.5.2 Data Transfer Instructions Table 3-10 describes the seven data transfer instructions. Table 3-10 Data Transfer Instructions Instruction Data MOV transfer MOV:G MOV:E MOV:I MOV:F MOV:L MOV:S LDM Size* B/W B W B/W B/W B/W W STM W XCH W SWAP B MOVTPE B MOVFPE B Function (EAs) → (EAd), #IMM → (EAd) Moves data between two general registers, or between a general register and memory, or moves immediate data to a general register or memory. Stack → Rn (register list) Pops data from the stack to one or more registers. Rn (register list) → stack Pushes data from one or more registers onto the stack. Rs ↔ Rd Exchanges data between two general registers. Rd (upper byte) ↔ Rd (lower byte) Exchanges the upper and lower bytes in a general register. Rn → (EAd) Transfers data from a general register to memory in synchronization with the E clock. (EAs) → Rd Transfers data from memory to a general register in synchronization with the E clock. Note: B—byte; W—word 52 3.5.3 Arithmetic Instructions Table 3-11 describes the 17 arithmetic instructions. Table 3-11 Arithmetic Instructions Instruction Arithmetic ADD operations ADD:G ADD:Q SUB ADDS SUBS ADDX SUBX Size B/W B/W B/W B/W B/W B/W B/W DADD DSUB B B MULXU B/W DIVXU B/W CMP CMP:G CMP:E CMP:I Note: B—byte; W—word B/W B W Function Rd ± (EAs) → Rd, (EAd) ± #IMM → (EAd) Performs addition or subtraction on data in a general register and data in another general register or memory, or on immediate data and data in a general register or memory. Rd ± (EAs) ± C → Rd Performs addition or subtraction with carry or borrow on data in a general register and data in another general register or memory, or on immediate data and data in a general register or memory. (Rd)10 ± (Rs)10 ± C → (Rd)10 Performs decimal addition or subtraction on data in two general registers. Rd × (EAs) → Rd Performs 8-bit × 8-bit or 16-bit × 16-bit unsigned multiplication on data in a general register and data in another general register or memory, or on data in a general register and immediate data. Rd ÷ (EAs) → Rd Performs 16-bit ÷ 8-bit or 32-bit ÷ 16-bit unsigned division on data in a general register and data in another general register or memory, or on data in a general register and immediate data. Rn – (EAs), (EAd) – #IMM Compares data in a general register with data in another general register or memory, or with immediate data, or compares immediate data with data in memory. 53 Table 3-11 Arithmetic Instructions (cont) Instruction Arithmetic operations EXTS Size B EXTU B TST B/W NEG B/W CLR B/W TAS B Function (<bit 7> of <Rd>) → (<bits 15 to 8> of <Rd>) Converts byte data in a general register to word data by extending the sign bit. 0 → (<bits 15 to 8> of <Rd>) Converts byte data in a general register to word data by padding with zero bits. (EAd) – 0 Compares general register or memory contents with 0. 0 – (EAd) → (EAd) Obtains the two’s complement of general register or memory contents. 0 → (EAd) Clears general register or memory contents to 0. (EAd) — 0, (1)2 → (<bit 7> of <EAd>) Tests general register or memory contents, then sets the most significant bit (bit 7) to 1. Note: B—byte; W—word 3.5.4 Logic Operations Table 3-12 lists the four instructions that perform logic operations. Table 3-12 Logic Operation Instructions Instruction Logical operations AND Size B/W OR B/W XOR B/W NOT B/W Function Rd∧(EAs) → Rd Performs a logical AND operation on a general register and another general register, memory, or immediate data. Rd∨(EAs) → Rd Performs a logical OR operation on a general register and another general register, memory, or immediate data. Rd⊕(EAs) → Rd Performs a logical exclusive OR operation on a general register and another general register, memory, or immediate data. ¬ (EAd) → (EAd) Obtains the one’s complement of general register or memory contents. Note: B—byte; W—word 54 3.5.5 Shift Operations Table 3-13 lists the eight shift instructions. Table 3-13 Shift Instructions Instruction Shift SHAL operations SHAR Size B/W B/W SHLL SHLR B/W B/W ROTL ROTR ROTXL ROTXR B/W B/W B/W B/W Function (EAd) shift → (EAd) Performs an arithmetic shift operation on general register or memory contents. (EAd) shift → (EAd) Performs a logical shift operation on general register or memory contents. (EAd) shift → (EAd) Rotates general register or memory contents. (EAd) rotate through carry → (EAd) Rotates general register or memory contents through the C (carry) bit. Note: B—byte; W—word 55 3.5.6 Bit Manipulations Table 3-14 describes the four bit-manipulation instructions. Table 3-14 Bit-Manipulation Instructions Instruction Bit BSET manipulations Size B/W BCLR B/W BNOT B/W BTST B/W Function ¬ (<bit-No.> of <EAd>) → Z, 1 → (<bit-No.> of <EAd>) Tests a specified bit in a general register or memory, then sets the bit to 1. The bit is specified by a bit number given in immediate data or a general register. ¬ (<bit-No.> of <EAd>) → Z, 0 → (<bit-No.> of <EAd>) Tests a specified bit in a general register or memory, then clears the bit to 0. The bit is specified by a bit number given in immediate data or a general register. ¬ (<bit-No.> of <EAd>) → Z, → (<bit-No.> of <EAd>) Tests a specified bit in a general register or memory, then inverts the bit. The bit is specified by a bit number given in immediate data or a general register. ¬ (<bit-No.> of <EAd>) → Z Tests a specified bit in a general register or memory. The bit is specified by a bit number given in immediate data or a general register. Note: B—byte; W—word 56 3.5.7 Branching Instructions Table 3-15 describes the 11 branching instructions. Table 3-15 Branching Instructions Instruction Branch Bcc Size — Function Branches if condition cc is true. Mnemonic BRA (BT) BRN (BF) BHI BLS BCC (BHS) Description Always (true) Never (false) HIgh Low or Same Carry Clear (High or Same) Carry Set (Low) Not Equal Equal Overflow Clear Overflow Set Plus Minus Greater or Equal Less Than Greater Than Less or Equal BCS (BLO) BNE BEQ BVC BVS BPL BMI BGE BLT BGT BLE JMP PJMP BSR JSR PJSR RTS — — — — — — Condition True False C∨Z=0 C∨Z=1 C=0 C=1 Z=0 Z=1 V=0 V=1 N=0 N=1 N⊕V=0 N⊕V=1 Z ∨ (N ⊕ V) = 0 Z ∨ (N ⊕ V) = 1 Branches unconditionally to a specified address in the same page. Branches unconditionally to a specified address in a specified page. Branches to a subroutine at a specified address in the same page. Branches to a subroutine at a specified address in the same page. Branches to a subroutine at a specified address in a specified page. Returns from a subroutine in the same page. 57 Table 3-15 Branching Instructions (cont) Instruction Branch PRTS RTD Size — — PRTD — SCB/F SCB/NE SCB/EQ — — — Function Returns from a subroutine in a different page. Returns from a subroutine in the same page and adjusts the stack pointer. Returns from a subroutine in a different page and adjusts the stack pointer. Controls a loop using a loop counter and/or a specified termination condition. 58 3.5.8 System Control Instructions Table 3-16 describes the 12 system control instructions. Table 3-16 System Control Instructions Instruction System TRAPA control TRAP/VS Size — — RTE LINK — — UNLK — SLEEP LDC — B/W* STC B/W* ANDC B/W* ORC B/W* XORC B/W* NOP — Function Generates a trap exception with a specified vector number. Generates a trap exception if the V bit is set to 1 when the instruction is executed. Returns from an exception-handling routine. FP → @–SP; SP → FP; SP + #IMM → SP Creates a stack frame. FP → SP; @SP+ → FP Deallocates a stack frame created by the LINK instruction. Causes a transition to the power-down state. (EAs) → CR Moves immediate data or general register or memory contents to a specified control register. CR → (EAd) Moves control register data to a specified general register or memory location. CR ∧ #IMM → CR Logically ANDs a control register with immediate data. CR ∨ #IMM → CR Logically ORs a control register with immediate data. CR ⊕ #IMM → CR Logically exclusive-ORs a control register with immediate data. PC + 1 → PC No operation. Only increments the program counter. * The size depends on the control register. Note on Stack Operation by LDC and STC Instructions of H8/500 CPU When using the LDC and STC instructions to stack and unstack the BR, CCR, TP, DP, and EP control registers in the H8/500 family, note the following point. H8/500 hardware does not permit byte access to the stack. If the LDC.B or STC.B assembler mnemonic is coded with the @R7 + (@SP+) or @–R7 (@–SP) addressing mode, the stackpointer addressing mode takes precedence and hardware automatically performs word access. 59 Specifically, the LDC.B and STC.B instructions are executed as follows. The following applies only to the stack-pointer addressing modes. In addressing modes that do not use the stack pointer, byte data access is performed as specified by the assembler mnemonic. (1) STC.B EP, @–SP When word data access is applied to EP, both EP and DP are accessed. This instruction stores EP at address SP (old) –2, and DP at address SP (old) –1. EP a Old SP – 2 Old SP – 1 DP b Old SP New SP a New SP + 1 b New SP + 2 After execution Before execution (2) LDC.B @SP+, EP When word data access is applied to EP, both EP and DP are accessed. This instruction loads EP from address SP (old), and DP from address SP (old) +1, updating the DP value as well as the EP value. Old SP a Old SP + 1 b Old SP + 2 EP a New SP – 2 New SP – 1 DP b DP b New SP After execution Before execution (3) EP a STC.B CCR, @–SP When word data access is applied to CCR, only CCR is accessed. This instruction stores identical CCR contents at both address SP (old) –2 and address SP (old) –1. CCR a New SP a Old SP – 1 New SP + 1 b Old SP New SP + 2 Old SP – 2 Before execution After execution 60 (4) LDC.B @SP+, CCR When word data access is applied to CCR, only CCR is accessed. This instruction loads CCR from address SP (old) +1. Note that the value in address SP (old) is not loaded. CCR Old SP a New SP – 2 Old SP + 1 b New SP – 1 Old SP + 2 CCR b New SP After execution Before execution BR, DP, and TP are accessed in the same way as CCR. When DP is specified, both EP and DP are accessed, but when CCR, BR, DP, or TP is specified, only the specified register is accessed. 61 3.5.9 Short-Format Instructions The ADD, CMP, and MOV instructions have special short formats. Table 3-17 lists these short formats together with the equivalent general formats. The short formats are a byte shorter than the corresponding general formats, and most of them execute one state faster. Table 3-17 Short-Format Instructions and Equivalent General Formats Short-Format Execution Equivalent GeneralExecution Instruction Length States *2 Format Instruction Length States *2 ADD:Q #xx,Rd *1 2 2 ADD:G #xx:8,Rd 3 3 CMP:E #xx:8,Rd 2 2 CMP:G.B #xx:8,Rd 3 3 CMP:I #xx:16,Rd 3 3 CMP:G.W #xx:16,Rd 4 4 MOV:E #xx:8,Rd 2 2 MOV:G.B #xx:8,Rd 3 3 MOV:I #xx:16,Rd 3 3 MOV:G.W #xx:16,Rd 4 4 MOV:L @aa:8,Rd 2 5 MOV:G @aa:8,Rd 3 5 MOV:S Rs,@aa:8 2 5 MOV:G Rs,@aa:8 3 5 MOV:F @(d:8,R6),Rd 2 5 MOV:G @(d:8,R6),Rd 3 5 MOV:F Rs,@(d:8,R6) 2 5 MOV:G Rs,@(d:8,R6) 3 5 Notes: * 1 The ADD:Q instruction accepts other destination operands in addition to a general register, but the immediate data value (#xx) is limited to ±1 or ±2. * 2 Number of execution states for access to on-chip memory. 3.6 Operating Modes The CPU operates in one of two modes: the minimum mode or the maximum mode. These modes are selected by the mode pins (MD2 to MD0 ). 3.6.1 Minimum Mode The minimum mode supports a maximum address space of 64 kbytes. The page registers are ignored. Instructions that branch across page boundaries (PJMP, PJSR, PRTS, PRTD) are invalid. 62 3.6.2 Maximum Mode In the maximum mode the page registers are valid, expanding the maximum address space to 1 Mbyte. The address space is divided into 64-kbyte pages. The pages are separate; it is not possible to move continuously across a page boundary. It is possible to move from one page to another with branching instructions (PJMP, PJSR, PRTS, PRTD). The TRAPA instruction and branches to interrupt-handling routines can also jump across page boundaries. It is not necessary for a program to be contained in a single 64-kbyte page. When data access crosses a page boundary, the program must rewrite the page register before it can access the data in the next page. For further information on the operating modes, see section 2, “MCU Operating Modes and Address Space.” 3.7 Basic Operational Timing 3.7.1 Overview The CPU operates on a system clock (ø) which is created by dividing an oscillator frequency (fosc) by two. One period of the system clock is referred to as a “state.” The CPU accesses memory in a cycle consisting of 2 or 3 states. The CPU uses different methods to access on-chip memory, the on-chip register field, and external devices. Access to On-Chip Memory (RAM, ROM): For maximum speed, access to on-chip memory (RAM, ROM) is performed in two states, using a 16-bit-wide data bus. Figure 3-6 shows the on-chip memory access cycle. Figure 3-7 indicates the pin states. The bus control output signals go to the nonactive state during the access. Access to On-Chip Register Field (Addresses H'FE80 to H'FFFF): The access cycle consists of three states. The data bus is 8 bits wide. Figure 3-8 shows the on-chip supporting module access cycle. Figure 3-9 indicates the pin states. 63 Access to External Devices: The access cycle consists of three states. The data bus is 8 bits wide. Figure 3-10 (a) and (b) shows the external access cycle. Additional wait states (Tw) can be inserted by the wait-state controller (WSC). 3.7.2 On-Chip Memory Access Cycle Memory cycle T1 state T2 state ø Internal address bus Address Internal Read signal Read data Internal data bus (Read access) Internal Write signal Internal data bus (Write access) Write data Figure 3-6 On-Chip Memory Access Timing 64 3.7.3 Pin States during On-Chip Memory Access T1 state T2 state ø A19 to A 0 R/W (read access) R/W (write access) “High” AS, DS, RD, WR High-impedance D 7 to D 0 Figure 3-7 Pin States during Access to On-Chip Memory 65 3.7.4 Register Field Access Cycle (Addresses H'FE80 to H'FFFF) Memory cycle T1 state T2 state ø Address Internal address bus Internal Read signal Internal data bus (read access) Read data Internal Write signal Internal data bus (write access) Write data Figure 3-8 Register Field Access Timing 66 T3 state 3.7.5 Pin States during Register Field Access (Addresses H'FE80 to H'FFFF) T1 state T2 state ø A 19 to A 0 R/W (read access) R/W (write access) “High” AS, DS, RD, WR High-impedance D 7 to D0 Figure 3-9 Pin States during Register Field Access 67 T3 state 3.7.6 External Access Cycle Read cycle T1 state T2 state T3 state ø A19 –A 0 Address AS R/W DS RD “High” WR D7 –D0 Read data Figure 3-10 (a) External Access Cycle (Read Access) 68 Write cycle T1 state T2 state T3 state ø A19 –A 0 Address AS R/W DS “High” RD WR D7 –D0 Write data Figure 3-10 (b) External Access Cycle (Write Access) 3.8 CPU States 3.8.1 Overview The CPU has five states: the program execution state, exception-handling state, bus-released state, reset state, and power-down state. The power-down state is further divided into the sleep mode, software standby mode, and hardware standby mode. Figure 3-11 summarizes these states, and figure 3-12 shows a map of the state transitions. 69 State Program execution state The CPU executes program instructions in sequence. Exception-handling state A transient state in which the CPU executes a hardware sequence (saving the program counter and status register, fetching a vector from the vector table, etc.) triggered by a reset, interrupt, or other exception. Bus-released state The state in which the CPU has released the external bus in response to a bus request signal from an external device, and is waiting for the bus to be returned. Reset state The state in which the CPU and all on-chip supporting modules have been initialized and are stopped. Power-down state A state in which some or all of the clock signals are stopped to conserve power. Sleep mode Software standby mode Hardware standby mode Figure 3-11 Operating States 70 BREQ = 1 BREQ = 0 Program execution state BREQ = 1 Bus-released state BREQ = 0 End of exception handling Request for exception handling SLEEP SLEEP instruction instruction with standby flag set Sleep mode Interrupt request NMI Software standby mode RES = 1 Exception-handling state Reset state * 1 STBY = 1, RES = 0 Hardware standby mode * 2 * 1 From any state except the hardware standby mode, a transition to the reset state occurs whenever RES goes Low. * 2 A transition to the hardware standby mode from any state occurs when STBY goes Low. Figure 3-12 State Transitions 3.8.2 Program Execution State In this state the CPU executes program instructions in normal sequence. 3.8.3 Exception-Handling State The exception-handling state is a transient state that occurs when the CPU alters the normal program flow due to an interrupt, trap instruction, address error, or other exception. In this state the CPU carries out a hardware-controlled sequence that prepares it to execute a user-coded exception-handling routine. 71 In the hardware exception-handling sequence the CPU does the following: 1. Saves the program counter and status register (in minimum mode) or program counter, code page register, and status register (in maximum mode) to the stack. 2. Clears the T bit in the status register to 0. 3. Fetches the start address of the exception-handling routine from the exception vector table. 4. Branches to that address, returning to the program execution state. See section 4, “Exception Handling,” for further information on the exception-handling state. 3.8.4 Bus-Released State When so requested, the CPU can grant control of the external bus to an external device. While an external device has the bus right, the CPU is said to be in the bus-released state. The bus right is controlled by two pins: • BREQ: • BACK: Input pin for the Bus Request signal from an external device Output pin for the Bus Request Acknowledge signal from the CPU, indicating that the CPU has released the bus The procedure by which the CPU enters and leaves the bus-released state is: 1. The CPU receives a Low BREQ signal from an external device. 2. The CPU places the address bus pins (A19 – A0), data bus pins (D7 – D0) and bus control pins (RD, WR, R/W, DS, and AS) in the high-impedance state, sets the BACK pin to the Low level to indicate that it has released the bus, then halts. 3. The external device that requested the bus (with the BREQ signal) becomes the bus master. It can use the data bus and address bus. The external device is responsible for manipulating the bus control signals (RD, WR, R/W, DS, and AS). 4. When the external device finishes using the bus, it clears the BREQ signal to the High level. The CPU then reassumes control of the bus and returns to the program execution state. Bus Release Timing: The CPU can release the bus right at the following times: 1. The BREQ signal is sampled during every memory access cycle (instruction prefetch or data read/write). If BREQ is Low, the CPU releases the bus right at the end of the cycle. (In word data access to external memory or an address from H'FE80 to H'FFFF, the CPU does not release the bus right until it has accessed both the upper and lower data bytes.) 2. During execution of the MULXU and DIVXU instructions, since considerable time may pass without an instruction prefetch or data read/write, BREQ is also sampled at internal machine cycles, and the bus right is released if BREQ is Low. 3. The bus right can also be released in the sleep mode. The CPU does not recognize interrupts while the bus is released. 72 Timing Charts: Timing charts of the operation by which the bus is released are shown in figure 3-13 for the case of bus release during an on-chip memory read cycle, in figure 3-14 for bus release during an external memory read cycle, and in figure 3-15 for bus release while the CPU is performing an internal operation. On-chip memory Access cycle T2 T1* Bus-right release cycle T2* TX* TX TX CPU cycle TX T1 ø A19 –A 0 D7 –D0 RD, WR, R/W DS, AS BREQ BACK (1) (1) (2) (3) (4) (5) (2) (3) (4) (5) The BREQ pin is sampled at the start of the T1 state and the Low level is detected. At the end of the memory access cycle, the BACK pin goes Low and the CPU releases the bus. While the bus is released, the BREQ pin is sampled at each Tx state. A High level is detected at the BREQ pin. The BACK pin is returned to the High level, ending the bus-right release cycle. Fig. 3-13 * T1 and T2: On-chip memory access states. Tx : Bus-right released state. Figure 3-13 Bus-Right Release Cycle (During On-Chip Memory Access Cycle) 73 External access cycle T1 T2 TW* Bus-right release cycle T3 TX* TX CPU cycle TX T1 ø A19 –A 0 D7 –D0 RD, WR R/W, DS BREQ BACK (1) (1) (2) (3) (4) (2) (3) (4) The BREQ pin is sampled at the start of the TW state and the Low level is detected. At the end of the external access cycle, the BACK pin goes Low and the CPU releases the bus. The BREQ pin is sampled at the TX state and a High level is detected. The BACK pin is returned to the High level, ending the bus-right release cycle. * TW : Wait state. TX : Bus-right released state. Fig. 3-14 Figure 3-14 Bus-Right Release Cycle (During External Access Cycle) 74 CPU internal operation Ti * Ti Ti Bus-right release cycle Ti TX* TX CPU cycle TX T1 ø A19 –A 0 D7 –D0 RD, WR R/W, DS BREQ BACK (1) (1) (2) (3) (4) (2) (3) (4) The BREQ pin is sampled at the start of a TI state and the Low level is detected. At the end of the internal operation cycle, the BACK pin goes Low and the CPU releases the bus. The BREQ pin is sampled at the TX state and a High level is detected. The BACK pin is returned to the High level, ending the bus-right release cycle. * TI : Internal CPU operation state. TX : Bus-right released state. Figure 3-15 Bus-Right Release Cycle (During Internal CPU Operation) 75 Notes: The BREQ signal must be held Low until BACK goes Low. If BREQ returns to the High level before BACK goes Low, the bus release operation may be executed incorrectly. To leave the bus-released state, the High level at the BREQ pin must be sampled two times. If BREQ returns to Low before it is sampled two times, the bus released cycle will not end. The bus release operation is enabled only when the BRLE bit in the port 1 control register (P1CR) is set to 1. When this bit is cleared to 0 (its initial value), the BREQ and BACK pins are used for general-purpose input and output, as P13 and P12. An instruction that sets the BRLE bit is: BSET.B #3, @H'FEFC Note the following point when using the bus release function. If the BREQ signal is asserted and an interrupt is requested simultaneously during execution of the SLEEP instruction, the BACK signal may fail to be output even though the CPU has released the bus. This may cause the system to stop for the interval during which BREQ is asserted, with no device in control of the bus. The interrupts that can cause this state include NMI, IRQ, and all the interrupts from on-chip supporting modules. When the BREQ signal is deasserted, ending this state, the CPU takes control of the bus again and resumes normal instruction execution. The following methods can be used to avoid entering this state. Method 1: If the BREQ signal is used, do not use the SLEEP instruction. Method 2: Disable the BREQ signal during execution of the SLEEP instruction. This can be done by clearing the bus release enable bit (BRLE) in the port 1 control register (P1CR) to 0 immediately before executing the SLEEP instruction. (When the BRLE bit is cleared, low inputs on the BREQ line are not latched on-chip.) Place instructions to set the BRLE bit to 1 at the beginning of interrupt-handling routines. If the data transfer controller (DTC) is used, place an instruction to set the BRLE bit immediately after the SLEEP instruction. If method 2 is used, BREQ inputs will be ignored while the chip is in sleep mode. (Coding example) Main Program BCLR.B SLEEP BSET.B Interrupt-Handling Routine BSET.B #3, @SYSCR1 #3, @SYSCR1 #3, @SYSCR1 RTE 76 3.8.5 Reset State In the reset state, the CPU and all on-chip supporting modules are initialized and placed in the stopped state. The CPU enters the reset state whenever the RES pin goes Low, unless the CPU is currently in the hardware standby mode. It remains in the reset state until the RES pin goes High. See section 4.2, “Reset,” for further information on the reset state. 3.8.6 Power-Down State The power-down state comprises three modes: the sleep mode, the software standby mode, and the hardware standby mode. See section 18, “Power-Down State,” for further information. 77 3.9 Programming Notes 3.9.1 Restriction on Address Location The following restriction applies when instructions are located in on-chip RAM. • Restriction Instruction execution cannot proceed continuously from an external address to on-chip RAM. • Solution To execute instructions located in on-chip RAM, use a branch instruction (examples: Bcc, JMP, etc.) to branch to the first instruction located in on-chip RAM. Do not place instruction code in the last three bytes of external memory (H'F67D to H'F67F). H'F67A NOP H'F67A NOP H'F67B NOP H'F67B BRA H'F67C NOP H'F67C disp H'F67D NOP H'F67D H'F67E NOP H'F67E H'F67F NOP H'F680 NOP H'F681 NOP Do not place instruction code here H'F67F Not executable H'F680 NOP H'F681 NOP Execution Disabled Execution Enabled 78 Branch Section 4 Exception Handling 4.1 Overview 4.1.1 Types of Exception Handling and Their Priority As indicated in table 4-1 (a) and (b), exception handling can be initiated by a reset, address error, trace, interrupt, or instruction. An instruction initiates exception handling if the instruction is an invalid instruction, a trap instruction, or a DIVXU instruction with zero divisor. Exception handling begins with a hardware exception-handling sequence which prepares for the execution of a user-coded software exception-handling routine. There is a priority order among the different types of exceptions, as shown in table 4-1 (a). If two or more exceptions occur simultaneously, they are handled in their order of priority. An instruction exception cannot occur simultaneously with other types of exceptions. Table 4-1 (a) Exceptions and Their Priority Exception Priority Type High Source Detection Timing Start of ExceptionHandling Sequence Reset External, internal RES Low-to-High transition Immediately Address error Internal Instruction fetch or data read/write bus cycle End of instruction execution Trace Internal End of instruction execution, if T = 1 in status register End of instruction execution Interrupt External, internal End of instruction execution or end of exception-handling sequence End of instruction execution Low Table 4-1 (b) Instruction Exceptions Exception Type Start of Exception-Handling Sequence Invalid instruction Attempted execution of instruction with undefined code Trap instruction Started by execution of trap instruction Zero divide Attempted execution of DIVXU instruction with zero divisor 79 4.1.2 Hardware Exception-Handling Sequence The hardware exception-handling sequence varies depending on the type of exception. When exception handling is initiated by a factor other than a reset, the CPU: 1. Saves the program counter and status register (in minimum mode) or program counter, code page register, and status register (in maximum mode) to the stack. 2. Clears the T bit in the status register to 0. 3. Fetches the start address of the exception-handling routine from the exception vector table. 4. Branches to that address. For an interrupt, the CPU also alters the interrupt mask level in bits I2 to I0 of the status register. For a reset, step 1 is omitted. See section 4.2, “Reset”, for the full reset sequence. 4.1.3 Exception Factors and Vector Table The factors that initiate exception handling can be classified as shown in figure 4-1. The starting addresses of the exception-handling routines for each factor are contained in an exception vector table located in the low addresses of page 0. The vector addresses are listed in table 4-2. Note that there are different addresses for the minimum and maximum modes. 80 • Reset External interrupt NMI IRQ0 IRQ1 to IRQ5 • Interrupt Internal interrupt Internal interrupt requested by onchip module Exception • Address error • Trace Invalid instruction • Instruction Zero divide TRAPA instruction TRAP/VS instruction Figure 4-1 Types of Factors Causing Exception Handling 81 Table 4-2 Exception Vector Table Type of Exception Reset (initialize PC) — (Reserved for system) Invalid instruction DIVXU instruction (zero divide) TRAP/VS instruction — (Reserved for system) Address error Trace — (Reserved for system) Nonmaskable external interrupt (NMI) — (Reserved for system) TRAPA instruction (16 vectors) External interrupts Internal interrupts *2 IRQ0 IRQ1 IRQ2 IRQ3 IRQ4 IRQ5 Minimum Mode H'0000 to H'0001 H'0002 to H'0003 H'0004 to H'0005 H'0006 to H'0007 H'0008 to H'0009 H'000A to H'000B to H'000E to H'000F H'0010 to H'0011 H'0012 to H'0013 H'0014 to H'0015 H'0016 to H'0017 H'0018 to H'0019 to H'001E to H'001F H'0020 to H'0021 to H'003E to H'003F H'0040 to H'0041 H'0048 to H'0049 H'0050 to H'0051 H'0052 to H'0053 H'0058 to H'0059 H'005A to H'005B H'0060 to H'0061 to H'0098 to H'0099 Vector Address Maximum Mode *1 H'0000 to H'0003 H'0004 to H'0007 H'0008 to H'000B H'000C to H'000F H'0010 to H'0013 H'0014 to H'0017 to H'001C to H'001F H'0020 to H'0023 H'0024 to H'0027 H'0028 to H'002B H'002C to H'002F H'0030 to H'0033 to H'003C to H'003F H'0040 to H'0043 to H'007C to H'007F H'0080 to H'0083 H'0090 to H'0093 H'00A0 to H'00A3 H'00A4 to H'00A7 H'00B0 to H'00B3 H'00B4 to H'00B7 H'00C0 to H'00C3 to H'0130 to H'0133 Notes: * 1. The exception vector table is located at the beginning of page 0. * 2. For details of the internal interrupt vectors, see table 5-2. 82 4.2 Reset 4.2.1 Overview A reset has the highest exception-handling priority. When the RES pin goes Low, all current processing is halted and the H8/534 or H8/536 chip enters the reset state. A reset initializes the internal status of the CPU and the registers of the on-chip supporting modules and I/O ports. It does not initialize the on-chip RAM. When the RES pin returns from Low to High, the chip comes out of the reset state and begins executing the hardware reset sequence. 4.2.2 Reset Sequence The Reset signal is detected when the RES pin goes Low. To ensure that the H8/534 or H8/536 is reset, the RES pin should be held Low for at least 20 ms at power-up. To reset the H8/534 or H8/536 during operation, the RES pin should be held Low for at least 6 system clock cycles. See table D-1, “Status of Ports” in appendix D for the status of other pins in the reset state. When the RES pin returns to the High state after being held Low for the necessary time, the hardware reset exception-handling sequence begins, during which: 1. In the status register (SR), the T bit is cleared to disable the trace mode, and the interrupt mask level (bits I2 to I0) is set to 7. A reset disables all interrupts, including NMI. 2. The CPU loads the reset start address from the vector table into the program counter and begins executing the program at that address. The contents of the vector table differs between minimum mode and maximum mode as indicated in figure 4-2. This affects step 3 as follows: Minimum Mode: One word is copied from addresses H'0000 and H'0001 in the vector table to the program counter. Program execution then begins from the address in the program counter (PC). 83 Maximum Mode: Two words are read from addresses H'0000 to H'0003 in the vector table. The byte in address H'0000 is ignored. The byte in address H'0001 is copied to the code page register (CP). The contents of addresses H'0002 and H'0003 are copied to the program counter. Program execution starts from the address indicated by the code page register and program counter. H’0000 PC (Upper) H’0000 Don’t care H’0001 PC (Lower) H’0001 CP H’0002 PC (Upper) H’0003 PC (Lower) (1) Minimum mode (2) Maximum mode Figure 4-2 Reset Vector Figure 4-3 shows the timing of the reset sequence in minimum mode. Figure 4-4 shows the timing of the reset sequence in maximum mode. 4.2.3 Stack Pointer Initialization The hardware reset sequence does not initialize the stack pointer, so this must be done by software. If an interrupt were to be accepted after Fig. a reset 4-2and before the stack pointer (SP) is initialized, the program counter and status register would not be saved correctly, causing a program crash. This danger can be avoided by coding the reset routine as explained next. When the chip comes out of the reset state all interrupts, including NMI, are disabled, so the instruction at the reset start address is always executed. In the minimum mode, this instruction should initialize the stack pointer (SP). In the maximum mode, this instruction should be an LDC instruction initializing the stack page register (TP), and the next instruction should initialize the stack pointer. Execution of the LDC instruction disables interrupts again, ensuring that the stack pointer initializing instruction is executed. 84 Figure 4-3 Reset Sequence (Minimum Mode, On-Chip Memory) 85 Minimum 6 states (1) Instruction prefetch address (2) Operation code (2) (1) Reset vector (3) Program start address (4) First instruction of program Internal processing cycle Vector Vector address Prefetch first instruction of program (4) (3) Instruction execution cycle Note: This timing chart applies to the minimum mode when the program and stack areas are both in on-chip memory and the program starts at an even address. Internal Write signal Internal Read signal Internal data bus (16 bits) Internal address bus RES ø Figure 4-4 Reset Sequence (Maximum Mode, External Memory) 86 Vector PC H Vector address + 2 Reset vector Vector CP don’t care (1) Program start address (2) First instruction of program Internal processing cycle Vector address + 1 Vector address Vector PC L Vector address + 3 (2) (1) Prefetch first instruction of program Note: This diagram applies to maximum mode when the program area and vector table are both in external memory. After a reset, the wait-state controller inserts three wait states in each bus cycle. Write signal LWR, HWR Read signal RD D15 to D0 A 23 to A 0 RES ø Instruction execution cycle 4.3 Address Error There are three causes of address errors: • Illegal instruction prefetch • Word data access at odd address • Off-chip access in single-chip mode An address error initiates the address error exception-handling sequence. This sequence clears the T bit of the status register to 0 to disable the trace mode, but does not affect the interrupt mask level in bits I2 to I0. 4.3.1 Illegal Instruction Prefetch An attempt to prefetch an instruction from the register field in memory addresses H'FE80 to H'FFFF causes an address error regardless of the MCU operating mode. Handling of this address error begins when the prefetch cycle that caused the error has been completed and execution of the current instruction has also been completed. The program counter value pushed on the stack is the address of the instruction immediately following the last instruction executed. Program code should not be located in addresses H'FE7D to H'FE7F. If the CPU executes an instruction in these addresses, it will attempt to prefetch the next instruction from the register field, causing an address error. 4.3.2 Word Data Access at Odd Address If an attempt is made to access word data starting at an odd address, an address error occurs regardless of the MCU operating mode. The program counter value pushed on the stack in the handling of this error is the address of the next instruction (or next but one) after the instruction that attempted the illegal word access. 4.3.3 Off-Chip Address Access in Single-Chip Mode In the single-chip mode there is no external memory, so in addition to the address errors described above, the following two types of address errors can occur. Access to Addresses H'8000 to H'F67F(H8/534): These addresses exist neither in on-chip ROM or RAM nor in the on-chip register field, so an address error occurs if they are accessed for any purpose: for instruction prefetch, byte data access, or word data access. Program code should not be located in the last three bytes of on-chip ROM (addresses H'7FFD to 87 H'7FFF). If the CPU excutes an instruction in these addresses, it will attempt to prefetch the next instruction from addresses H'8000 to H'8002, causing an address error. Access to Disabled RAM Area: The on-chip RAM area (H'F680 to H'FE7F) can be disabled by clearing the RAME bit in the RAM control register (RAMCR). If any form of RAM access is attempted in this state in the single-chip mode, an address error occurs. 4.4 Trace When the T bit of the status register is set to 1, the CPU operates in trace mode. A trace exception occurs at the completion of each instruction. The trace mode can be used to execute a program for debugging by a debugger. In the trace exception sequence the T bit of the status register is cleared to 0 to disable the trace mode while the trace routine is executing. The interrupt mask level in bits I2 to I0 is not changed. Interrupts are accepted as usual during the trace routine. In the status-register data saved on the stack, the T bit is set to 1. When the trace routine returns with the RTE instruction, the status register is popped from the stack and the trace mode resumes. If an address error occurs during execution of the first instruction after the return from the trace routine, since the address error has higher priority, the address error exception-handling sequence is initiated, clearing the T bit in the status register to 0 and making it impossible to trace this instruction. 4.5 Interrupts Interrupts can be requested from seven external sources (NMI, IRQ0, and IRQ1 to IRQ5) and eight on-chip supporting modules: the 16-bit free-running timers (FRT1 to FRT3), the 8-bit timer, the serial communication interfaces (SCI1 and SCI2), the A/D converter, and the watchdog timer (WDT). The on-chip interrupt sources can request a total of nineteen different types of interrupts, each having its own interrupt vector. Figure 4-5 lists the interrupt sources and the number of different interrupts from each source. Each interrupt source has a priority. NMI interrupts have the highest priority, and are normally accepted unconditionally. The priorities of the other interrupt sources are set in control registers (IPR A to D) in the register field at the high end of page 0 and can be changed by software. Priority levels range from 0 (low) to 7 (high), with NMI considered to be on level 8. IRQ0 and IRQ1 can be prioritized individually. IRQ2 and IRQ3 are prioritized as a pair. IRQ4 and IRQ5 are also prioritized as a pair. The on-chip supporting modules are prioritized as modules. 88 The on-chip interrupt controller decides whether an interrupt can be accepted by comparing its priority with the interrupt mask level, and determines the order in which to accept competing interrupt requests. Interrupts that are not accepted immediately remain pending until they can be accepted later. When it accepts an interrupt, the interrupt controller also decides whether to interrupt the CPU or start the on-chip data transfer controller (DTC). This decision is controlled by bits set in four data transfer enable registers (DTEA to DTEF) in the register field. The DTC is started if the corresponding bit in DTEA to DTEF is set to 1; otherwise a CPU interrupt is generated. DTC interrupts provide an efficient way to send and receive blocks of data via the serial communication interface, or to transfer data between memory and I/O without detailed CPU programming. The CPU stops while the DTC is operating. DTC interrupts are described in section 6, “Data Transfer Controller.” The hardware exception-handling sequence for a CPU interrupt clears the T bit in the status register to 0 and sets the interrupt mask level in bits I2 to I0 to the level of the interrupt it has accepted. This prevents the interrupt-handling routine from being interrupted except by a higher-level interrupt. The previous interrupt mask level is restored on the return from the interrupt-handling routine. For further information on interrupts, see section 5, “Interrupt Controller.” 89 External interrupts NMI (1) IRQ0 (1) IRQ1 to IRQ5 (5) Interrupt sources 16-Bit FRT1 (4) 16-Bit FRT2 (4) 16-Bit FRT3 (4) Internal interrupts 8-Bit timer (3) SCI (3) A/D converter (1) WDT* (1) NMI: IRQ: FRT: SCI: WDT: NonMaskable Interrupt Interrupt Request Free-Running Timer Serial Communication Interface WatchDog Timer * When the watchdog timer is used in interval timer mode, and interrupt is requested at each counter overflow. Figure 4-5 Interrupt Sources (and Number of Interrupt Types) 90 4.6 Invalid Instruction An invalid instruction exception occurs if an attempt is made to execute an instruction with an undefined operation code or illegal addressing mode specification. The program counter value pushed on the stack is the value of the program counter when the invalid instruction code was detected. In the invalid instruction exception-handling sequence the T bit of the status register is cleared to 0, but the interrupt mask level (I2 to I0) is not affected. 4.7 Trap Instructions and Zero Divide A trap exception occurs when the TRAPA or TRAP/VS instruction is executed. A zero divide exception occurs if an attempt is made to execute a DIVXU instruction with a zero divisor. In the exception-handling sequences for these exceptions the T bit of the status register is cleared to 0, but the interrupt mask level (I2 to I0) is not affected. If a normal interrupt is requested while a trap or zero-divide instruction is being executed, after the trap or zero-divide exception-handling sequence, the normal interrupt exception-handling sequence is carried out. TRAPA Instruction: The TRAPA instruction always causes a trap exception. The TRAPA instruction includes a vector number from 0 to 15, allowing the user to provide up to sixteen different trap-handling routines. TRAP/VS Instruction: When the TRAP/VS instruction is executed, a trap exception occurs if the overflow (V) bit in the condition code register is set to 1. If the V bit is cleared to 0, no exception occurs and the next instruction is executed. DIVXU Instruction with Zero Divisor: An exception occurs if an attempt is made to divide by zero in a DIVXU instruction. 4.8 Cases in Which Exception Handling is Deferred In the cases described next, the address error exception, trace exception, external interrupt (NMI, IRQ0, and IRQ1 to IRQ5) requests, and internal interrupt requests (23 types) are not accepted immediately but are deferred until after the next instruction has been executed. 4.8.1 Instructions that Disable Interrupts Interrupts are disabled immediately after the execution of five instructions: XORC, ORC, ANDC, LDC, and RTE. Suppose that an internal interrupt is requested and the interrupt controller, after checking the interrupt priority and interrupt mask level, notifies the CPU of the interrupt, but the CPU is 91 currently executing one of the five instructions listed above. After executing this instruction the CPU always proceeds to the next instruction. (And if the next instruction is one of these five, the CPU also proceeds to the next instruction after that.) The exception-handling sequence starts after the next instruction that is not one of these five has been executed. The following is an example: (Example) . . . . . . LDC.B #H'00,TP MOV.W #H'FE80,SP Program flow ← Interrupt controller notifies CPU of interrupt CPU executes the instruction next to LDC before starting exception handling MOV.B #H'00,@WCR To exception-handling sequence . . . 4.8.2 Disabling of Exceptions Immediately after a Reset If an interrupt is accepted after a reset and before the stack pointer (SP) is initialized, the program counter and status register will not be saved correctly, leading to a program crash. To prevent this, when the chip comes out of the reset state all interrupts, including the NMI, are disabled, so the first instruction of the reset routine is always executed. As noted earlier, in the minimum mode, this instruction should initialize the stack pointer (SP). In the maximum mode, the first instruction should be an LDC instruction that initializes the stack page register (TP); the next instruction should initialize the stack pointer. 4.8.3 Disabling of Interrupts after a Data Transfer Cycle If an interrupt starts the data transfer controller and another interrupt is requested during the data transfer cycle, when the data transfer cycle ends, the CPU always executes the next instruction before handling the second interrupt. Even if a nonmaskable interrupt (NMI) occurs during a data transfer cycle, it is not accepted until the next instruction has been executed. An example of this is shown below. 92 (Example) . . . . . Program flow ← DTC interrupt request ADD.W R2,R0 NMI interrupt Data transfer cycle MOV.W R0,@H'FE00 After data transfer cycle, CPU executes next instruction before branching to exception handling MOV.W #H'FE02,R0 . . . To NMI exception-handling sequence 4.9 Stack Status after Completion of Exception Handling The status of the stack after an exception-handling sequence is described below. Table 4-3 shows the stack after completion of the exception-handling sequence for various types of exceptions in the minimum and maximum modes. Table 4-3 Stack after Exception Handling Sequence Exception Factor Trace Interrupt Trap SP Minimum Mode Maximum Mode SR (upper byte) TP:SP SR (upper byte) SR (lower byte) SR (lower byte) Next instruction address (upper byte) Don’t-care Next instruction address (lower byte) Next instruction page (8 bits) Next instruction address (upper byte) Next instruction address (lower byte) Zero divide (DIVXU) Note: The RTE instruction returns to the next instruction after the instruction being executed when the exception occurred. Table 4-3 93 Table 4-3 Stack after Exception Handling Sequence (cont) Exception Factor Invalid instruction SP Minimum Mode Maximum Mode SR (upper byte) TP:SP SR (upper byte) SR (lower byte) SR (lower byte) PC when error occurred (upper byte) Don’t-care PC when error occurred (lower byte) CP when error occurred (8 bits) PC when error occurred (upper byte) PC when error occurred (lower byte) Note: The program counter value pushed on the stack is not necessarily the address of the first byte of the invalid instruction. Table 4-3(cont) Address error SP SR (upper byte) TP:SP SR (upper byte) SR (lower byte) SR (lower byte) PC when error occurred (upper byte) Don’t-care PC when error occurred (lower byte) CP when error occurred (8 bits) PC when error occurred (upper byte) PC when error occurred (lower byte) Note: The program counter value pushed on the stack is the address of the next instruction after the last instruction successfully executed. Table 4-3(cont) 94 4.9.1 PC Value Pushed on Stack for Trace, Interrupts, Trap Instructions, and Zero Divide Exceptions The program counter value pushed on the stack for a trace, interrupt, trap, or zero divide exception is the address of the next instruction at the time when the interrupt was accepted. The RTE instruction accordingly returns to the next instruction after the instruction executed before the exception-handling sequence. 4.9.2 PC Value Pushed on Stack for Address Error and Invalid Instruction Exceptions The program counter value pushed on the stack for an address error or invalid instruction exception differs depending on the conditions when the exception occurred. 4.10 Notes on Use of the Stack If the stack pointer is set to an odd address, an address error will occur when the stack is accessed during interrupt handling or for a subroutine call. The stack pointer should always point to an even address. To keep the stack pointer pointing to an even address, a program should use word data size when saving or restoring registers to and from the stack. In the @–SP or @SP+ addressing mode, the CPU performs word access even if the instruction specifies byte size. (This is not true in the @–Rn and @Rn+ addressing modes when Rn is a register from R0 to R6.) 95 Section 5 Interrupt Controller 5.1 Overview The interrupt controller decides which interrupts to accept, and how to deal with multiple interrupts. It also decides whether an interrupt should be served by the CPU or by the data transfer controller (DTC). This section explains the features of the interrupt controller, describes its internal structure and control registers, and details the handling of interrupts. For detailed information on the data transfer controller, see section 6, “Data Transfer Controller.” 5.1.1 Features Three main features of the interrupt controller are: • Interrupt priorities are user-programmable. User programs can set priority levels from 7 (high) to 0 (low) in six interrupt priority (IPR) registers for IRQ0, IRQ1 to IRQ5, and each of the on-chip supporting modules—for every interrupt, that is, except the nonmaskable interrupt (NMI). NMI has the highest priority level (8) and is normally always accepted. An interrupt with priority level 0 is always masked. • Multiple interrupts on the same level are served in a default priority order. Lower-priority interrupts remain pending until higher-priority interrupts have been handled. • For most interrupts, software can select whether to have the interrupt served by the CPU or the on-chip data transfer controller (DTC). User programs can make this selection by setting and clearing bits in four data transfer enable (DTE) registers. The data transfer controller can be started by any interrupts except NMI, the error interrupt (ERI) from the on-chip serial communication interface, and the overflow interrupts (FOVI and OVI) from the on-chip timers. 97 5.1.2 Block Diagram Figure 5-1 shows the block configuration of the interrupt controller. Interrupt controller NMI request NMI IRQ 0 /interval timer IRQ 4 /IRQ 5 FRT1 FRT2 FRT3 8 bit timer Interrupt request SCI A/D converter DTEA to DTEF Interrupt request signals from modules Comparator IPRA to IPRF IRQ 2 /IRQ 3 Priority decision IRQ 1 DTC request I2 I1 I0 SR (CPU) FRT: 16 Bits Free Running Timer SCI: Serial Communication Interface SR: Status Register IPRA to IPRF: Interrupt Priority Register DTEA to DTEF: Data Transfer Enable Register Figure 5-1 Interrupt Controller Block Diagram 98 5.1.3 Register Configuration The six interrupt priority registers (IPRA to IPRF) and six data transfer enable registers (DTEA to DTEF) are 8-bit registers located at addresses H'FF00 to H'FF0D in the register field in page 0 of the address space. Table 5-1 lists their attributes. Table 5-1 Interrupt Controller Registers Name Interrupt priority register Data transfer enable register A B C D E F A B C D E F Abbreviation IPRA IPRB IPRC IPRD IPRE IPRF DTEA DTEB DTEC DTED DTEE DTEF Read/Write R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Address H'FF00 H'FF01 H'FF02 H'FF03 H'FF04 H'FF05 H'FF08 H'FF09 H'FF0A H'FF0B H'FF0C H'FF0D Initial Value H'00 H'00 H'00 H'00 H'00 H'00 H'00 H'00 H'00 H'00 H'00 H'00 See section 6.2.5, “Data Transfer Enable Registers A to F” for further information about DTEA to DTEF. 5.2 Interrupt Types There are 30 distinct types of interrupts: 7 external interrupts originating off-chip and 23 internal interrupts originating in the on-chip supporting modules. 5.2.1 External Interrupts The seven external interrupts are NMI, IRQ0, and IRQ1 to IRQ5. NMI (NonMaskable Interrupt): This interrupt has the highest priority level (8) and cannot be masked. An NMI is generated by input to the NMI pin, and can also be generated by a watchdog timer (WDT) overflow. The input at the NMI pin is edge-sensed. A user program can select whether to have the interrupt occur on the rising edge or falling edge of the NMI input by setting or clearing the nonmaskable interrupt edge bit (NMIEG) in system control register 1 (SYSCR1). In the NMI exception-handling sequence, the T (Trace) bit in the CPU status register (SR) is cleared to "0," and the interrupt mask level in I2 to I0 is set to 7, masking all other interrupts. The interrupt controller holds the NMI request until the NMI exception-handling sequence begins, 99 then clears the NMI request, so if another interrupt is requested at the NMI pin during the NMI exception-handling sequence, the NMI exception-handling sequence will be carried out again. Coding Examples: To select the rising edge of the NMI input: To select the falling edge of the NMI input: BSET.B #4, @H'FEFC BCLR.B #4, @H'FEFC IRQ0 (Interrupt Request 0): An IRQ0 interrupt can be requested by a Low input to the IRQ0 pin. A Low IRQ0 input requests an IRQ0 interrupt if the interrupt request enable 0 bit (IRQ0E) in SYSCR1 is set to 1. IRQ0 must be held Low until the CPU accepts the interrupt. Otherwise the request will be ignored. The IRQ0 interrupt can be assigned any priority level from 7 to 0 by setting the corresponding value in the upper four bits of IPRA. If bit 4 of data transfer enable register A (DTEA) is set to 1, an IRQ0 interrupt starts the data transfer controller. Otherwise the interrupt is served by the CPU. In the CPU interrupt-handling sequence for IRQ0, the T bit of the status register is cleared to 0, and the interrupt mask level is set to the value in the upper four bits of IPRA. Coding Examples: To enable IRQ0 to be requested by IRQ0 input: To assign priority level 7 to IRQ0: To have IRQ0 start the DTC: BSET.B #5, @H'FEFC OR.B #70, @H'FF00 BSET.B #4, @H'FF08 IRQ1 to IRQ5 (Interrupt Request 1 to 5): An IRQ1 to IRQ5 interrupt is requested by a High-toLow transition at the IRQ1 to IRQ5 pin. The IRQ1 interrupt is enabled only when the interrupt request enable 1 bit (IRQ1E) in SYSCR1 is set to 1. IRQ2 to IRQ5 are controlled by bits IRQ2E to IRQ5E in SYSCR2. (see section 9.7, “Port 6.”) Interrupts IRQ1 to IRQ5 can be assigned any priority level from 7 (high) to 0 (low) by setting the corresponding value in IPRA and IPRB. The lower four bits of IPRA determine the priority of IRQ1. The upper four bits of IPRB determine the priority of IRQ2 and IRQ3. The lower four bits of IPRB determine the priority of IRQ4 and IRQ5. Interrupt requests IRQ1 to IRQ5 are held in the interrupt controller and cleared during the corresponding interrupt exception-handling sequence. Contention among IRQ1 to IRQ5 is resolved when the CPU accepts the interrupt by taking the interrupt with the highest priority first and holding lower-priority interrupts pending. (Contention between IRQ2 and IRQ3, or between IRQ4 and IRQ5, is resolved by the priority order shown in table 5-2.) 100 During the interrupt-handling routine, if the same external interrupt is requested again the request is held, but the exception-handling sequence is not carried out immediately because the interrupt is masked by bits I2 to I0 in the status register. On return from the interrupt-handling routine one more instruction is executed, then the pending exception-handling sequence is carried out. Interrupts IRQ1 to IRQ5 are served by the CPU or DTC depending on DTEA bit 0 and DTEB bits 0, 1, 4, and 5. In the CPU interrupt exception-handling sequence for IRQ1 to IRQ5, the T bit of the CPU status register is cleared to 0, and the interrupt mask level is set to the value in IPRA or IPRB. Coding Examples: To enable IRQ1 to be requested by IRQ1 input: To assign priority level 7 to IRQ0 and level 5 to IRQ1: To have IRQ1 start the DTC: BSET.B #6, @H'FEFC MOV.B #75, @H'FF00 BSET.B #0, @H'FF08 5.2.2 Internal Interrupts Twenty-three types of internal interrupts can be requested by the on-chip supporting modules. Each interrupt is separately vectored in the exception vector table, so it is not necessary for the user-coded interrupt handler routine to determine which type of interrupt has occurred. Each of the internal interrupts can be enabled or disabled by setting or clearing an enable bit in the control register of the on-chip supporting module. An interrupt priority level from 7 to 0 can be assigned to each on-chip supporting module by setting interrupt priority registers C to F. Within each module, different interrupts have a fixed priority order. For most of these interrupts, values set in data transfer enable registers C to F can select whether to have the interrupt served by the CPU or the data transfer controller. In the CPU interrupt-handling sequence, the T bit of the CPU status register is cleared to 0, and the interrupt mask level in bits I2 to I0 is set to the value in the IPR. Unlike external interrupt requests, internal interrupt requests are not held in the interrupt controller, so the bits that generate internal interrupts must be cleared by software. 101 5.2.3 Interrupt Vector Table Table 5-2 lists the addresses of the exception vector table entries for each interrupt, and explains how their priority is determined. For the on-chip supporting modules, the priority level set in the interrupt priority register applies to the module as a whole: all interrupts from that module have the same priority level. A separate priority order is established among interrupts from the same module. If the same priority level is assigned to two or more modules and two interrupts are requested simultaneously from these modules, they are served in the priority order indicated in the rightmost column in table 5-2. A reset clears the interrupt priority registers so that all interrupts except NMI start with priority level 0, meaning that they are unconditionally masked. 102 Table 5-2 Interrupts, Vectors, and Priorities Interrupt NMI IRQ0 Interval timer IRQ1 IRQ2 IRQ3 IRQ4 IRQ5 FRT1 ICI OCIA OCIB FOVI FRT2 ICI OCIA OCIB FOVI FRT3 ICI OCIA OCIB FOVI 8-bit CMIA timer CMIB OVI SCI1 ERI RXI TXI SCI2 ERI RXI TXI A/D ADI converter Assignable Priority Levels (Initial Level) 8(8) 7 to 0 (0) 7 to 0 (0) 7 to 0 (0) 7 to 0 (0) 7 to 0 (0) IPR Bits — IPRA bits 6 to 4 IPRA bits 2 to 0 IPRB bits 6 to 4 IPRB bits 2 to 0 IPRC bits 6 to 4 7 to 0 (0) IPRC bits 2 to 0 7 to 0 (0) IPRD bits 6 to 4 7 to 0 (0) IPRD bits 2 to 0 7 to 0 (0) IPRE bits 6 to 4 7 to 0 (0) IPRE bits 2 to 0 7 to 0 (0) IPRF bits 6 to 4 Priority within Module — 1 0 — Vector Table Entry Address Minimum Maximum Mode Mode H'16 - H'17 H'2C - H'2F H'40 - H'41 H'80 - H'83 H'42 - H'43 H'84 - H'87 H'48 - H'49 H'90 - H'93 1 0 1 0 3 2 1 0 3 2 1 0 3 2 1 0 2 1 0 2 1 0 2 1 0 — H'50 - H'51 H'52 - H'53 H'58 - H'59 H'5A - H'5B H'60 - H'61 H'62 - H'63 H'64 - H'65 H'66 - H'67 H'68 - H'69 H'6A - H'6B H'6C - H'6D H'6E - H'6F H'70 - H'71 H'72 - H'73 H'74 - H'75 H'76 - H'77 H'78 - H'79 H'7A - H'7B H'7C - H'7D H'80 - H'81 H'82 - H'83 H'84 - H'85 H'88 - H'89 H'8A - H'8B H'8C - H'8D H'90 - H'91 Priority among Interrupts on Same Level* High H'A0 - H'A3 H'A4 - H'A7 H'B0 - H'B3 H'B4 - H'B7 H'C0 - H'C3 H'C4 - H'C7 H'C8 - H'CB H'CC - H'CF H'D0 - H'D3 H'D4 - H'D7 H'D8 - H'DB H'DC - H'DF H'E0 - H'E3 H'E4 - H'E7 H'E8 - H'EB H'EC - H'EF H'F0 - H'F3 H'F4 - H'F7 H'F8 - H'FB H'100 - H'103 H'104 - H'107 H'108 - H'10B H'110 - H'113 H'114 - H'117 H'118 - H'11B H'120 - H'123 Low * If two or more interrupts are requested simultaneously, they are handled in order of priority level, as set in registers IPRA to IPRF. If they have the same priority level because they are requested from the same on-chip supporting module, they are handled in a fixed priority order within the module. If they are requested from different modules to which the same priority level is assigned, they are handled in the order indicated in the right-hand column. 103 5.3 Register Descriptions 5.3.1 Interrupt Priority Registers A to F (IPRA to IPRF) IRQ0, IRQ1 to IRQ5, and the on-chip supporting modules are each assigned three bits in one of the six interrupt priority registers (IPRA to IPRF). These bits specify a priority level from 7 (high) to 0 (low) for interrupts from the corresponding source. The drawing below shows the configuration of the interrupt priority registers. Table 5-3 lists their assignments to interrupt sources. Bit 7 6 5 4 — 3 2 1 0 — Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W Note: Bits 7 and 3 are reserved. They cannot be modified and are always read as 0. Table 5-3 Assignment of Interrupt Priority Registers Register IPRA IPRB IPRC IPRD IPRE IPRF Interrupt Request Source Bits 6 to 4 Bits 2 to 0 IRQ0 IRQ1 IRQ2, IRQ3 IRQ4, IRQ5 FRT1 FRT2 FRT3 8-bit timer SCI1 SCI2 A/D converter — As table 5-3 indicates, each interrupt priority register specifies priority levels for two interrupt sources. A user program can assign desired levels to these interrupt sources by writing “000” in bits 6 to 4 or bits 2 to 0 to set priority level 0, for example, or “111” to set priority level 7. A reset clears registers IPRA to IPRF to H'00, so all interrupts except NMI are initially masked. 104 When the interrupt controller receives one or more interrupt requests, it selects the request with the highest priority and compares its priority level with the interrupt mask level set in bits I2 to I0 in the CPU status register. If the priority level is higher than the mask level, the interrupt controller passes the interrupt request to the CPU (or starts the data transfer controller). If the priority level is lower than the mask level, the interrupt controller leaves the interrupt request pending until the interrupt mask is altered to a lower level or the interrupt priority is raised. Similarly, if it receives two interrupt requests with the same priority level, the interrupt controller determines their priority as explained in table 5-2 and leaves the interrupt request with the lower priority pending. 5.3.2 Timing of Priority Setting The interrupt controller requires two system clock (ø) periods to determine the priority level of an interrupt. Accordingly, when an instruction modifies an instruction priority register, the new priority does not take effect until after the next instruction has been executed. 5.4 Interrupt Handling Sequence 5.4.1 Interrupt Handling Flow The interrupt-handling sequence follows the flowchart in figure 5-2. Note that address error, trace exception, and NMI requests bypass the interrupt controller’s priority decision logic and are routed directly to the CPU. 1. Interrupt requests are generated by one or more on-chip supporting modules or external interrupt sources. 2. The interrupt controller checks the interrupt priorities set in IPRA to IPRF and selects the interrupt with the highest priority. Interrupts with lower priorities remain pending. Among interrupts with the same priority level, the interrupt controller determines priority as explained in table 5-2. 3. The interrupt controller compares the priority level of the selected interrupt request with the mask level in the CPU status register (bits I2 to I0). If the priority level is equal to or less than the mask level, the interrupt request remains pending. If the priority level is higher than the mask level, the interrupt controller accepts the interrupt request and proceeds to the next step. 4. The interrupt controller checks the corresponding bit (if any) in the data transfer enable registers (DTEA to DTEF). If this bit is set to 1, the data transfer controller is started. Otherwise, the CPU interrupt exception-handling sequence is started. When the data transfer controller is started, the interrupt request is cleared (except for interrupt requests from the serial communication interface, which are cleared by writing to the TDR or reading the RDR). 105 If the data transfer enable bit is cleared to 0 (or is nonexistent), the sequence proceeds as follows. For the case in which the data transfer controller is started, see section 6, “Data Transfer Controller.” 5. After the CPU has finished executing the current instruction, the program counter and status register (in minimum mode) or program counter, code page register, and status register (in maximum mode) are saved to the stack, leaving the stack in the condition shown in figure 5-3 (a) or (b). The program counter value saved on the stack is the address of the next instruction to be executed. 6. The T (Trace) bit of the status register is cleared to 0, and the priority level of the interrupt is copied to bits I2 to I0, thus masking further interrupts unless they have a higher priority level. When an NMI is accepted, the interrupt mask level in bits I2 to I0 is set to 7. 7. The interrupt controller generates the vector address of the interrupt, and the entry at this address in the exception vector table is read to obtain the starting address of the user-coded interrupt handling routine. In step 7, the same difference between the minimum and maximum modes exists as in the reset handling sequence. In the minimum mode, one word is copied from the vector table to the program counter, then the interrupt-handling routine starts executing from the address indicated in the program counter. In the maximum mode, two words are read. The lower byte of the first word is copied to the code page register. The second word is copied to the program counter. The interrupt-handling routine starts executing from the address indicated in the code page register and program counter. 106 Program execution state N Interrupt requested? Address error? Y N N Trace? NMI? Y Y Y N N Level-7 interrupt? N Level-6 interrupt? Y Level-1 interrupt? Y N Y Mask level in SR ≤ 6? Mask level in SR ≤ 5? N Y Mask level in SR = 0? N Y N Y Interrupt remains pending Y Data transfer enabled? Start DTC Read DTC vector N Exception-handling sequence Read transfer mode Save PC Read source address Read data Y Maximum mode? N Source address increment mode? Save PC Y Increment source address (+1 or +2) N Save SR Write source address Read destination address Clear T bit Write data N Trace Destination address increment mode? Address error? Y N N Update mask level Y Increment source address (+1 or +2) Write destination address Read DTCR Vectoring DTCR-1 → DTCR Write DTCR To user-coded exception-handling routine Y DTCR = 0? Figure 5-2 Interrupt Handling Flowchart 107 N 5.4.2 Stack Status after Interrupt Handling Sequence Figure 5-3 (a) and (b) show the stack before and after the interrupt exception-handling sequence. Address Address 2m – 4 2m – 4 Upper 8 bits of SR 2m – 3 2m – 3 Lower 8 bits of SR 2m – 2 2m – 2 Upper 8 bits of PC 2m – 1 Lower 8 bits of PC 2m – 1 SP 2m 2m Stack area (Before) (After) Save to stack Notes: 1. PC: The address of the next instruction to be executed is saved. 2. Register saving and restoring must start at an even address (e.g 2m). Figure 5-3 (a) Stack before and after Interrupt Exception-Handling (Minimum Mode) Fig. 5-3(a) 108 SP Address Address 2m – 6 2m – 6 Upper 8 bits of SR 2m – 5 2m – 5 Lower 8 bits of SR 2m – 4 2m – 4 Don’t care 2m – 3 2m – 3 CP 2m – 2 2m – 2 Upper 8 bits of PC 2m – 1 2m – 1 Lower 8 bits of PC SP 2m SP 2m Stack area (Before) (After) Save to stack Notes: 1. PC: The address of the next instruction to be executed is saved. 2. Register saving and restoring must start at an even address (e.g 2m). Figure 5-3 (b) Stack before and after Interrupt Exception-Handling (Maximum Mode) 5.4.3 Timing of Interrupt Exception-Handling Sequence Figure 5-4 shows the timing of the exception-handling sequence Fig. 5-3(b) for an interrupt in minimum mode when the program area and stack area are both in on-chip memory and the user-coded interrupt handling routine starts at an even address. Figure 5-5 shows the timing of the exception-handling sequence for an interrupt in maximum mode when the program area and stack area are both in external memory. 5.5 Interrupts During Operation of the Data Transfer Controller If an interrupt is requested during a DTC data transfer cycle, the interrupt is not accepted until the data transfer cycle has been completed and the next instruction has been executed. This is true even if the interrupt is an NMI. An example is shown below. Program flow (Example) DTC interrupt request ADD.W R2, R0 MOV.W R0, @H'FE00 ADD.W @H' FE02,R0 Data transfer cycle NMI interrupt After data transfer cycle, CPU executes next instruction before starting exception handling To NMI exception handling sequence 109 Figure 5-4 Interrupt Sequence (Minimum Mode, On-Chip Memory) 110 (2) (1) (2) (1) (2) Internal processing cycle (1) Stack access SR SP - 4 (4) (3) (4) First instruction of interrupt-handling routine Prefetch first Start instruction Interrupt accepted instruction of execution interrupthandling routine Vector Vector address (3) Starting address of interrupt-handling routine PC SP - 2 Note: This timing chart applies to the minimum mode when the program and stack areas are both in on-chip memory and the interrupt-handling routine starts at an even address. (2) Instruction code Priority level decision and wait for end of current instruction (1) Instruction prefetch address Internal write signal Internal read signal Internal data bus (16 bits) NMI, IRQ0 IRQ 1 to IRQ 5 Interrupt address bus ø Figure 5-5 Interrupt Sequence (Maximum Mode, External Memory) 111 (2) (1) PC H SP – 2 Priority level decision Internal and wait for processing end of cycle current instruction (2) (1) PC L SP – 1 CP SP – 3 Stack access don’t care SP – 4 SR H SP – 6 SR L SP – 5 Vector don’t care address Vector Vector Vector Vector Interrupt vector Vector Vector address + 1 address + 2 address + 3 Note: This timing chart applies to the maximum mode when the program and stack areas are both in external memory. Instruction execution starts after interrupt vector fetch and 4-byte (4 bys cycles) instruction prefetch has been done. (4) First instruction of interrupt-handling routine (3) Starting address of interrupt-handling routine (2) Instruction code (1) Instruction prefetch address Internal Write signal Internal Read signal Internal data bus (16 bits) NMI, IRQ 0 IRQ1 to IRQ5 Internal address bus ø Prefetch first instruction of interrupt-handling routine (4) (3) Start instruction execution 5.6 Interrupt Response Time Table 5-4 indicates the number of states that may elapse between the generation of an interrupt request and the execution of the first instruction of the interrupt-handling routine, assuming that the interrupt is not masked and not preempted by a higher-priority interrupt. Since word access is performed to on-chip memory areas, fastest interrupt service can be obtained by placing the program in on-chip ROM and the stack in on-chip RAM. Table 5-4 Number of States before Interrupt Service No. 1 2 3 Reason for Wait Interrupt priority decision and comparison with mask level in CPU status register Maximum number of Instruction is in on-chip states to completion memory of current instruction Instruction is in external memory Number of States Minimum Mode Maximum Mode 2 states x (x = 38 for LDM instruction specifying all registers) y (y = 74 + 16m for LDM instruction specifying all registers) Stack is in on-chip RAM 16 21 Stack is in external memory 28 + 6m 41 + 10m Saving of PC and SR or PC, CP, and SR and instruction prefetch Stack is in Instruction is in on-chip on-chip RAM memory Instruction is in external Total memory Stack is in Instruction is in on-chip external RAM memory Instruction is in external memory 18 + x (56) 18 + y (92 + 16m) 30 + 6m + x (68 + 6m) 30 + 6m + y (104 + 22m) Note: m: Number of wait states inserted in external memory access. Values in parentheses are for the LDM instruction. 112 23 + x (61) 23 + y (97 + 16m) 43 + 10m + x (81 + 10m) 43 + 10m + y (117 + 26m) Section 6 Data Transfer Controller 6.1 Overview The H8/534 and H8/536 include a data transfer controller (DTC) that can be started by designated interrupts to transfer data from a source address to a destination address located in page 0. These addresses include in particular the registers of the on-chip supporting modules and I/O ports. Typical uses of the DTC are to change the setting of a control register of an on-chip supporting module in response to an interrupt from that module, or to transfer data from memory to an I/O port or the serial communication interface. Once set up, the transfer is interrupt-driven, so it proceeds independently of program execution, although program execution temporarily stops while each byte or word is being transferred. 6.1.1 Features The main features of the DTC are listed below. • The source address and destination address can be set anywhere in the 64-kbyte address space of page 0. • The DTC can be programmed to transfer one byte or one word of data per interrupt. • The DTC can be programmed to increment the source address and/or destination address after each byte or word is transferred. • After transferring a designated number of bytes or words, the DTC generates a CPU interrupt with the vector of the interrupt source that started the DTC. • This designated data transfer count can be set from 1 to 65,536 bytes or words. 6.1.2 Block Diagram Figure 6-1 shows a block diagram of the DTC. The four DTC control registers (DTMR, DTSR, DTDR, and DTCR) are invisible to the CPU, but corresponding information is kept in a register information table in memory. A separate table is maintained for each DTC interrupt type. When an interrupt requests DTC service, the DTC loads its control registers from the table in memory, transfers the byte or word of data, and writes any altered register information back to memory. 113 Internal data bus DTC request RAM Interrupt controller IRQ 0 DTEA IRQ 1 DTEB Register information table 0 DTC Register information table 1 DTEC DTMR DTED DTSR DTEE DTDR DTEF DTCR DTMR: DT Mode Register DTSR: DT Source Address Register DTDR: DT Destination Address Register DTCR: DT Count Register DTEA to DTEF: DT Enable Register A to D Figure 6-1 Block Diagram of Data Transfer Controller 6.1.3 Register Configuration The four DTC control registers are listed in table 6-1. These registers are not located in the address space and cannot be written or read by the CPU. To set information in these registers, a program must write the information in a table in memory from which it will be loaded by the DTC. Table 6-1 Internal Control Registers of the DTC Name Data transfer mode register Data transfer source address register Data transfer destination address register Data transfer count register Abbreviation DTMR DTSR DTDR DTCR 114 Read/Write Disabled Disabled Disabled Disabled Starting of the DTC is controlled by the six data transfer enable registers, which are located in high addresses in page 0. Table 6-2 lists these registers. Table 6-2 Data Transfer Enable Registers Name Data transfer enable register A Data transfer enable register B Data transfer enable register C Data transfer enable register D Data transfer enable register E Data transfer enable register F Abbreviation DTEA DTEB DTEC DTED DTEE DTEF Read/Write R/W R/W R/W R/W R/W R/W Address H'FF08 H'FF09 H'FF0A H'FF0B H'FF0C H'FF0D Initial Value H'00 H'00 H'00 H'00 H'00 H'00 6.2 Register Descriptions 6.2.1 Data Transfer Mode Register (DTMR) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Sz SI DI — — — — — — — — — — — — — Read/Write — — — — — — — — — — — — — — — — The data transfer mode register is a 16-bit register, the first three bits of which designate the data size and specify whether to increment the source and destination addresses. Bit 15—Sz (Size): This bit designates the size of the data transferred. Bit 15 Sz Description 0 Byte transfer 1 Word transfer* (two bytes at a time) * For word transfer, the source and destination addresses must be even addresses. Bit 14—SI (Source Increment): This bit specifies whether to increment the source address. Bit 14 SI 0 1 Description Source address is not incremented. 1) If Sz = 0: Source address is incremented by +1 after each data transfer. 2) If Sz = 1: Source address is incremented by +2 after each data transfer. 115 Bit 13—DI (Destination Increment): This bit specifies whether to increment the destination address. Bit 13 DI 0 1 Description Destination address is not incremented. 1) If Sz = 0: Destination address is incremented by +1 after each data transfer. 2) If Sz = 1: Destination address is incremented by +2 after each data transfer. Bits 12 to 0—Reserved Bits: These bits are reserved. 6.2.2 Data Transfer Source Address Register (DTSR) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Read/Write — — — — — — — — — — — — — — — — The data transfer source register is a 16-bit register that designates the data transfer source address. For word transfer this must be an even address. In the maximum mode, this address is implicitly located in page 0. 6.2.3 Data Transfer Destination Register (DTDR) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Read/Write — — — — — — — — — — — — — — — — The data transfer destination register is a 16-bit register that designates the data transfer destination address. For word transfer this must be an even address. In the maximum mode, this address is implicitly located in page 0. 6.2.4 Data Transfer Count Register (DTCR) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Read/Write — — — — — — — — — — — — — — — — 116 The data transfer count register is a 16-bit register that counts the number of bytes or words of data remaining to be transferred. The initial count can be set from 1 to 65,536. A register value of 0 designates an initial count of 65,536. The data transfer count register is decremented automatically after each byte or word is transferred. When its value reaches 0, indicating that the designated number of bytes or words have been transferred, a CPU interrupt is generated with the vector of the interrupt that requested the data transfer. 6.2.5 Data Transfer Enable Registers A to F (DTEA to DTEF) These six registers designate whether an interrupt starts the DTC. The bits in these registers are assigned to interrupts as indicated in table 6-3. No bits are assigned to the NMI, FOVI, OVI, and ERI interrupts, which cannot request data transfers. Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Table 6-3 Assignment of Data Transfer Enable Registers Interrupt Source or Register Module Bits 7 to 4 7 6 DTEA IRQ0 — — — 5 — 4 IRQ0 Interrupt Source or Module Bits 3 to 0 3 2 IRQ1 — — IRQ3 IRQ2 IRQ4, IRQ5 — — 1 — 0 IRQ1 IRQ5 IRQ4 DTEB IRQ2, IRQ3 — DTEC 16-Bit FRT1 — OCIB1 OCIA1 ICI1 16-Bit FRT2 — DTED 16-Bit FRT3 — OCIB3 OCIA3 ICI3 8-Bit Timer — — DTEE SCI1 — TXI1 RXI1 — SCI2 — TXI2 RXI2 — DTEF A/D converter — — — ADI — — — — OCIB2 OCIA2 ICI2 CMIB CMIA Note: Bits marked “—” should always be cleared to 0. If the bit for a certain interrupt is set to 1, that interrupt is regarded as a request for DTC service. If the bit is cleared to 0, the interrupt is regarded as a CPU interrupt request. 117 Only the interrupts indicated in table 6-3 can request DTC service. DTE bits not assigned to any interrupt (indicated by “—” in table 6-3) should be left cleared to 0. • Note on Timing of DTE Modifications: The interrupt controller requires two system clock (ø) periods to determine the priority level of an interrupt. Accordingly, when an instruction modifies a data transfer enable register, the new setting does not take effect until the third state after taht instruction has been executed. 6.3 Data Transfer Operation 6.3.1 Data Transfer Cycle When started by an interrupt, the DTC executes the following data transfer cycle: 1. From the DTC vector table, the DTC reads the address at which the register information table for that interrupt is located in memory. 2. The DTC loads the data transfer mode register and source address register from this table and reads the data (one byte or word) from the source address. 3. If so specified in the mode register, the DTC increments the source address register and writes the new source address back to the table in memory. 4. The DTC loads the data transfer destination address register and writes the byte or word of data to the destination address. 5. If so specified in the mode register, the DTC increments the destination address register and writes the new destination address back to the table in memory. 6. The DTC loads the data transfer count register from the table in memory, decrements the data count, and writes the new count back to memory. 7. If the data transfer count is now 0, the DTC generates a CPU interrupt. The interrupt vector is the vector of the interrupt type that started the DTC. At an appropriate point during this procedure the DTC also clears the interrupt request by clearing the corresponding flag bit in the status register of the on-chip supporting module to 0. But the DTC does not clear the data transfer enable bit in the data transfer enable register. This action, if necessary, must be taken by the user-coded interrupt-handling routine invoked at the end of the transfer. The data transfer cycle is shown in a flowchart in figure 6-2. For the steps from the occurrence of the interrupt up to the start of the data transfer cycle, see section 5.4.1, “Interrupt Handling Flow.” 118 INT Interrupt CPU N DTC interrupt? Y DTC Save PC and SR Read DTC vector Read vector Read transfer mode Read address from vector table Read source address Read data N Start executing interrupt-handling routine at that address. Y Source address increment mode? Increment source address (+1 or +2) Write source address Read destination address Write data Destination address increment mode? N Y Increment destination address (+1 or +2) Write destination address Read DTCR DTCR – 1 → DTCR Write DTCR Y DTCR = 0? N DTC END Figure 6-2 Flowchart of Data Transfer Cycle 119 6.3.2 DTC Vector Table The DTC vector table is located immediately following the exception vector table at the beginning of page 0 in memory. For each interrupt that can request DTC service, the DTC vector table provides a pointer to an address in memory where the table of DTC control register information for that interrupt is stored. The register information tables can be placed in any available locations in page 0. RAM Vector table DTMR0 Exception vector table TA0 Register information table 0 DTSR0 DTDR0 DTCR0 DTMR1 TA0 TA1 TA1 Register information table 1 DTSR1 DTDR1 DTCR1 DTC vector table Note: TA0, TA1, ...: Addresses of DTC register information tables in memory. Note: TA 0 , TA1,... : Addresses of DTC register information tables in memory. Normally the register information tables are placed on RAM. If software does not need to modify the register information (addresses are fixed and transfer count is 1), it can be placed on ROM. Figure 6-3 DTC Vector Table In minimum mode, each entry in the DTC vector table consists of two bytes, pointing to an address in page 0. In maximum mode, for compatibility reasons, each DTC vector table entry consists of four bytes but the first two bytes are ignored; the last two bytes point to an address which is implicitly assumed to be in page 0, regardless of the current page specifications. Figure 6-4 shows one DTC vector table entry in minimum and maximum mode. 120 RAM DTC vector table DTC vector table Address Address m Address (H) m+1 Address (L) Register information (1) Minimum mode Don’t care 2m* Don’t care 2 m + 1* Address (H) 2m+2 Address (L) 2m+3 (2) Maximum mode * Address 2m and 2m + 1 are not accessed at vector read. Figure 6-4 DTC Vector Table Entry Table 6-4 lists the addresses of the entries in the DTC vector table for each interrupt. Table 6-4 Addresses of DTC Vectors Interrupt IRQ0 Interval timer IRQ1 IRQ2 IRQ3 IRQ4 IRQ5 FRT1 FRT2 FRT3 ICI OCIA OCIB ICI OCIA OCIB ICI OCIA OCIB Fig. 6-4 Address of DTC Vector Minimum Mode Maximum Mode H'00C0 - H'00C1 H'0180 - H'0183 H'00C2 - H'00C3 H'0184 - H'0187 H'00C8 - H'00C9 H'0190 - H'0193 H'00D0 - H'00D1 H'01A0 - H'01A3 H'00D2 - H'00D3 H'01A4 - H'01A7 H'00D8 - H'00D9 H'01B0 - H'01B3 H'00DA - H'00DB H'01B4 - H'01B7 H'00E0 - H'00E1 H'01C0 - H'01C3 H'00E2 - H'00E3 H'01C4 - H'01C7 H'00E4 - H'00E5 H'01C8 - H'01CB H'00E8 - H'00E9 H'01D0 - H'01D3 H'00EA - H'00EB H'01D4 - H'01D7 H'00EC - H'00ED H'01D8 - H'01DB H'00F0 - H'00F1 H'01E0 - H'01E3 H'00F2 - H'00F3 H'01E4 - H'01E7 H'00F4 - H'00F5 H'01E8 - H'01EB 121 Table 6-4 Addresses of DTC Vectors (cont) Interrupt 8-Bit timer SCI1 SCI2 A/D converter CMIA CMIB RXI TXI RXI TXI ADI Address of DTC Vector Minimum Mode Maximum Mode H'00F8 - H'00F9 H'01F0 - H'01F3 H'00FA - H'00FB H'01F4 - H'01F7 H'00A2 - H'00A3 H'0144 - H'0147 H'00A4 - H'00A5 H'0148 - H'014B H'00AA - H'00AB H'0154 - H'0157 H'00AC - H'00AD H'0158 - H'015B H'00B0 - H'00B1 H'0160 - H'0163 6.3.3 Location of Register Information in Memory For each interrupt, the DTC control register information is stored in four consecutive words in memory in the order shown in figure 6-5. DTC vector table RAM TA DTMR Mode register TA + 2 DTSR Source address register TA + 4 DTDR Destination address register TA + 6 DTCR 8 Bits 8 Bits Count register Figure 6-5 Order of Register Information 6.3.4 Length of Data Transfer Cycle Table 6-5 lists the number of states requiredFig. per6-5 data transfer, assuming that the DTC control register information is stored in on-chip RAM. This is the number of states required for loading and saving the DTC control registers and transferring one byte or word of data. Two cases are considered: a transfer between on-chip RAM and a register belonging to an I/O port or on-chip supporting module (i.e., a register in the register field from addresses H'FE80 to H'FFFF); and a transfer between such a register and external RAM. 122 Table 6-5 Number of States per Data Transfer Increment Mode Source Destina(SI) tion (DI) 0 0 0 1 1 0 1 1 On-Chip RAM ↔Module or I/O Register Byte Transfer Word Transfer 31 34 33 36 33 36 35 38 External RAM ↔ Module or I/O Register Byte Transfer Word Transfer 32 38 34 40 34 40 36 42 Note: Numbers in the table are the number of states. The values in table 6-5 are calculated from the formula: N = 26 + 2 × SI + 2 × DI + MS + MD Where MS and MD have the following meanings: MS: Number of states for reading source data MD: Number of states for writing destination data The values of MS and MD depend on the data location as follows: ➀ Byte or word data in on-chip RAM: ➩ 2 states ➁ Byte data in external RAM or register field: ➩ 3 states ➂ Word data in external RAM or register field: ➩ 6 states If the DTC control register information is stored in external RAM, 20 + 4 × SI + 4 × DI must be added to the values in table 6-5. The values given above do not include the time between the occurrence of the interrupt request and the starting of the DTC. This time includes two states for the interrupt controller to check priority and a variable wait until the end of the current CPU instruction. At maximum, this time equals the sum of the values indicated for items No. 1 and 2 in table 6-6. If the data transfer count is 0 at the end of a data transfer cycle, the number of states from the end of the data transfer cycle until the first instruction of the user-coded interrupt-handling routine is executed is the value given for item No. 3 in table 6-6. 123 Table 6-6 Number of States before Interrupt Service No. Reason for Wait 1 Interrupt priority decision and comparison with mask level in CPU status register 2 Maximum number of Instruction is in on-chip states to completion memory of current instruction Instruction is in external memory 3 Saving of PC and SR Stack is in on-chip RAM or PC, CP, and SR and instruction prefetch Stack is in external memory Number of States Minimum Mode Maximum Mode 2 states 38 (LDM instruction specifying all registers) 74 + 16m (LDM instruction specifying all registers) 16 21 28 + 6m 41 + 10m m: Number of wait states inserted in external memory access 6.4 Procedure for Using the DTC A program that uses the DTC to transfer data must do the following: 1. Set the appropriate DTMR, DTSR, DTDR, and DTCR register information in the memory location indicated in the DTC vector table. 2. Set the data transfer enable bit of the pertinent interrupt to 1, and set the priority of the interrupt source (in the interrupt priority register) and the interrupt mask level (in the CPU status register) so that the interrupt can be accepted. 3. Set the interrupt enable bit in the control register for the interrupt source (or set the IRQ enable bit). Following these preparations, the DTC will be started each time the interrupt occurs. When the number of bytes or words designated by the DTCR value have been transferred, after transferring the last byte or word, the DTC generates a CPU interrupt. The user-coded interrupt-handling routine must take action to prepare for or disable further DTC data transfer: by readjusting the data transfer count, for example, or clearing the interrupt enable bit. If no action is taken, the next interrupt of the same type will start the DTC with an initial data transfer count of 65,536. 124 6.5 Example Purpose: To receive 128 bytes of serial data the serial communication interface 1. Conditions: • • • • Operating mode: Minimum mode Received data are to be stored in consecutive addresses starting at H'FC00. DTC control register information for the RXI interrupt is stored at addresses H'FB80 to H'FB87. Accordingly, the DTC vector table contains H'FB at address H'00A2 and H'80 at address H'00A3. • The desired interrupt mask level in the CPU status register is 4, and the desired SCI1 interrupt priority level is 5. Procedure 1. The user program sets DTC control register information in addresses H'FB80 to H'FB87 as shown in table 6-7. Table 6-7 DTC Control Register Information Set in RAM Address Register H'FB80 DTMR H'FB82 H'FB84 H'FB86 DTSR DTDR DTCR Description Byte transfer Source address fixed Increment destination address Address of SCI1 receive data register Address H'FC00 Number of bytes to be received: 128 Value Set H'2000 H'FEDD H'FC00 H'0080 2. The program sets the RI (SCI1 Receive Interrupt) bit in the data transfer enable register (bit 5 of register DTEE) to 1. 3. The program sets the interrupt mask in the CPU status register to 4, and the SCI1 interrupt priority in bits 6 to 4 of interrupt priority register IPRE to 5. 4. The program sets SCI1 to the appropriate receive mode, and sets the receive interrupt enable (RIE) bit in the serial control register (SCR) to 1 to enable receive interrupts. 5. Thereafter, each time SCI1 receives one byte of data, it requests an RXI interrupt, which the interrupt controller directs toward the DTC. The DTC transfers the byte from the SCI’s receive data register (RDR) into RAM, and clears the interrupt request before ending. 125 6. When 128 bytes have been transferred (DTCR = 0), the DTC generates a CPU interrupt. The interrupt type is RXI from SCI1. 7. The user-coded RXI interrupt-handling routine processes the received data and disables further data transfer (by clearing the RIE bit, for example). Figure 6-6 shows the DTC vector table and data in RAM for this example. DTC vector table Address RAM Address H'FB80 H'20 H'FB81 H'00 Mode H'00A2 H'FB H'00A3 H'80 H'FE Source address H'DD H'FC Destination address H'00 H'00 Counter H'FB87 H'80 H'FC00 Receive data 1 Receive data 2 Transferred by DTC H'FC7F Receive data 128 RDR SCI Figure 6-6 Use of DTC to Receive Data via Serial Communication Interface 1 126 Section 7 Wait-State Controller 7.1 Overview To simplify interfacing to low-speed external devices, the H8/534 and H8/536 have an on-chip wait-state controller (WSC) that can insert wait states (TW) to prolong bus cycles. The wait-state function can be used in CPU and DTC access cycles to external addresses. It is not used in access to on-chip supporting modules. The TW states are inserted between the T2 state and T3 state in the bus cycle. The number of wait states can be selected by a value set in the waitstate control register (WCR), or by holding the WAIT pin Low for the required interval. 7.1.1 Features The main features of the wait-state controller are: • Selection of three operating modes Programmable wait mode, pin wait mode, or pin auto-wait mode • 0, 1, 2, or 3 wait states can be inserted. And in the pin wait mode, 4 or more states can be inserted by holding the WAIT pin Low. 127 7.1.2 Block Diagram Figure 7-1 shows a block diagram of the wait-state controller. Internal data bus WCR — — — — WMS1 WMS0 WC1 WC0 Wait counter WAIT request Control logic WAIT input WCR: Wait-state Control Register WMS1, 0: Wait Mode Select 1, 0 WC1, 0: Wait Count 1, 0 Figure 7-1 Block Diagram of Wait-State Controller Fig. 7-1 7.1.3 Register Configuration The wait-state controller has one control register: the wait-state control register described in table 7-1. Table 7-1 Register Configuration Name Wait-state control register Abbreviation WCR Read/Write R/W 128 Initial Value H'F3 Address H'FF10 7.2 Wait-State Control Register The wait-state control register (WCR) is an 8-bit register that specifies the wait mode and the number of wait states to be inserted. A reset initializes the WCR to specify the programmable wait mode with three wait states. The WCR is not initialized in the software standby mode. Bit 7 6 5 4 3 2 1 0 — — — — WMS1 WMS0 WC1 WC0 Initial value 1 1 1 1 0 0 1 1 Read/Write — — — — R/W R/W R/W R/W Bits 7 to 4—Reserved: These bits cannot be modified and are always read as 1. Bits 3 and 2—Wait Mode Select 1 and 0 (WMS1 and WMS0): These bits select the wait mode as shown below. Bit 3 WMS1 0 0 1 1 Bit 2 WMS0 0 1 0 1 Description Programmable wait mode (Initial value) No wait states are inserted, regardless of the wait count. Pin wait mode Pin auto-wait mode Bits 1 and 0—Wait Count (WC1 and WC0): These bits specify the number of wait states to be inserted. Wait states are inserted only in bus cycles in which the CPU or DTC accesses an external address. Bit 1 WC1 0 0 1 1 Bit 0 WC0 0 1 0 1 Description No wait states are inserted, except in pin wait mode. 1 Wait state is inserted. 2 Wait states are inserted. 3 Wait states are inserted. (Initial value) 129 7.3 Operation in Each Wait Mode Table 7-2 summarizes the operation of the three wait modes. Table 7-2 Wait Modes Mode Programmable wait mode WMS1 = 0 WMS0 = 0 Pin wait mode WMS1 = 1 WMS0 = 0 Pin auto-wait mode WMS1 = 1 WMS0 = 1 WAIT Insertion Pin Function Conditions Disabled Inserted on access to an off-chip address Enabled Enabled Number of Wait States Inserted 1 to 3 wait states are inserted, as specified by bits WC0 and WC1. Inserted on access to 0 to 3 wait states are inserted, as an off-chip address specified by bits WC0 and WC1, plus additional wait states while the WAIT pin is held Low. Inserted on access to 1 to 3 wait states are inserted, as an off-chip address if specified by bits WC0 and WC1. the WAIT pin is Low 7.3.1 Programmable Wait Mode The programmable wait mode is selected when WMS1 = 0 and WMS0 = 0. Whenever the CPU or DTC accesses an off-chip address, the number of wait states set in bits WC1 and WC0 are inserted. The WAIT pin is not used for wait control; it is available as an I/O pin. 130 Figure 7-2 shows the timing of the operation in this mode when the wait count is 1 (WC1 = 0, WC0 = 1). T2 state or T3 T1 T2 TW T3 ø Off-chip address A19 –A 0 RD, AS, DS (Read) Read data Read data D7 –D0 WR, DS (Write) Write data D7 –D0 Figure 7-2 Programmable Wait Mode 7.3.2 Pin Wait Mode The pin wait mode is selected when WMS1 = 1 and WMS0 = 0. Fig. 7-2 In this mode the WAIT function of the P14 /WAIT pin is used automatically. The number of wait states indicated by bits WC1 and WC0 are inserted into any bus cycle in which the CPU or DTC accesses an off-chip address. In addition, wait states continue to be inserted as long as the WAIT pin is held low. In particular, if the wait count is 0 but the WAIT pin is Low at the rising edge of the ø clock in the T2 state, wait states are inserted until the WAIT pin goes High. This mode is useful for inserting four or more wait states, or when different external devices require different numbers of wait states. 131 Figure 7-3 shows the timing of the operation in this mode when the wait count is 1 (WC1 = 0, WC0 = 1) and the WAIT pin is held Low to insert one additional wait state. T1 T2 Wait count TW WAIT pin TW * ø T3 * WAIT pin A19 –A 0 Off-chip address RD, AS, DS (Read) Read data D7 –D0 WR, DS (Write) D7 –D0 Write data * The arrowheads indicate the times at which the WAIT pin is sampled. Figure 7-3 Pin Wait Mode Fig. 7-3 132 7.3.3 Pin Auto-Wait Mode The pin auto-wait mode is selected when WMS1 = 1 and WMS0 = 1. In this mode the WAIT function of the P14 /WAIT pin is used automatically. In this mode, the number of wait states indicated by bits WC1 and WC0 are inserted, but only if there is a Low input at the WAIT pin. Figure 7-4 shows the timing of this operation when the wait count is 1. In the pin auto-wait mode, the WAIT pin is sampled only once, on the falling edge of the ø clock in the T2 state. If the WAIT pin is Low at this time, the wait-state controller inserts the number of wait states indicated by bits WC1 and WC0. The WAIT pin is not sampled during the Tw and T3 states, so no additional wait states are inserted even if the WAIT pin continues to be held Low. This mode offers a simple way to interface a low-speed device: the wait states can be inserted by routing a decoded address signal to the WAIT pin. T1 ø T2 T3 T1 * T2 TW T3 * WAIT A19 –A 0 External address External address RD, AS, DS (Read) Read data Read data D7 –D0 WR, DS (Write) D7 –D0 Write data Write data * The arrowheads indicate the times at which the WAIT pin is sampled. Figure 7-4 Pin Auto-Wait Mode Fig. 7-4 133 Section 8 Clock Pulse Generator 8.1 Overview The H8/534 and H8/536 have a built-in clock pulse generator (CPG) consisting of an oscillator circuit, a system (ø) clock divider, an E clock divider, and a group of prescalers. The prescalers generate clock signals for the on-chip supporting modules. 8.1.1 Block Diagram CPG Prescalers XTAL EXTAL Oscillator circuit Divider ÷2 Divider ÷8 ø E ø/2 to ø/4096 Figure 8-1 Block Diagram of Clock Pulse Generator 8.2 Oscillator Circuit If an external crystal is connected across the EXTAL and XTAL pins, the on-chip oscillator circuit generates a clock signal for the system clock divider. Alternatively, an external clock signal can be applied to the EXTAL pin. Connecting an External Crystal (1) Circuit Configuration: An external crystal can be connected as in the example in figure 8-2. An AT-cut parallel resonating crystal should be used. 135 CL1 EXTAL XTAL CL2 CL1 =C L2 =10 to 22pF Figure 8-2 Connection of Crystal Oscillator (Example) (2) Crystal Oscillator: The external crystal should have the characteristics listed in table 8-1. CL L RS XTAL EXTAL C0 AT-cut parallel resonating crystal Figure 8-3 Crystal Oscillator Equivalent Circuit Table 8-1 (1) External Crystal Parameters (HD6475368R, HD6475348R, HD6435368R, HD6435348R) Frequency (MHz) 2 4 8 Rs max (Ω) 500 120 60 C0 (pF) 7pF max Fig. 8-3 12 16 20 40 30 20 Table 8-1 (2) External Crystal Parameters (HD6475368S, HD6475348S, HD6435368S, HD6435348S) Frequency (MHz) 4 8 12 16 20 24 Rs max (Ω) 120 80 60 50 40 40 C0 (pF) 7pF max Note: Use a fundamental-mode crystal (not an overtone crystal). (3) Note on Board Design: When an external crystal is connected, other signal lines should be kept away from the crystal circuit to prevent induction from interfering with correct oscillation. See figure 8-4. When the board is designed, the crystal and its load capacitors should be placed as close as possible to the XTAL and EXTAL pins. 136 Not allowed Signal A Signal B H8/534 H8/536 CL2 XTAL EXTAL CL1 Figure 8-4 Notes on Board Design around External Crystal Input of External Clock Signal (1) Circuit Configuration (HD6475368R, HD6475348R, HD6435368R, HD6435348R): When using an external clock, input complementary clock signals to the EXTAL and XTAL pins as shown in figure 8-5. Make sure the external clock does not go high during standby mode. EXTAL 74HC04 External clock input XTAL Figure 8-5 External Clock Input (Example) (2) External Clock Input Fig. 8-5 Frequency Double the system clock (ø) frequency Duty cycle 45% to 55% Note: Mask-ROM versions can operate on external clock input to the EXTAL pin alone, with the XTAL pin left open. ZTAT versions can also operate with the XTAL pin left open if the external clock frequency is 16 MHz or less. 137 (3) Circuit Configuration (HD6475368S, HD6475348S, HD6435368S, HD6435348S): Figure 8-6 shows examples of external clock input. When using figure 8-6 (b), make sure the external clock does not go high during standby mode. When the XTAL pin is open, make sure the parasitic capacifance is less than 10 pF. EXTAL External clock input XTAL Open (a) XTAL pin left open EXTAL External clock input 74HC04 XTAL (b) Complementary clock input at XTAL pin Figure 8-6 External Clock Input (Examples) (4) External Clock Input Frequency Double the system clock (ø) frequency Duty cycle 40% to 60% 138 8.3 System Clock Divider The system clock divider divides the crystal oscillator or external clock frequency (fosc) by 2 to create the ø clock. An E clock signal is created by dividing the ø clock by 8. The E clock is used for interfacing to E clock based devices. Figure 8-7 shows the phase relationship of the E clock to the ø clock. ø E Figure 8-7 Phase Relationship of ø Clock and E Clock 139 Section 9 I/O Ports 9.1 Overview The H8/534 and H8/536 have nine ports. Ports 1, 3, 4, 5, 7, and 9 are eight-bit input/output ports. Port 2 is a five-bit input/output port. Port 6 is a four-bit input/output port. Port 8 is an eight-bit input-only port. Table 9-1 summarizes the functions of each port. Input and output are memory-mapped. The CPU views each port as a data register (DR) located in the register field at the high end of page 0 of the address space. Each port (except port 8) also has a data direction register (DDR) which determines which pins are used for input and which for output. Additional system control registers (SYSCR1 and SYSCR2) control the functions of pins in ports 1, 6, and 9. To read data from an I/O port, the CPU selects input in the data direction register and reads the data register. This causes the input logic level at the pin to be placed directly on the internal data bus. There is no intervening input latch. To send data to an output port, the CPU selects output in the data direction register and writes the desired data in the data register, causing the data to be held in a latch. The latch output drives the pin through a buffer amplifier. If the CPU reads the data register of an output port, it obtains the data held in the latch rather than the actual level of the pin. As table 9-1 indicates, all of the I/O port pins have dual functions. For example, pin 7 of port 1 can be used either as a general-purpose I/O pin (P17), or for output of the TMO signal from the on-chip 8-bit timer. The function is determined by the MCU operating mode, or by a value set in a control register. Outputs from ports 1 to 6 can drive one TTL load and a 90 pF capacitive load. Outputs from ports 7 and 9 can drive one TTL load and a 30 pF capacitive load. Outputs from ports 1 to 7 and 9 can also drive a Darlington transistor pair. Outputs from port 4 can drive a light-emitting diode (with 10mA current sink). Ports 5 and 6 have built-in MOS pullups for each input. Port 7 has Schmitt inputs. Schematic diagrams of the I/O port circuits are shown in appendix C. 141 Table 9-1 Input/Output Port Summary Port Description Pins Port 1 8-Bit input/output P17 / TMO P16 / IRQ1 / ADTRG P15 / IRQ0 P14 / WAIT P13 / BREQ P12 / BACK P11 / E P10 / ø Port 2 5-Bit input/output P24 / WR port P23 / RD P22 / DS P21 / R/W P20 / AS Port 3 8-Bit input/output P37 - P30 / port D7 – D0 Port 4 8-Bit input/output P47 – P40 / port A7 – A0 Can drive a LED Port 5 8-Bit input/output P57 – P50 / port A15 – A8 Built-in input pull-up (MOS) Expanded Modes Single-Chip Mode Mode 1 Mode 2 Mode 3 Mode 4 (Mode 7) These input/output pins double as IRQ1, IRQ0, and ADTRG inputs, and as an output pin (TMO) for the 8-bit timer. These pins function as WAIT, BREQ, and BACK when necessary controlregister bits are set to 1. These pins function as input pins or as clock (E, ø) output pins, depending on the data direction register setting. Bus control signal outputs (WR, RD, DS, R/W, AS) Data bus (D7 – D0) 142 High address bus (A15 – A8) Page address bus (A19 – A16) Input/output port Input/output port Input/output port Low address bus (A7 – A0) High High address address bus bus if (A15 – DDR is A8) set to 1 Port 6 4-Bit input/output P63 / PW3 / Output for PWM port IRQ5 / A19 timers 1, 2, and Built-in input P62 / PW2 / 3, input for IRQ2 pull-up (MOS) IRQ4 / A18 to IRQ5, and P61 / PW1 / input/output port. IRQ3 / A17 P60 / IRQ2 / A16 Input/output port High address bus if DDR is set to 1 Page address bus if DDR is set to 1, input port and IRQ2 to IRQ5 input pins if DDR is set to 0 Input/output port Input/output port Table 9-1 Input/Output Port Summary (cont) Port Description Port 7 8-Bit input/output port (Schmitt inputs) Pins P77 / FTOA1 P76 / FTOB3 / FTCI3 P75 / FTOB2 / FTCI2 P74 / FTOB1 / FTCI1 / P73 / FTI3 TMRI P72 / FTI2 P71 / FTI1 P70 / TMCI Port 8 8-Bit input port P80 – P87 AN7 – AN0 Port 9 8-Bit input/output P97 / SCK1 port P96 / RXD1 P95 / TXD1 P94 / SCK2 / PW3 P93 / RXD2 / PW2 P92 / TXD2 / PW1 P91 / FTOA3 P90 / FTOA2 Expanded Modes Single-Chip Mode Mode 1 Mode 2 Mode 3 Mode 4 (Mode 7) Input/output for free-running timers 1, 2 and 3 (FTI1 to FTI3, FTCI1 to FTCI3, FTOB1 to FTOB3, FTOA1),input for 8-bit timer input (TMCI, TMRI), and 8-bit input/output port (P77 to P70) Analog input pins for A/D converter, and 8-bit input port Output for free-running timers 2 and 3 (FTOA2, FTOA3), PWM timer output (PW1, PW2, PW3), serial communication interface (SCI1 and SCI2) input/output (SCK1, RXD1, TXD1, SCK2, RXD2, TXD2), and 8-bit input/output port 143 9.2 Port 1 9.2.1 Overview Port 1 is an 8-bit input/output port with the pin configuration shown in figure 9-1. All pins have dual functions, except that in the single-chip mode pins 4, 3, and 2 do not have the WAIT, BREQ, and BACK functions (because the CPU does not access an external bus). Outputs from port 1 can drive one TTL load and a 90 pF capacitive load. They can also drive a Darlington transistor pair. Port 1 Pin P17 / TMO P16 / IRQ1 / ADTRG P15 / IRQ0 P14 / WAIT P13 / BREQ P12 / BACK P11 / E P10 / ø Expanded Modes P17 (input/output) / TMO (output) P16 (input/output) / IRQ1 (input) / ADTRG (input) P15 (input/output) / IRQ0 (input) P14 (input/output) / WAIT (input) P13 (input/output) / BREQ (input) P12 (input/output) / BACK (output) P11 (input) / E (output) P10 (input) / ø (output) Single-Chip Mode P17 (input/output) / TMO (output) P16 (input/output) / IRQ1 (input) / ADTRG (input) P15 (input/output) / IRQ0 (input) P14 (input/output) P13 (input/output) P12 (input/output) P11 (input) / E (output) P10 (input) / ø (output) Figure 9-1 Pin Functions of Port 1 9.2.2 Port 1 Registers Register Configuration: Table 9-2 lists the registers of port 1. Table 9-2 Port 1 Registers Name Port 1 data direction register Port 1 data register System control register 1 Abbreviation P1DDR P1DR SYSCR1 Read/Write W R/W*1 R/W *1 Bits 1 and 0 are read-only. *2 Bits 1 and 0 are undetermined. Other bits are initialized to 0. 144 Initial Value H'03 Undetermined*2 H'87 Address H'FE80 H'FE82 H'FEFC 1. Port 1 Data Direction Register (P1DDR)—H'FE80 Bit 7 6 5 4 3 2 1 0 P17DDR P16DDR P15DDR P14DDR P13DDR P12DDR P11DDR P10DDR Initial value 0 0 0 0 0 0 1 1 Read/Write W W W W W W W W P1DDR is an 8-bit register that selects the direction of each pin in port 1. A pin functions as an output pin if the corresponding bit in P1DDR is set to 1, and as an input pin if the bit is cleared to 0. P1DDR can be written but not read. An attempt to read this register does not cause an error, but all bits are read as 1, regardless of their true values. A reset initializes P1DDR to H'03, so that pins P11 and P10 carry clock outputs and the other pins are set for input. In the hardware standby mode, P1DDR is cleared to H'00, stopping the clock outputs. P1DDR is not initialized in the software standby mode, so if a P1DDR bit is set to 1 when the chip enters the software standby mode, the corresponding pin continues to output the value in the port 1 data register (or the ø or E clock). 2. Port 1 Data Register (P1DR)—H'FE82 Bit 7 6 5 4 3 2 1 0 P17 P16 P15 P14 P13 P12 P11 P10 Initial value 0 0 0 0 0 0 — — Read/Write R/W R/W R/W R/W R/W R/W R R P1DR is an 8-bit register containing the data for pins P17 to P10. When the CPU reads P1DR, for output pins it reads the value in the P1DR latch, but for input pins, it obtains the pin status directly. Note that when pins P11 and P10 are used for output, they output the clock signals (ø and E), not the contents of P1DR. If the CPU reads Pl1 and Pl0 (when Pl1DDR = Pl0DDR = 1), it obtains the clock values at the current instant. 3. System Control Register 1 (SYSCR1)—H'FEFC Bit 7 6 5 4 3 2 1 0 — IRQ1E IRQ0E NMIEG BRLE — — — Initial value 1 0 0 0 0 1 1 1 Read/Write — R/W R/W R/W R/W — — — 145 SYSCR1 selects the functions of four of the port 1 pins. It also selects the input edge of the NMI pin. At a reset and in the hardware standby mode, SYSCR1 is initialized to H'87. It is not initialized in the software standby mode. Bit 7—Reserved: This bit cannot be modified and is always read as 1. Bit 6—Interrupt Request 1 Enable (IRQ1E): This bit selects the function of pin P16. Bit 6 IRQ1E 0 1 Description P16 functions as an input/output pin. (Initial value) P16 functions as the IRQ1 input pin, regardless of the value set in P16DDR. (However, the CPU can still read the pin status by reading P1DR.) Bit 5—Interrupt Request 0 Enable (IRQ0E): This bit selects the function of pin P15. Bit 5 IRQ0E 0 1 Description P15 functions as an input/output pin. (Initial value) P15 functions as the IRQ0 input pin, regardless of the value set in P15DDR. (However, the CPU can still read the pin status by reading P1DR.) Bit 4—Nonmaskable Interrupt Edge (NMIEG): This bit selects the input edge of the NMI pin. It is not related to port 0. Bit 4 NMIEG 0 1 Description A nonmaskable interrupt is generated on the falling edge of the input at the NMI pin. A nonmaskable interrupt is generated on the rising edge of the input at the NMI pin. (Initial value) Bit 3—Bus Release Enable (BRLE): This bit selects the functions of pins P12 and P13. It is valid only in the expanded modes (modes 1, 2, 3, and 4). In the single-chip mode, pins P12 and P13 function as input/output pins regardless of the value of the BRLE bit. 146 Bit 3 BRLE 0 1 Description P13 and P12 function as input/output pins. (Initial value) P13 functions as the BREQ input pin. P12 functions as the BACK output pin. Bits 2 to 0—Reserved: These bits cannot be modified and are always read as 1. 9.2.3 Pin Functions in Each Mode Port 1 operates differently in the expanded modes (modes 1, 2, 3, and 4) and the single-chip mode (mode 7). Table 9-3 explains how the pin functions are selected in the expanded mode. Table 9-4 explains how the pin functions are selected in the single-chip mode. Table 9-3 Port 1 Pin Functions in Expanded Modes Pin Selection of Pin Functions P17 / TMO The function depends on output select bits 3 to 0 (OS3 to OS0) of the 8-bit timer control/status register (TCSR) and on the P17DDR bit as follows: OS3 to OS0 P17DDR Pin function All four bits are 0 0 1 P17 input P17 output At least one bit is 1 0 1 TMO output P16 / IRQ1 / The function depends on the IRQ1E bit and the trigger enable bit (TRGE) ADTRG in the A/D control register (ADCR) as follows: IRQ1E 0 1 TRGE 0 1 0 1 Pin function P16 input/ ADTRG IRQ1 input IRQ1 and output input ADTRG input When used for P16 input/output, the input or output function is selected by P16DDR. P15 / IRQ0 The function depends on the IRQ0E bit and the P15DDR bit as follows: IRQ0E P15DDR Pin function 0 0 P15 input 1 1 P15 output 147 0 1 IRQ0 input Table 9-3 Port 1 Pin Functions in Expanded Modes (cont) Pin P14 / WAIT Selection of Pin Functions The function depends on the wait mode select 1 bit (WMS1) of the wait-state control register (WCR) and the P14DDR bit as follows: WMS1 P14DDR Pin function P13 / BREQ 1 1 P14 output 0 1 WAIT input The function depends on the BRLE bit and the P13DDR bit as follows: BRLE P13DDR Pin function P12 / BACK 0 0 P14 input 0 0 P13 input 1 P13 output 1 0 1 BREQ input The function depends on the BRLE bit and the P12DDR bit as follows: BRLE P12DDR Pin function 0 P12 input 0 P11DDR Pin function 0 Input 1 E clock output P10DDR Pin function 0 Input 1 ø clock output 1 P12 output P11 / E P10 / ø 148 1 0 1 BACK output Table 9-4 Port 1 Pin Functions in Single-Chip Modes Pin P17 / TMO Selection of Pin Functions The function depends on output select bits 3 to 0 (OS3 to OS0) of the 8-bit timer control/status register (TCSR) and on the P17DDR bit as follows: OS3 to OS0 P17DDR Pin function P16 / IRQ1 / ADTRG All four bits are 0 0 1 P17 input P17 output At least one bit is 1 0 1 TMO output The function depends on the IRQ1E bit and the trigger enable bit (TRGE) in the A/D control register (ADCR) as follows: IRQ1E 0 1 TRGE 0 1 0 1 Pin function P16 input/ ADTRG IRQ1 input IRQ1 and output input ADTRG input When used for P16 input/output, the input or output function is selected by P16DDR. P15 / IRQ0 The function depends on the IRQ0E bit and the P15DDR bit as follows: IRQ0E P15DDR Pin function 0 P15 input 0 1 P14DDR Pin function 0 Input 1 Output P13DDR Pin function 0 Input 1 Output 1 P15 output P14 P13 149 0 1 IRQ0 input Table 9-4 Port 1 Pin Functions in Single-Chip Modes (cont) Pin P12 Selection of Pin Functions P12DDR Pin function 0 Input 1 Output P11DDR Pin function 0 Input 1 E clock output P10DDR Pin function 0 Input 1 ø clock output P11 / E P10 / ø 9.3 Port 2 9.3.1 Overview Port 2 is a five-bit input/output port with the pin configuration shown in figure 9-2. It functions as an input/output port only in the single-chip mode. In the expanded modes it is used for output of bus control signals. Outputs from port 2 can drive one TTL load and a 90 pF capacitive load. They can also drive a Darlington transistor pair. Port 2 Pin P24 / WR P23 / RD P22 / DS P21 / R/W P20 / AS Expanded Modes WR (output) RD (output) DS (output) R/W (output) AS (output) Single-Chip Mode P24 (input/output) P23 (input/output) P22 (input/output) P21 (input/output) P20 (input/output) Figure 9-2 Pin Functions of Port 2 150 9.3.2 Port 2 Registers Register Configuration: Table 9-5 lists the registers of port 2. Table 9-5 Port 2 Registers Name Port 2 data direction register Port 2 data register Abbreviation P2DDR P2DR Read/Write W R/W Initial Value H'E0 H'E0 Address H'FE81 H'FE83 1. Port 2 Data Direction Register (P2DDR)—H'FE81 Bit 7 6 5 4 3 2 1 0 — — — Initial value 1 1 1 0 0 0 0 0 Read/Write — — — W W W W W P24DDR P23DDR P22DDR P21DDR P20DDR P2DDR is an 8-bit register that selects the direction of each pin in port 2. Single-Chip Mode: A pin functions as an output pin if the corresponding bit in P2DDR is set to 1, and as an input pin if the bit is cleared to 0. Bits 4 to 0 can be written but not read. An attempt to read this register does not cause an error, but all bits are read as 1, regardless of their true values. Bits 7 to 5 are reserved. They cannot be modified and are always read as 1. At a reset and in the hardware standby mode, P2DDR is initialized to H'E0, making all five pins input pins. P2DDR is not initialized in the software standby mode, so if a P2DDR bit is set to 1 when the chip enters the software standby mode, the corresponding pin continues to output the value in the port 2 data register. Expanded Modes: All bits of P2DDR are fixed at 1 and cannot be modified. 151 2. Port 2 Data Register (P2DR)—H'FE83 Bit 7 6 5 4 3 2 1 0 — — — P24 P23 P22 P21 P20 Initial value 1 1 1 0 0 0 0 0 Read/Write — — — R/W R/W R/W R/W R/W P2DR is an 8-bit register containing the data for pins P24 to P20. Bits 7 to 5 are reserved. They cannot be modified and are always read as 1. When the CPU reads P2DR, for output pins it reads the value in the P2DR latch, but for input pins, it obtains the pin status directly. 9.3.3 Pin Functions in Each Mode Port 2 has different functions in the expanded modes (modes 1, 2, 3, 4) and the single-chip mode (mode 7). Separate descriptions are given below. Pin Functions in Expanded Modes: In the expanded modes (modes 1, 2, 3, and 4), all pins of P2DDR is automatically set to 1 for output. Port 2 outputs the bus control signals (AS, R/W, DS, RD, WR). Figure 9-3 shows the pin functions in the expanded modes. Port 2 WR RD DS R/W AS (output) (output) (output) (output) (output) Figure 9-3 Port 2 Pin Functions in Expanded Modes 152 Pin Functions in Single-Chip Mode: In the single-chip mode (mode 7), each of the port 2 pins can be designated as an input pin or an output pin, as indicated in figure 9-4, by setting the corresponding bit in P2DDR to 1 for output or clearing it to 0 for input. Port 2 P24 P23 P22 P21 P20 (input/output) (input/output) (input/output) (input/output) (input/output) Figure 9-4 Port 2 Pin Functions in Single-Chip Mode 9.4 Port 3 9.4.1 Overview Port 3 is an 8-bit input/output port with the pin configuration shown in figure 9-5. In the expanded modes it operates as the external data bus (D7 – D0). In the single-chip mode it operates as a general-purpose input/output port. Outputs from port 3 can drive one TTL load and a 90pF capacitive load. They can also drive a Darlington transistor pair. Port 3 Pin P37 / D7 P36 / D6 P35 / D5 P34 / D4 P33 / D3 P32 / D2 P31 / D1 P30 / D0 Expanded Modes D7 (input/output) D6 (input/output) D5 (input/output) D4 (input/output) D3 (input/output) D2 (input/output) D1 (input/output) D0 (input/output) Single-Chip Mode P37 (input/output) P36 (input/output) P35 (input/output) P34 (input/output) P33 (input/output) P32 (input/output) P31 (input/output) P30 (input/output) Figure 9-5 Pin Functions of Port 3 153 9.4.2 Port 3 Registers Register Configuration: Table 9-6 lists the registers of port 3. Table 9-6 Port 3 Registers Name Port 3 data direction register Port 3 data register Abbreviation P3DDR P3DR Read/Write W R/W Initial Value H'00 H'00 Address H'FE84 H'FE86 1. Port 3 Data Direction Register (P3DDR)—H'FE84 Bit 7 6 5 4 3 2 1 0 P37DDR P36DDR P35DDR P34DDR P33DDR P32DDR P31DDR P30DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W P3DDR is an 8-bit register that selects the direction of each pin in port 3. Single-Chip Mode: A pin functions as an output pin if the corresponding bit in P3DDR is set to 1, and as an input pin if the bit is cleared to 0. P3DDR can be written but not read. An attempt to read this register does not cause an error, but all bits are read as 1, regardless of their true values. At a reset and in the hardware standby mode, P3DDR is initialized to H'00, making all eight pins input pins. P3DDR is not initialized in the software standby mode, so if a P3DDR bit is set to 1 when the chip enters the software standby mode, the corresponding pin continues to output the value in the port 3 data register. Expanded Modes: P3DDR is not used. 154 2. Port 3 Data Register (P3DR)—H'FE86 Bit 7 6 5 4 3 2 1 0 P37 P36 P35 P34 P33 P32 P31 P30 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W P3DR is an 8-bit register containing the data for pins P37 to P30. At a reset and in the hardware standby mode, P3DR is initialized to H'00. When the CPU reads P3DR, for output pins it reads the value in the P3DR latch, but for input pins, it obtains the pin status directly. 9.4.3 Pin Functions in Each Mode Port 3 has different functions in the expanded modes (modes 1, 2, 3, 4) and the single-chip mode (mode 7). Separate descriptions are given below. Pin Functions in Expanded Modes: In the expanded modes (modes 1, 2, 3, and 4), port 3 is automatically used as the data bus and P3DDR is ignored. Figure 9-6 shows the pin functions for the expanded modes. Port 3 D7 D6 D5 D4 D3 D2 D1 D0 (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) Figure 9-6 Port 3 Pin Functions in Expanded Modes 155 Pin Functions in Single-Chip Mode: In the single-chip mode (mode 7), each of the port 3 pins can be designated as an input pin or an output pin, as indicated in figure 9-7, by setting the corresponding bit in P3DDR to 1 for output or clearing it to 0 for input. Port 3 P37 P36 P35 P34 P33 P32 P31 P30 (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) Figure 9-7 Port 3 Pin Functions in Single-Chip Mode 9.5 Port 4 9.5.1 Overview Port 4 is an 8-bit input/output port with the pin configuration shown in figure 9-8. In the expanded modes it provides the low bits (A7 – A0) of the address bus. In the single-chip mode it operates as a general-purpose input/output port. Outputs from port 4 can drive one TTL load and a 90 pF capacitive load. They can also drive a Darlington transistor pair or LED (with 10 mA current sink). Port 4 Pin P47 / A7 P46 / A6 P45 / A5 P44 / A4 P43 / A3 P42 / A2 P41 / A1 P40 / A0 Expanded Modes A7 (output) A6 (output) A5 (output) A4 (output) A3 (output) A2 (output) A1 (output) A0 (output) Single-Chip Mode P47 (input/output) P46 (input/output) P45 (input/output) P44 (input/output) P43 (input/output) P42 (input/output) P41 (input/output) P40 (input/output) Figure 9-8 Pin Functions of Port 4 156 9.5.2 Port 4 Registers Register Configuration: Table 9-7 lists the registers of port 4. Table 9-7 Port 4 Registers Name Port 4 data direction register Port 4 data register Abbreviation P4DDR P4DR Read/Write W R/W Initial Value H'00 H'00 Address H'FE85 H'FE87 1. Port 4 Data Direction Register (P4DDR)—H'FE85 Bit 7 6 5 4 3 2 1 0 P47DDR P46DDR P45DDR P44DDR P43DDR P42DDR P41DDR P40DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W P4DDR is an 8-bit register that selects the direction of each pin in port 4. Single-Chip Mode: A pin functions as an output pin if the corresponding bit in P4DDR is set to 1, and as in input pin if the bit is cleared to 0. P4DDR can be written but not read. An attempt to read this register does not cause an error, but all bits are read as 1, regardless of their true values. At a reset and in the hardware standby mode, P4DDR is initialized to H'00, making all eight pins input pins. P4DDR is not initialized in the software standby mode, so if a P4DDR bit is set to 1 when the chip enters the software standby mode, the corresponding pin continues to output the value in the port 4 data register. Expanded Modes: All bits of P4DDR are fixed at 1 and cannot be modified. 157 2. Port 4 Data Register (P4DR)—H'FE87 Bit 7 6 5 4 3 2 1 0 P47 P46 P45 P44 P43 P42 P41 P40 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W P4DR is an 8-bit register containing the data for pins P47 to P40. At a reset and in the hardware standby mode, P4DR is initialized to H'00. When the CPU reads P4DR, for output pins it reads the value in the P4DR latch, but for input pins, it obtains the pin status directly. 9.5.3 Pin Functions in Each Mode Port 4 has different functions in the expanded modes (modes 1, 2, 3, 4) and the single-chip mode (mode 7). Separate descriptions are given below. Pin Functions in Expanded Modes: In the expanded modes (modes 1, 2, 3, and 4), port 4 is used for output of the low bits (A7 – A0) of the address bus. P4DDR is automatically set for output. Figure 9-9 shows the pin functions for the expanded modes. Port 4 A7 A6 A5 A4 A3 A2 A1 A0 (output) (output) (output) (output) (output) (output) (output) (output) Figure 9-9 Port 4 Pin Functions in Expanded Modes Pin Functions in Single-Chip Mode: In the single-chip mode (mode 7), each of the port 4 pins can be designated as an input pin or an output pin, as indicated in figure 9-10, by setting the corresponding bit in P4DDR to 1 for output or clearing it to 0 for input. 158 Port 4 P47 P46 P45 P44 P43 P42 P41 P40 (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) Figure 9-10 Port 4 Pin Functions in Single-Chip Mode 9.6 Port 5 9.6.1 Overview Port 5 is an 8-bit input/output port with the pin configuration shown in figure 9-11. In the expanded modes that use the on-chip ROM (modes 2 and 4), the pins of port 5 function either as general-purpose input pins or as bits A15 – A8 of the address bus, depending on the port 5 data direction register (P5DDR). Port 5 has built-in MOS pull-ups that can be turned on or off under program control. Outputs from port 5 can drive one TTL load and a 90 pF capacitive load. They can also drive a Darlington transistor pair. Port 5 Pin P57 / A15 P56 / A14 P55 / A13 P54 / A12 P53 / A11 P52 / A10 P51 / A9 P50 / A8 Modes 1 and 3 A15 (output) A14 (output) A13 (output) A12 (output) A11 (output) A10 (output) A9 (output) A8 (output) Modes 2 and 4 P57 (input) / A15 (output) P56 (input) / A14 (output) P55 (input) / A13 (output) P54 (input) / A12 (output) P53 (input) / A11 (output) P52 (input) / A10 (output) P51 (input) / A9 (output) P50 (input) / A8 (output) Figure 9-11 Pin Functions of Port 5 159 Single-Chip Mode P57 (input/output) P56 (input/output) P55 (input/output) P54 (input/output) P53 (input/output) P52 (input/output) P51 (input/output) P50 (input/output) 9.6.2 Port 5 Registers Register Configuration: Table 9-8 lists the registers of port 5. Table 9-8 Port 5 Registers Name Port 5 data direction register Port 5 data register Abbreviation P5DDR P5DR Read/Write W R/W Initial Value H'00 H'00 Address H'FE88 H'FE8A 1. Port 5 Data Direction Register (P5DDR)—H'FE88 Bit 7 6 5 4 3 2 1 0 P57DDR P56DDR P55DDR P54DDR P53DDR P52DDR P51DDR P50DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W P5DDR is an 8-bit register that selects the direction of each pin in port 5. Single-Chip Mode: A pin functions as an output pin if the corresponding bit in P5DDR is set to 1, and as an input pin if the bit is cleared to 0. P5DDR can be written but not read. An attempt to read this register does not cause an error, but all bits are read as 1, regardless of their true values. At a reset and in the hardware standby mode, P5DDR is initialized to H'00, making all eight pins input pins. P5DDR is not initialized in the software standby mode, so if a P5DDR bit is set to 1 when the chip enters the software standby mode, the corresponding pin continues to output the value in the port 5 data register. Expanded Modes Using On-Chip ROM (Modes 2 and 4): If a 1 is set in P5DDR, the corresponding pin is used for address output. If a 0 is set in P5DDR, the pin is used for generalpurpose input. P5DDR is initialized to H'00 at a reset and in the hardware standby mode. Expanded Modes Not Using On-Chip ROM (Modes 1 and 3): All bits of P5DDR are fixed at 1 and cannot be modified. Port 5 is used for address output. 160 Port 5 Data Register (P5DR)—H'FE8A Bit 7 6 5 4 3 2 1 0 P57 P56 P55 P54 P53 P52 P51 P50 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W P5DR is an 8-bit register containing the data for pins P57 to P50. At a reset and in the hardware standby mode, P5DR is initialized to H'00. When the CPU reads P5DR, for output pins it reads the value in the P5DR latch, but for input pins, it obtains the pin status directly. 9.6.3 Pin Functions in Each Mode Port 5 operates in one way in modes 1 and 3, in another way in modes 2 and 4, and in a third way in mode 7. Separate descriptions are given below. Pin Functions in Modes 1 and 3: In modes 1 and 3 (expanded modes in which the on-chip ROM is not used), all bits of P5DDR are automatically set to 1 for output, and the pins of port 5 carry bits A15 – A8 of the address bus. Figure 9-12 shows the pin functions for modes 1 and 3. Port 5 A15 A14 A13 A12 A11 A10 A9 A8 (output) (output) (output) (output) (output) (output) (output) (output) Figure 9-12 Port 5 Pin Functions in Modes 1 and 3 161 Pin Functions in Modes 2 and 4: In modes 2 and 4, (expanded modes in which the on-chip ROM is used), software can select whether to use port 5 for general-purpose input, or for output of bits A15 – A8 of the address bus. If a bit in P5DDR is set to 1, the corresponding pin is used for address output. If the bit is cleared to 0, the pin is used for input. A reset clears all P5DDR bits to 0, so before the address bus is used, all necessary bits in P5DDR must be set to 1. Figure 9-13 shows the pin functions in modes 2 and 4. Port 5 When P5DDR Bit is Set to “1” A15 (output) A14 (output) A13 (output) A12 (output) A11 (output) A10 (output) A9 (output) A8 (output) When P5DDR Bit is Cleared to “0” P57 (input) P56 (input) P55 (input) P54 (input) P53 (input) P52 (input) P51 (input) P50 (input) Figure 9-13 Port 5 Pin Functions in Modes 2 and 4 Pin Functions in Single-Chip Mode: In the single-chip mode (mode 7), each of the port 5 pins can be designated as an input pin or an output pin, as indicated in figure 9-14, by setting the corresponding bit in P5DDR to 1 for output or clearing it to 0 for input. Port 5 P57 P56 P55 P54 P53 P52 P51 P50 (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) (input/output) Figure 9-14 Port 5 Pin Functions in Single-Chip Mode 162 9.6.4 Built-In MOS Pull-Up The MOS input pull-ups of port 5 are turned on by clearing the corresponding bit in P5DDR to 0 and writing a 1 in P5DR. These pull-ups are turned off at a reset and in the hardware standby mode. Table 9-9 indicates the status of the MOS pull-ups in various modes. Table 9-9 Status of MOS Pull-Ups for Port 5 Mode Reset Hardware Standby Mode 1 OFF OFF 2 3 4 7 * Including the software standby mode. Notation: OFF: ON/OFF: Other Operating States* OFF ON/OFF OFF ON/OFF The MOS pull-up is always off. The MOS pull-up is on when P5DDR = 0 and P5DR = 1, and off otherwise. Note on Usage of MOS Pull-Ups If the bit manipulation instructions listed below are executed on input/output ports 5 and 6 which have selectable MOS pull-ups, the logic levels at input pins will be transferred to the DR latches, causing the MOS pull-ups to be unintentionally switched on or off. This can occur with the following bit manipulation instructions: BSET, BCLR, BNOT (1) Specific Example (BSET Instruction): An example will be shown in which the BSET instruction is executed for port 5 under the following conditions: P57: Input pin, low, MOS pull-up transistor on P56: Input pin, high, MOS pull-up transistor off P55 – P50: Output pins, low The intended purpose of this BSET instruction is to switch the output level at P50 from low to high. 163 A: Before Execution of BSET Instruction Input/output Pin state DDR DR Pull-up P57 Input Low 0 1 On P56 Input High 0 0 Off P55 Output Low 1 0 Off P54 Output Low 1 0 Off P53 Output Low 1 0 Off P52 Output Low 1 0 Off P51 Output Low 1 0 Off P50 Output Low 1 0 Off P51 Output Low 1 0 Off P50 Output High 1 1 Off B: Execution of BSET Instruction BSET.B #0 ;set bit 0 in data register @PORT5 C: After Execution of BSET Instruction Input/output Pin state DDR DR Pull-up P57 Input Low 0 0 Off P56 Input High 0 1 On P55 Output Low 1 0 Off P54 Output Low 1 0 Off P53 Output Low 1 0 Off P52 Output Low 1 0 Off Explanation: To execute the BSET instruction, the CPU begins by reading port 5. Since P57 and P56 are input pins, the CPU reads the level of these pins directly, not the value in the data register. It reads P57 as low (0) and P56 as high (1). Since P55 to P50 are output pins, for these pins the CPU reads the value in the data register (0). The CPU therefore reads the value of port 5 as H'40, although the actual value in P5DR is H'80. Next the CPU sets bit 0 of the read data to 1, changing the value to H'41. Finally, the CPU writes this value (H'41) back to P5DR to complete the BSET instruction. As a result, bit P50 is set to 1, switching pin P50 to high output. In addition, bits P57 and P56 are both modified, changing the on/off settings of the MOS pull-up transistors of pins P57 and P56. Programming Solution: The switching of the pull-ups for P57 and P56 in the preceding example can be avoided by using a byte in RAM as a work area for P5DR, performing bit manipulations on the work area, then writing the result to P5DR. 164 A: Before Execution of BSET Instruction MOV.B MOV.B MOV.B #80, R0 R0, @RAM0 R0, @PORT5 P57 Input Low 0 1 On 1 Input/output Pin state DDR DR Pull-up RAM0 P56 Input High 0 0 Off 0 ;write data (H'80) for data register ;write to work area (RAM0) ;write to P5DR P55 Output Low 1 0 Off 0 P54 Output Low 1 0 Off 0 P53 Output Low 1 0 Off 0 P52 Output Low 1 0 Off 0 P51 Output Low 1 0 Off 0 P50 Output Low 1 0 Off 0 P51 Output Low 1 0 Off 0 P50 Output High 1 1 Off 0 B: Execution of BSET Instruction BSET.B #0, @RAM0 ;set bit 0 in work area (RAM0) C: After Execution of BSET Instruction MOV.B MOV.B @RAM0, R0 R0, @PORT5 Input/output Pin state DDR DR Pull-up RAM0 P57 Input Low 0 1 On 1 P56 Input High 0 0 Off 0 ;get value in work area (RAM0) ;write value to P5DR P55 Output Low 1 0 Off 0 P54 Output Low 1 0 Off 0 P53 Output Low 1 0 Off 0 P52 Output Low 1 0 Off 0 9.7 Port 6 9.7.1 Overview Port 6 is a 4-bit input/output port with the pin configuration shown in figure 9-15. In modes 7, 2, and 1, port 6 is used for IRQ2 to IRQ5 input and PWM timer output. In mode 4, port 6 is used for IRQ2 to IRQ5 input and page address output. In mode 3, port 6 is used for page address output. Port 6 has built-in MOS pull-ups that can be turned on or off under program control. Outputs from port 6 can drive one TTL load and a 90 pF capacitive load. They can also drive a Darlington transistor pair. 165 Port 6 Pin Mode 3 Mode 4 P63 / PW3 / IRQ5 / A19 A19 (output) P63 (input) / IRQ5 (input) / A19 (output) P62 / PW2 / IRQ4 / A18 A18 (output) P62 (input) / IRQ4 (input) / A18 (output) P61 / PW1 / IRQ3 / A17 A17 (output) P61 (input) / IRQ3 (input) / A17 (output) P60 / IRQ2 / A16 A16 (output) P60 (input) / IRQ2 (input) / A16 (output) Mode 1 and 2 and Single-Chip Mode P63 (input/output) / IRQ5 (input) / PW3 (output) P62 (input/output) / IRQ4 (input) / PW2 (output) P61 (input/output) / IRQ3 (input) / PW1 (output) P60 (input/output) / IRQ2 (input) Figure 9-15 Pin Functions of Port 6 9.7.2 Port 6 Registers Register Configuration: Table 9-10 lists the registers of port 6. Table 9-10 Port 6 Registers Name Port 6 data direction register Port 6 data register System control register 2 Abbreviation P6DDR P6DR SYSCR2 Read/Write W R/W R/W Initial Value H'F0 H'F0 H'80 Address H'FE89 H'FE8B H'FEFD 1. Port 6 Data Direction Register (P6DDR)—H'FE89 Bit 7 6 5 4 3 2 1 0 — — — — Initial value 1 1 1 1 0 0 0 0 Read/Write — — — — W W W W P63DDR P62DDR P61DDR P60DDR P6DDR is an 8-bit register that selects the direction of each pin in port 6. Single-Chip Mode and Expanded Minimum Modes: A pin functions as an output pin if the corresponding bit in P6DDR is set to 1, and as in input pin if the bit is cleared to 0. Bits 7 to 4 are reserved. They cannot be modified and are always read as 1. 166 Bits 3 to 0 can be written but not read. An attempt to read these bits does not cause an error, but all bits are read as 1, regardless of their true values. At a reset and in the hardware standby mode, P6DDR is initialized to H'F0, making all four pins input pins. P6DDR is not initialized in the software standby mode. In the single-chip mode, if a P6DDR bit is set to 1 when the chip enters the software standby mode, the corresponding pin continues to output the value in the port 6 data register. Expanded Maximum Mode Using On-Chip ROM (Mode 4): If a 1 is set in P6DDR, the corresponding pin is used for address output. If a 0 is set in P6DDR, the pin is used for input. P6DDR is initialized to H'F0 at a reset and in the hardware standby mode. Expanded Maximum Mode Not Using On-Chip ROM (Mode 3): All bits of P6DDR are fixed at 1 and cannot be modified. 2. Port 6 Data Register (P6DR)—H'FE8B Bit 7 6 5 4 3 2 1 0 — — — — P63 P62 P61 P60 Initial value 1 1 1 1 0 0 0 0 Read/Write — — — — R/W R/W R/W R/W P6DR is an 8-bit register containing data for pins P63 to P60. Bits 7 to 4 are reserved. They cannot be modified and are always read as 1. At a reset and in the hardware standby mode, P6DR is initialized to H'F0. When the CPU reads P6DR, for output pins it reads the value in the P6DR latch, but for input pins, it obtains the pin status directly. 3. System Control Register 2 (SYSCR2)—H'FEFD Bit 7 6 5 4 — IRQ5E IRQ4E IRQ3E Initial value 1 0 0 0 0 0 0 0 Read/Write — R/W R/W R/W R/W R/W R/W R/W 167 3 2 1 0 IRQ2E P6PWME P9PWME P9SCI2E SYSCR2 controls the functions of port 6 and the functions of some pins in port 9. SYSCR2 is initialized to H'80 by a reset and in the hardware standby mode. It is not initialized in the software standby mode. Bit 7—Reserved: This bit cannot be modified and is always read as 1. Bit 6—Interrupt Request 5 Enable (IRQ5E): Selects the function of pin P63. Bit 6 IRQ5E 0 1 Description P63 functions as an input/output pin (but as the PW3 output pin (Initial value) if P6PWME and the OE bit of PWM timer 3 are both set to 1). P63 is the IRQ5 input pin regardless of the value of P63DDR (although the logic level of the pin can still be read). Bit 5—Interrupt Request 4 Enable (IRQ4E): Selects the function of pin P62. Bit 5 IRQ4E 0 1 Description P62 functions as an input/output pin (but as the PW2 output (Initial value) pin if P6PWME and the OE bit of PWM timer 2 are both set to 1). P62 is the IRQ4 input pin regardless of the value of P62DDR (although the logic level of the pin can still be read). Bit 4—Interrupt Request 3 Enable (IRQ3E): Selects the function of pin P61. Bit 4 IRQ3E 0 1 Description P61 functions as an input/output pin (but as the PW1 output (Initial value) pin if P6PWME and the OE bit of PWM timer 1 are both set to 1). P61 is the IRQ3 input pin regardless of the value of P61DDR (although the logic level of the pin can still be read). Bit 3—Interrupt Request 2 Enable (IRQ2E): Selects the function of pin P60. Bit 3 IRQ2E 0 1 Description P60 functions as an input/output pin. (Initial value) P60 is the IRQ2 input pin regardless of the value of P60DDR (although the logic level of the pin can still be read). 168 Bit 2—Port 6 PWM Enable (P6PWME): Controls pin functions of port 6. Bit 2 P6PWME Description 0 P63 to P61 function as input/output pins (Initial value) (or as IRQ input pins when bits IRQ5E to IRQ3E are set to 1). 1 P63 to P61 function as PWM output pins if the corresponding OE bit of PWM3 to PWM1 is set to 1. If the OE bit is cleared to 0 or the IRQE bit is set to 1, the pin functions as an input/output pin. Bit 1—Port 9 PWM Enable (P9PWME): Controls pin functions of port 9. Bit 1 P9PWME Description 0 The PWM functions of P94 to P92 are disabled. (Initial value) (See section 9.10.3, “Pin Functions.”) 1 The PWM functions of P94 to P92 are enabled. (See section 9.10.3, “Pin Functions.”) Bit 0—Port 9 SCI2 Enable (P9PWME): Controls pin functions of port 9. Bit 1 P9SCI2E Description 0 The serial communication interface functions of P94 to P92 (Initial value) are disabled. (See section 9.10.3, “Pin Functions.”) 1 The serial communication interface functions of P94 to P92 are enabled. (See section 9.10.3, “Pin Functions.”) 169 9.7.3 Pin Functions in Each Mode The usage of port 6 depends on the MCU operating mode. Separate descriptions are given below. Pin Functions in Mode 3: In mode 3 (the expanded maximum mode in which the on-chip ROM is not used), P6DDR is automatically set for output, and the pins of port 6 carry the page address bits (A19 – A16) of the address bus. Figure 9-16 shows the pin functions for mode 3. Port 6 A19 A18 A17 A16 (output) (output) (output) (output) Figure 9-16 Port 6 Pin Functions in Mode 3 Pin Functions in Mode 4: In mode 4, (the expanded maximum mode in which the on-chip ROM is used), software can select whether to use port 6 for general-purpose input, IRQ2 to IRQ5 input, or output of page address bits. If a bit in P6DDR is set to 1, the corresponding pin is used for page address output. If the P6DDR bit is cleared to 0 and the corresponding IRQnE bit is cleared to 0, the pin is used for generalpurpose input. If the P6DDR bit is cleared to 0 and the corresponding IRQnE bit is set to 1, the pin is used for IRQ2 to IRQ5 input. A reset initializes these pins to the general-purpose input function, so when the address bus is used, all necessary bits in P6DDR must first be set to 1. Figure 9-17 shows the pin functions in mode 4. Port 6 When P6DDR Bit is Set to 1 A19 (output) A18 (output) A17 (output) A16 (output) When P6DDR Bit is Cleared to 0 IRQnE = 0 IRQnE = 1 P63 (input) IRQ5 P62 (input) IRQ4 P61 (input) IRQ3 P60 (input) IRQ2 Figure 9-17 Port 6 Pin Functions in Mode 4 Pin Functions in Single-Chip Mode and Expanded Minimum Modes: In the single-chip mode (mode 7) and expanded minimum modes (modes 1 and 2), the port 6 pins can be designated individually as input or output pins. Port 6 can be used for general-purpose input/output, IRQ input, or PWM output, depending on the combination of settings of the IRQE and P6PWME bits in system control register 2 and the OE 170 bits of the three PWM timers. Figure 9-18 shows the pin functions in modes 7, 2, and 1. Port 6 P63 P62 P61 P60 (input/output) / IRQ5 / PW3 (input/output) / IRQ4 / PW2 (input/output) / IRQ3 / PW1 (input/output) / IRQ2 Figure 9-18 Port 6 Pin Functions in Modes 7, 2, and 1 Table 9-11 Port 6 Pin Functions in Modes 7, 2, and 1 Pin P63 / IRQ5 / PW3 Selection of Pin Functions The function depends on the interrupt request 5 enable bit (IRQ5E) and port 6 PWM enable bit (P6PWME) in system control register 2 (SYSCR2), and the output enable bit (OE) of PWM timer 3. IRQ5E 0 1 P6PWME 0 1 0 1 OE 0 1 0 1 0 1 0 1 Pin function P63 input/output PW3 output IRQ5 input IRQ5 input When used for P63 input/output, the input or output function is selected by P63DDR. P62 / IRQ4 / PW2 The function depends on the interrupt request 4 enable bit (IRQ4E) and P6PWME bit in SYSCR2, and the OE bit of PWM timer 2. 0 1 IRQ4E P6PWME 0 1 0 1 OE 0 1 0 1 0 1 0 1 Pin function P62 input/output PW2 output IRQ4 input IRQ4 input When used for P62 input/output, the input or output function is selected by P62DDR. 171 Table 9-11 Port 6 Pin Functions in Modes 7, 2, and 1 (cont) Pin P61 / IRQ3 / PW1 Selection of Pin Functions The function depends on the interrupt request 3 enable bit (IRQ3E) and P6PWME bit in SYSCR2, and the OE bit of PWM timer 1. 0 1 IRQ3E P6PWME 0 1 0 1 OE 0 1 0 1 0 1 0 1 Pin function P61 input/output PW1 output IRQ3 input IRQ3 input When used for P61 input/output, the input or output function is selected by P61DDR. P60 / IRQ2 The function depends on the interrupt request 2 enable bit (IRQ2E) in SYSCR2. IRQ2E Pin function 0 P60 input/output 1 IRQ2 input When used for P60 input/output, the input or output function is selected by P60DDR. 9.7.4 Built-In MOS Pull-Up Port 6 has programmable MOS input pull-ups which are turned on by clearing the corresponding bit in P6DDR to 0 and writing a 1 in P6DR. These pull-ups are turned off at a reset and in the hardware standby mode. Table 9-12 indicates the status of the MOS pull-ups in various modes. Table 9-12 Status of MOS Pull-Ups for Port 5 Mode 1 2 3 4 7 Reset OFF Hardware Standby Mode OFF Other Operating States* ON/OFF OFF ON/OFF * Including software standby mode. Notation: OFF: The MOS pull-up is always off. ON/OFF: The MOS pull-up is on when P6DDR = 0 and P6DR = 1, and off otherwise. Note: When P61, P62, and P63 are used for PWM timer output, their MOS pull-ups are switched off regardless of the values in P6DDR and P6DR. 172 9.8 Port 7 9.8.1 Overview Port 7 is an 8-bit input/output port with the pin configuration shown in figure 9-19. Its pins also carry input and output signals for the on-chip free-running timers (FRT1, FRT2, and FRT3), and two input signals for the on-chip 8-bit timer. Port 7 has Schmitt inputs. Outputs from port 7 can drive one TTL load and a 30 pF capacitive load. They can also drive a Darlington transistor pair. P77 P76 P75 P74 P73 P72 P71 P70 Port 7 (input/output) / FTOA1 (output) (input/output) / FTOB3 (output) / FTCI3 (input) (input/output) / FTOB2 (output) / FTCI2 (input) (input/output) / FTOB1 (output) / FTCI1 (input) (input/output) / FTI3 (input) /TMRI (input) (input/output) / FTI2 (input) (input/output) / FTI1 (input) (input/output) / TMCI (input) Figure 9-19 Pin Functions of Port 7 9.8.2 Port 7 Registers Register Configuration: Table 9-13 lists the registers of port 7. Table 9-13 Port 7 Registers Name Port 7 data direction register Port 7 data register Abbreviation P7DDR P7DR Read/Write W R/W Initial Value H'00 H'00 Address H'FE8C H'FE8E 1. Port 7 Data Direction Register (P7DDR)—H'FE8C Bit 7 6 5 4 3 2 1 0 P77DDR P76DDR P75DDR P74DDR P73DDR P72DDR P71DDR P70DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W P7DDR is an 8-bit register that selects the direction of each pin in port 7. A pin functions as an output pin if the corresponding bit in P7DDR is set to 1, and as an input pin if the bit is cleared to 0. 173 P7DDR can be written but not read. An attempt to read this register does not cause an error, but all bits are read as 1, regardless of their true values. At a reset and in the hardware standby mode, P7DDR is initialized to H'00, setting all pins for input. P7DDR is not initialized in the software standby mode, so if a P7DDR bit is set to 1 when the chip enters the software standby mode, the corresponding pin continues to output the value in the port 7 data register. A transition to the software standby mode initializes the on-chip supporting modules, so any pins of port 7 that were being used by an on-chip timer when the transition occurs revert to generalpurpose input or output, controlled by P7DDR and P7DR. 2. Port 7 Data Register (P7DR)—H'FE8E Bit 7 6 5 4 3 2 1 0 P77 P76 P75 P74 P73 P72 P71 P70 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W P7DR is an 8-bit register containing the data for pins P77 to P70. When the CPU reads P7DR, for output pins it reads the value in the P7DR latch, but for input pins, it obtains the pin status directly. 9.8.3 Pin Functions The pin functions of port 7 are the same in all MCU operating modes. As figure 9-19 indicated, these pins are used for input and output of on-chip timer signals as well as for general-purpose input and output. For some pins, two or more functions can be enabled simultaneously. 174 Table 9-14 shows how the functions of the pins of port 7 are selected. Table 9-14 Port 7 Pin Functions Pin P77 / FTOA1 Selection of Pin Functions The function depends on the output enable A bit (OEA) of the FRT1 timer control register (TCR) and on the P77DDR bit as follows: OEA P77DDR Pin function P76 / FTOB3 / FTCI3 1 0 1 FTOA1 output 0 0 1 P76 input P76 output FTCI3 input 1 0 1 FTOB3 output The function depends on the output compare B bit (OEB) of the FRT2 timer control register (TCR) and on the P75DDR bit as follows: OEB P75DDR Pin function P74 / FTOB1 / FTCI1 1 P77 output The function depends on the output compare B bit (OEB) of the FRT3 timer control register (TCR) and on the P76DDR bit as follows: OEB P76DDR Pin function P75 / FTOB2 / FTCI2 0 0 P77 input 0 0 1 P75 input P75 output FTCI2 input 1 0 1 FTOB2 output The function depends on the output compare B bit (OEB) of the FRT1 timer control register (TCR) and on the P74DDR bit as follows: OEB P74DDR Pin function 0 0 1 P74 input P74 output FTCI1 input 175 1 0 1 FTOB1 output Table 9-14 Port 7 Pin Functions (cont) Pin P73 / FTI3 / TMRI Selection of Pin Functions The function depends on the counter clear bits 1 and 0 (CCLR1 and CCLR0) in the timer control register (TCR) of the 8-bit timer, and on the P73DDR bit as follows: The TMRI function is operative when bits CCLR0 and CCLR1 in the timer control register (TCR) of the 8-bit timer are both set to 1. P73DDR Pin function 0 1 P73 input P73 output FTI3 input and TMRI input P72DDR Pin function 0 1 P72 input P72 output FTI2 input P71DDR Pin function 0 1 P71 input P71 output FTI1 input P72 / FTI2 P71 / FTI1 P70 / TMCI This pin always has a general-purpose input/output function, and can simultaneously be used for external clock input for the 8-bit timer, depending on clock select bits 2 to 0 (CKS2, CKS1, and CKS0) in the timer control register (TCR). See section 11, “8-Bit Timer” for details. P70DDR Pin function 0 1 P70 input P70 output TMCI input 176 9.9 Port 8 9.9.1 Overview Port 8 is an 8-bit input port that also receives inputs for the on-chip A/D converter. The pin functions are the same in all MCU operating modes, as shown in figure 9-20. P87 P86 P85 P84 P83 P82 P81 P80 Port 8 (input) / AN7 (input) (input) / AN6 (input) (input) / AN5 (input) (input) / AN4 (input) (input) / AN3 (input) (input) / AN2 (input) (input) / AN1 (input) (input) / AN0 (input) Figure 9-20 Pin Functions of Port 8 9.9.2 Port 8 Registers Register Configuration: Port 8 has only the data register described in table 9-15. Since it is exclusively an input port, there is no data direction register. Table 9-15 Port 8 Registers Name Port 8 data register Abbreviation P8DR Read/Write R Address H'FE8F 1. Port 8 Data Register (P8DR)—H'FE8F Bit 7 6 5 4 3 2 1 0 P87 P86 P85 P84 P83 P82 P81 P80 Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R When the CPU reads P8DR it always reads the current status of each pin, except that during A/D conversion, the pin being used for analog input reads 1 regardless of the input voltage at that pin. 177 9.10 Port 9 9.10.1 Overview Port 9 is an 8-bit input/output port with the pin configuration shown in figure 9-21. In addition to general-purpose input and output, its pins are used for the output compare A signals from freerunning timers 2 and 3, for PWM timer output, and for input and output by the on-chip serial communication interfaces (SCI1 and SCI2). The pin functions are the same in all MCU operating modes. Outputs from port 9 can drive one TTL load and a 30 pF capacitive load. They can also drive a Darlington transistor pair. P97 P96 P95 P94 P93 P92 P91 P90 Port 9 (input/output) / SCK1 (input/output) (input/output) / RXD1 (input) (input/output) / TXD1 (output) (input/output) / SCK2 (input/output)* / PW3 (output) (input/output) / RXD2 (input)* / PW2 (output) (input/output) / TXD2 (output)* / PW1 (output) (input/output) / FTOA3 (output) (input/output) / FTOA2 (output) * The SCI2 functions of P92, P93, and P94 cannot be combined with the PWM functions. Figure 9-21 Pin Functions of Port 9 9.10.2 Port 9 Registers Register Configuration: Table 9-16 lists the registers of port 9. Table 9-16 Port 9 Registers Name Port 9 data direction register Port 9 data register Abbreviation P9DDR P9DR Read/Write W R/W 178 Initial Value H'00 H'00 Address H'FEFE H'FEFF 1. Port 9 Data Direction Register (P9DDR)—H'FEFE Bit 7 6 5 4 3 2 1 0 P97DDR P96DDR P95DDR P94DDR P93DDR P92DDR P91DDR P90DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W P9DDR is an 8-bit register that selects the direction of each pin in port 9. A pin functions as an output pin if the corresponding bit in P9DDR is set to 1, and as an input pin if the bit is cleared to 0. P9DDR can be written but not read. An attempt to read this register does not cause an error, but all bits are read as 1, regardless of their true values. At a reset and in the hardware standby mode, P9DDR is initialized to H'00, setting all pins for input. P9DDR is not initialized in the software standby mode, so if a P9DDR bit is set to 1 when the chip enters the software standby mode, the corresponding pin continues to output the value in the port 9 data register. A transition to the software standby mode initializes the on-chip supporting modules, so any pins of port 9 that were being used by an on-chip module (example: free-running timer output) when the transition occurs revert to general-purpose input or output, controlled by P9DDR and P9DR. 2. Port 9 Data Register (P9DR)—H'FEFF Bit 7 6 5 4 3 2 1 0 P97 P96 P95 P94 P93 P92 P91 P90 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W P9DR is an 8-bit register containing the data for pins P97 to P90. When the CPU reads P9DR, for output pins it reads the value in the P9DR latch, but for input pins, it obtains the pin status directly. 9.10.3 Pin Functions The pin functions of port 9 are the same in all MCU operating modes. As figure 9-21 indicated, these pins are used for output of on-chip timer signals and for input and output of serial data and clock signals as well as for general-purpose input and output. Specifically, they carry output signals for free-running timers 2 and 3, pulse-width modulation (PWM) timer output signals, and input and output signals for the serial communication interfaces. 179 Table 9-17 shows how the functions of the pins of port 9 are selected. Table 9-17 Port 9 Pin Functions Pin P97 / SCK1 Selection of Pin Functions The function depends on the communication mode bit (C/A) in the SCI1 serial mode register (SMR) and the clock enable 1 and 0 bits (CKE1 and CKE0) in the SCI1 serial control register (SCR). C/A CKE1 CKE0 0 Pin function P97 input/ output 0 1 1 0 1 1 0 1 0 1 0 1 SCI1 SCI1 external SCI1 internal SCI1 external internal clock input clock output clock input clock output When used for P97 input/output, the input or output function is selected by P97DDR. P96 / RXD1 The function depends on the receive enable bit (RE) in the SCI1 serial control register (SCR) and on the P96DDR bit as follows. RE P96DDR Pin function P95 / TXD1 0 0 0 P96 input 1 1 P96 output 0 1 RXD1 input The function depends on the transmit enable bit (TE) in SCI1’s SCR and on the P96DDR bit as follows. TE P95DDR Pin function 0 0 P95 input 1 P95 output 180 1 0 1 TXD1 output Table 9-17 Port 9 Pin Functions (cont) Pin Selection of Pin Functions P94 / SCK2 / The function depends on the output enable bit (OE) of PWM timer 3’s timer control PW3 register (TCR), the C/A bit in SCI2’s SMR, the CKE1 and CKE0 bits in SCI2’s SCR, and the port 9 PWM enable bit (P9PWME) and port 9 serial enable bit (P9SCI2E) in system control register 2 (SYSCR2). P9SCI2E P9PWME OE C/A CKE1 CKE0 Pin function 1 0 0/1 0 1 1 0 1 0 0 1 0/1 0 1 0/1 0/1 0/1 0 1 0 1 0/1 0/1 0/1 0 1 0 1 0 1 0 1 0/1 0/1 0/1 P94 SCI2 SCI2 SCI2 SCI2 P94 PW3 P94 input/ internal external internal external input/ output input/ output clock clock clock clock output output output input output input When used for P94 input/output, the input or output function is selected by P94DDR. P93 / RXD2 / The function depends on the OE bit in PWM timer 2’s TCR, the RE bit in SCI2’s PW2 SCR, and the P9PWME bit and P9SCI2E bit in SYSCR2. P9SCI2E P9PWME OE RE Pin function 1 0 0 1 0 1 0 1 0 1 0 0 0/1 0/1 1 1 0/1 0/1 0 1 0 1 0 1 P93 RXD2 P93 PW2 P93 input/ input input/ output input/ output output output When used for P93 input/output, the input or output function is selected by P93DDR. 181 Table 9-17 Port 9 Pin Functions (cont) Pin Selection of Pin Functions P92 / TXD2 / The function depends on the OE bit in PWM timer 1’s TCR, the TE bit in SCI2’s PW1 SCR, and the P9PWME bit and P9SCI2E bit in SYSCR2. P9SCI2E P9PWME OE TE Pin function 1 0 0 1 1 1 0/1 0/1 1 0 1 0 1 0 1 0 1 0 1 P92 TXD2 P92 PW1 P92 input/ output input/ output input/ output output output When used for P92 input/output, the input or output function is selected by P92DDR. P91 / FTOA3 The function depends on the output enable A bit (OEA) in FRT3’s TCR and on the P91DDR bit as follows. OEA P91DDR Pin function P90 / FTOA2 0 0 0 0/1 0/1 0 0 P91 input 1 P91 output 1 0 1 FTOA3 output The function depends on the output enable A bit (OEA) in FRT2’s TCR and on the P90DDR bit as follows. OEA P90DDR Pin function 0 0 P90 input 1 1 P90 output 182 0 1 FTOA2 output Section 10 16-Bit Free-Running Timers 10.1 Overview The H8/534 and H8/536 have an on-chip 16-bit free-running timer (FRT) module with three independent channels (FRT1, FRT2, and FRT3). All three channels are functionally identical. Each channel has a 16-bit free-running counter that it uses as a time base. Applications of the FRT module include rectangular-wave output (up to two independent waveforms per channel), input pulse width measurement, and measurement of external clock periods. 10.1.1 Features The features of the free-running timer module are listed below. • Selection of four clock sources The free-running counters can be driven by an internal clock source (ø/4, ø/8, or ø/32), or an external clock input (enabling use as an external event counter). • Two independent comparators Each free-running timer channel can generate two independent waveforms. • Input capture function The current count can be captured on the rising or falling edge (selectable) of an input signal. • Four types of interrupts Compare-match A and B, input capture, and overflow interrupts can be requested independently. The compare-match and input capture interrupts can be served by the data transfer controller (DTC), enabling interrupt-driven data transfer with minimal CPU programming. • Counter can be cleared under program control The free-running counters can be cleared on compare-match A. 183 10.1.2 Block Diagram Figure 10-1 shows a block diagram of one free-running timer channel. External clock Internal clock ø/4 ø/8 FTCI ø/32 Clock Clock select OCRA Compare-match A Comparator A Bus interface FTOA Overflow FTOB FRC Clear FTI Compare-match B Comparator B Control OCRB logic Module data bus Capture ICR TCSR TCR ICI OCIA OCIB FOVI Interrupt signals OCRA: OCRB: FRC: ICR: TCSR: TCR: Output Compare Register A Output Compare Register B Free Running Counter Input Capture Register Timer Control/Status Register Timer Control Register Figure 10-1 Block Diagram of 16-Bit Free-Running Timer 184 Internal data bus 10.1.3 Input and Output Pins Table 10-1 lists the input and output pins of the free-running timer module. Table 10-1 Input and Output Pins of Free-Running Timer Module Channel Name 1 Output compare A Output compare B or counter clock input Input capture 2 Output compare A Output compare B or counter clock input Input capture 3 Output compare A Output compare B or counter clock input Input capture Abbreviation FTOA1 FTOB1 / FTCI1 FTI1 FTOA2 FTOB2 / FTCI2 FTI2 FTOA3 FTOB3 / FTCI3 FTI3 I/O Output Output / Input Input Output Output / Input Input Output Output / Input Input 185 Function Output controlled by comparator A of FRT1 Output controlled by comparator B of FRT1, or input of external clock source for FRT1 Trigger for capturing current count of FRT1 Output controlled by comparator A of FRT2 Output controlled by comparator B of FRT2, or input of external clock source for FRT2 Trigger for capturing current count of FRT2 Output controlled by comparator A of FRT3 Output controlled by comparator B of FRT3, or input of external clock source for FRT3 Trigger for capturing current count of FRT3 10.1.4 Register Configuration Table 10-2 lists the registers of each free-running timer channel. Table 10-2 Register Configuration Channel Name Abbreviation R/W Timer control register TCR R/W Timer control/status register TCSR R/(W)* Free-running counter (High) FRC (H) R/W Free-running counter (Low) FRC (L) R/W 1 Output compare register A (High) OCRA (H) R/W Output compare register A (Low) OCRA (L) R/W Output compare register B (High) OCRB (H) R/W Output compare register B (Low) OCRB (L) R/W Input capture register (High) ICR (H) R Input capture register (Low) ICR (L) R Timer control register TCR R/W Timer control/status register TCSR R/(W)* Free-running counter (High) FRC (H) R/W Free-running counter (Low) FRC (L) R/W 2 Output compare register A (High) OCRA (H) R/W Output compare register A (Low) OCRA (L) R/W Output compare register B (High) OCRB (H) R/W Output compare register B (Low) OCRB (L) R/W Input capture register (High) ICR (H) R Input capture register (Low) ICR (L) R * Software can write a 0 to clear bits 7 to 4, but cannot write a 1 in these bits. 186 Initial Value H'00 H'00 H'00 H'00 H'FF H'FF H'FF H'FF H'00 H'00 H'00 H'00 H'00 H'00 H'FF H'FF H'FF H'FF H'00 H'00 Address H'FE90 H'FE91 H'FE92 H'FE93 H'FE94 H'FE95 H'FE96 H'FE97 H'FE98 H'FE99 H'FEA0 H'FEA1 H'FEA2 H'FEA3 H'FEA4 H'FEA5 H'FEA6 H'FEA7 H'FEA8 H'FEA9 Table 10-2 Register Configuration (cont) Channel Name Abbreviation R/W Timer control register TCR R/W Timer control/status register TCSR R/(W)* Free-running counter (High) FRC (H) R/W Free-running counter (Low) FRC (L) R/W 3 Output compare register A (High) OCRA (H) R/W Output compare register A (Low) OCRA (L) R/W Output compare register B (High) OCRB (H) R/W Output compare register B (Low) OCRB (L) R/W Input capture register (High) ICR (H) R Input capture register (Low) ICR (L) R * Software can write a 0 to clear bits 7 to 4, but cannot write a 1 in these bits. Initial Value H'00 H'00 H'00 H'00 H'FF H'FF H'FF H'FF H'00 H'00 Address H'FEB0 H'FEB1 H'FEB2 H'FEB3 H'FEB4 H'FEB5 H'FEB6 H'FEB7 H'FEB8 H'FEB9 10.2 Register Descriptions 10.2.1 Free-Running Counter (FRC)—H'FE92, H'FEA2, H'FEB2 Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Read/WriteR/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Each FRC is a 16-bit readable/writable up-counter that increments on an internal pulse generated from a clock source. The clock source is selected by the clock select 1 and 0 bits (CKS1 and CKS0) of the timer control register (TCR). The FRC can be cleared by compare-match A. When the FRC overflows from H'FFFF to H'0000, the overflow flag (OVF) in the timer control/status register (TCSR) is set to 1. Because the FRC is a 16-bit register, a temporary register (TEMP) is used when the FRC is written or read. See section 10.3, “CPU Interface” for details. The FRCs are initialized to H'0000 at a reset and in the standby modes. 187 10.2.2 Output Compare Registers A and B (OCRA and OCRB)—H'FE94 and H'FE96, H'FEA4 and H'FEA6, H'FEB4 and H'FEB6 Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Read/WriteR/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W OCRA and OCRB are 16-bit readable/writable registers, the contents of which are continually compared with the value in the FRC. When a match is detected, the corresponding output compare flag (OCFA or OCFB) is set in the timer control/status register (TCSR). In addition, if the output enable bit (OEA or OEB) in the timer control register (TCR) is set to 1, when the output compare register and FRC values match, the logic level selected by the output level bit (OLVLA or OLVLB) in the timer control status register (TCSR) is output at the output compare pin (FTOA or FTOB). The FTOA and FTOB output are 0 before the first compare-match. Because OCRA and OCRB are 16-bit registers, a temporary register (TEMP) is used when they are written. See section 10.3, “CPU Interface” for details. OCRA and OCRB are initialized to H'FFFF at a reset and in the standby modes. 10.2.3 Input Capture Register (ICR)—H'FE98, H'FEA8, H'FEB8 Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R R R R R R R R R The ICR is a 16-bit read-only register. When the rising or falling edge of the signal at the input capture input pin is detected, the current value of the FRC is copied to the ICR. At the same time, the input capture flag (ICF) in the timer control/status register (TCSR) is set to 1. The input capture edge is selected by the input edge select bit (IEDG) in the TCSR. Because the ICR is a 16-bit register, a temporary register (TEMP) is used when the ICR is written or read. See section 10.3, “CPU Interface” for details. 188 To ensure input capture, the pulse width of the input capture signal should be at least 1.5 system clock periods (1.5·ø). ø FTI Minimum FTI Pulse Width The ICR is initialized to H'0000 at a reset and in the standby modes. Note: When input capture is detected, the FRC value is transferred to the ICR even if the input capture flag (ICF) is already set. 10.2.4 Timer Control Register (TCR) Bit 7 6 5 4 3 2 1 0 ICIE OCIEB OCIEA OVIE OEB OEA CKS1 CKS0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The TCR is an 8-bit readable/writable register that selects the FRC clock source, enables the output compare signals, and enables interrupts. The TCR is initialized to H'00 at a reset and in the standby modes. Bit 7—Input Capture Interrupt Enable (ICIE): This bit selects whether to request an input capture interrupt (ICI) when the input capture flag (ICF) in the timer status/control register (TCSR) is set to 1. Bit 7 ICIE 0 1 Description The input capture interrupt request (ICI) is disabled. The input capture interrupt request (ICI) is enabled. (Initial value) Bit 6—Output Compare Interrupt Enable B (OCIEB): This bit selects whether to request output compare interrupt B (OCIB) when output compare flag B (OCFB) in the timer status/control register (TCSR) is set to 1. 189 Bit 6 OCIEB 0 1 Description Output compare interrupt request B (OCIB) is disabled. Output compare interrupt request B (OCIB) is enabled. (Initial value) Bit 5—Output Compare Interrupt Enable A (OCIEA): This bit selects whether to request output compare interrupt A (OCIA) when output compare flag A (OCFA) in the timer status/control register (TCSR) is set to 1. Bit 5 OCIEA 0 1 Description Output compare interrupt request A (OCIA) is disabled. Output compare interrupt request A (OCIA) is enabled. (Initial value) Bit 4—Timer Overflow Interrupt Enable (OVIE): This bit selects whether to request a freerunning timer overflow interrupt (FOVI) when the timer overflow flag (OVF) in the timer status/control register (TCSR) is set to 1. Bit 4 OVIE 0 1 Description The free-running timer overflow interrupt request (FOVI) is disabled. The free-running timer overflow interrupt request (FOVI) is enabled. (Initial value) Bit 3—Output Enable B (OEB): This bit selects whether to enable or disable output of the logic level selected by the OLVLB bit in the timer status/control register (TCSR) at the output compare B pin when the FRC and OCRB values match. Bit 3 OEB 0 1 Description Output compare B output is disabled. Output compare B output is enabled. (Initial value) Bit 2—Output Enable A (OEA): This bit selects whether to enable or disable output of the logic level selected by the OLVLA bit in the timer status/control register (TCSR) at the output compare A pin when the FRC and OCRA values match. 190 Bit 2 OEA 0 1 Description Output compare A output is disabled. Output compare A output is enabled. (Initial value) Bits 1 and 0—Clock Select (CKS1 and CKS0): These bits select external clock input or one of three internal clock sources for the FRC. External clock pulses are counted on the rising edge. Bit 1 CKS1 0 0 1 1 Bit 0 CKS0 0 1 0 1 Description Internal clock source (ø/4) (Initial value) Internal clock source (ø/8) Internal clock source (ø/32) External clock source (counted on the rising edge) 10.2.5 Timer Control/Status Register (TCSR) Bit 7 6 5 4 3 2 1 0 ICF OCFB OCFA OVF OLVLB OLVLA IEDG CCLRA Initial value 0 0 0 0 0 0 0 0 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* R/W R/W R/W R/W The TCSR is an 8-bit readable and partially writable* register that selects the input capture edge and output compare levels, and specifies whether to clear the counter on compare-match A. It also contains four status flags. The TCSR is initialized to H'00 at a reset and in the standby modes. * Software can write a 0 in bits 7 to 4 to clear the flags, but cannot write a 1 in these bits. Bit 7—Input Capture Flag (ICF): This status flag is set to 1 to indicate an input capture event. It signifies that the FRC value has been copied to the ICR. 191 Bit 7 ICF 0 1 Description This bit is cleared from 1 to 0 when: (Initial value) 1. The CPU reads the ICF bit after it has been set to 1, then writes a 0 in this bit. 2. The data transfer controller (DTC) serves an input capture interrupt . This bit is set to 1 when an input capture signal causes the FRC value to be copied to the ICR. Bit 6—Output Compare Flag B (OCFB): This status flag is set to 1 when the FRC value matches the OCRB value. Bit 6 OCFB 0 1 Description This bit is cleared from 1 to 0 when: (Initial value) 1. The CPU reads the OCFB bit after it has been set to 1, then writes a 0 in this bit. 2. The data transfer controller (DTC) serves output compare interrupt B. This bit is set to 1 when FRC = OCRB. Bit 5—Output Compare Flag A (OCFA): This status flag is set to 1 when the FRC value matches the OCRA value. Bit 5 OCFA 0 1 Description This bit is cleared from 1 to 0 when: (Initial value) 1. The CPU reads the OCFA bit after it has been set to 1, then writes a 0 in this bit. 2. The data transfer controller (DTC) serves output compare interrupt A. This bit is set to 1 when FRC = OCRA. Bit 4—Timer Overflow Flag (OVF): This status flag is set to 1 when the FRC overflows (changes from H'FFFF to H'0000). Bit 4 OVF 0 1 Description This bit is cleared from 1 to 0 when the CPU reads (Initial value) the OVF bit after it has been set to 1, then writes a 0 in this bit. This bit is set to 1 when FRC changes from H'FFFF to H'0000. Bit 3—Output Level B (OLVLB): This bit selects the logic level to be output at the FTOB pin when the FRC and OCRB values match. 192 Bit 3 OLVLB 0 1 Description A 0 logic level (Low) is output for compare-match B. A 1 logic level (High) is output for compare-match B. (Initial value) Bit 2—Output Level A (OLVLA): This bit selects the logic level to be output at the FTOA pin when the FRC and OCRA values match. Bit 2 OLVLA 0 1 Description A 0 logic level (Low) is output for compare-match A. A 1 logic level (High) is output for compare-match A. (Initial value) Bit 1—Input Edge Select (IEDG): This bit selects whether to capture the count on the rising or falling edge of the input capture signal. Bit 1 IEDG 0 1 Description The FRC value is copied to the ICR on the falling edge of the input capture signal. The FRC value is copied to the ICR on the rising edge of the input capture signal. (Initial value) Bit 0—Counter Clear A (CCLRA): This bit selects whether to clear the FRC at compare-match A (when the FRC and OCRA values match). Bit 0 CCLRA Description 0 The FRC is not cleared. (Initial value) 1 The FRC is cleared at compare-match A. 193 10.3 CPU Interface The FRC, OCRA, OCRB, and ICR are 16-bit registers, but they are connected to an 8-bit data bus. When the CPU accesses these four registers, to ensure that both bytes are written or read simultaneously, the access is performed using an 8-bit temporary register (TEMP). These registers are written and read as follows. • Register Write When the CPU writes to the upper byte, the upper byte of write data is placed in TEMP. Next, when the CPU writes to the lower byte, this byte of data is combined with the byte in TEMP and all 16 bits are written in the register simultaneously. • Register Read When the CPU reads the upper byte, the upper byte of data is sent to the CPU and the lower byte is placed in TEMP. When the CPU reads the lower byte, it receives the value in TEMP. Programs that access these four registers should normally use word access. Equivalently, they may access first the upper byte, then the lower byte. Data will not be transferred correctly if the bytes are accessed in reverse order, or if only one byte is accessed. Coding Examples : Write the contents of R0 into OCRA in FRT1 MOV.W R0, @H'FE94 : Read ICR of FRT2 MOV.W, @H'FEA8, R0 The same considerations apply to access by the DTC. Figure 10-2 shows the data flow when the FRC is accessed. The other registers are accessed in the same way, except that when OCRA or OCRB is read, the upper and lower bytes are both transferred directly to the CPU without using the temporary register. 194 < Upper byte write > Module data bus CPU writes data H'AA Bus interface TEMP [H'AA] FRCH [ ] FRCL [ ] < Lower byte write > Module data bus CPU writes data H'55 Bus interface TEMP [H'AA] FRCH [H'AA] FRCL [H'55] Figure 10-2 (a) Write Access to FRC (When CPU Writes H'AA55) Fig. 10-2 (a) 195 < Upper byte read > Module data bus CPU writes data H'AA Bus interface TEMP [H'55] FRCH [H'AA] FRCL [H'55] < Lower byte read > Module data bus CPU writes data H'55 Bus interface TEMP [H'55] FRCH [ ] FRCL [ ] Figure 10-2 (b) Read Access to FRC (When FRC Contains H'AA55) 10.4 Operation 10.4.1 FRC Incrementation Timing Fig. 10-2 (b) The FRC increments on a pulse generated once for each period of the selected (internal or external) clock source. If external clock input is selected, the FRC increments on the rising edge of the clock signal. Figure 10-3 shows the increment timing. 196 The pulse width of the external clock signal must be at least 1.5·ø clock periods. The counter will not increment correctly if the pulse width is shorter than 1.5·ø clock periods. ø FTCI Minimum FTCI Pulse Width ø External clock source FRC clock pulse FRC N N+1 Figure 10-3 Increment Timing for External Clock Input 10.4.2 Output Compare Timing Setting of Output Compare Flags A and B (OCFA and OCFB): The output compare flags are set to 1 by an internal compare-match signal generated when the FRC value matches the OCRA or Fig. 10-3 OCRB value. This compare-match signal is generated at the last state in which the two values match, just before the FRC increments to a new value. Accordingly, when the FRC and OCR values match, the compare-match signal is not generated until the next period of the clock source. Figure 10-4 shows the timing of the setting of the output compare flags. 197 ø FRC N OCR N N+1 Internal comparematch signal OCF Figure 10-4 Setting of Output Compare Flags Output Timing: When a compare-match occurs, the logic level selected by the output level bit (OLVLA or OLVLB) in the TCSR is output at the output compare pin (FTOA or FTOB). Figure 10-5 shows the timing of this operation for compare-match A. ø Internal comparematch A signal OLYLA FTOA Figure 10-5 Timing of Output Compare A Fig. 10-5 198 FRC Clear Timing: If the CCLRA bit is set to 1, the FRC is cleared when compare-match A occurs. Figure 10-6 shows the timing of this operation. ø Internal comparematch A signal FRC N H'0000 Figure 10-6 Clearing of FRC by Compare-Match A 10.4.3 Input Capture Timing 1. Input Capture Timing: An internal input capture signal is generated from the rising or falling edge of the input at the input capture pin (FTI), as selected by the IEDG bit in the TCSR. Figure 10-7 shows the usual input capture timing when the rising edge is selected (IEDG = 1). ø Input at FTI pin Internal input capture signal Figure 10-7 Input Capture Timing (Usual Case) But if the upper byte of the ICR is being read when the input capture signal arrives, the internal input capture signal is delayed by one state. Figure 10-8 shows the timing for this case. 199 Read cycle: CPU reads upper byte of ICR T1 T2 T3 ø Input at FTI pin Internal input capture signal Figure 10-8 Input Capture Timing (1-State Delay) Timing of Input Capture Flag (ICF) Setting: The input capture flag (ICF) is set to 1 by the internal input capture signal. Figure 10-9 shows the timing of this operation. ø Internal input capture signal ICF FRC N–1 N ICR N+1 N Figure 10-9 Setting of Input Capture Flag 200 10.4.4 Setting of FRC Overflow Flag (OVF) The FRC overflow flag (OVF) is set to 1 when the FRC overflows (changes from H'FFFF to H'0000). Figure 10-10 shows the timing of this operation. ø FRC H'FFFF H'0000 Internal overflow signal OVF Figure 10-10 Setting of Overflow Flag (OVF) 10.5 CPU Interrupts and DTC Interrupts Each free-running timer channel can request four types of interrupts: input capture (ICI), output compare A and B (OCIA and OCIB), and overflow (FOVI). Each interrupt is requested when the corresponding enable and flag bits are set. Independent signals are sent to the interrupt controller for each type of interrupt. Table 10-3 lists information about these interrupts. Table 10-3 Free-Running Timer Interrupts Interrupt ICI OCIA OCIB FOVI Description Requested when ICF is set Requested when OCFA is set Requested when OCFB is set Requested when OVF is set DTC Service Available? Yes Yes Yes No Priority High Low The ICI, OCIA, and OCIB interrupts can be directed to the data transfer controller (DTC) to have a data transfer performed in place of the usual interrupt-handling routine. When the DTC serves one of these interrupts, it automatically clears the ICF, OCFA, or OCFB flag to 0. See section 6, “Data Transfer Controller” for further information on the DTC. 201 10.6 Synchronization of Free-Running Timers 1 to 3 10.6.1 Synchronization after a Reset The three free-running timer channels are synchronized at a reset and remained synchronized until: • the clock source is changed; • FRC contents are rewritten; or • an FRC is cleared. After a reset, each free-running counter operates on the ø/4 internal clock source. 10.6.2 Synchronization by Writing to FRCs When synchronization among free-running timers 1 to 3 is lost, it can be restored by writing to the free-running counters. Synchronization on Internal Clock Source: When an internal clock is selected, free-running timers 1 to 3 can be synchronized by writing data to their free-running counters as indicated in table 10-4. Table 10-4 Synchronization by Writing to FRCs Clock Source Write Interval ø/4 4n (states) ø/8 8n (states) ø/32 32n (states) m, n: Arbitrary integers Write Data m (FRC1) m+n (FRC2) m + 2n (FRC3) After writing these data, synchronization can be checked by reading the three free-running counters at the same interval as the write interval. If the read data have the same relative differences as the write data, the three free-running timers are synchronized. Programs for synchronizing the timers are shown next. Examples a, b, and c can be used when the program is stored in on-chip memory. Examples d, e, and f can be used when the program is stored in external memory. These programs assume that no wait states (TW) are inserted and there is no NMI input. 202 Example a: ø/4 clock source, 12-state write interval (n = 3), on-chip memory LA: LDC.B #H'FE,BR ; Initialize base register for short-format instruction (MOV:S) LDC.W #H'0700,SR ; Raise interrupt mask level to 7 MOV.W #m,R1 ; Data for free-running timer 1 MOV.W #m+3,R2 ; Data for free-running timer 2 (m + n = m + 3) MOV.W #m+6,R3 ; Data for free-running timer 3 (m + 2n = m + 2 × 3) BSR SET4 ; Call write routine .ALIGN 2 SET4:MOV:S.W R1,@H'92:8 BRN SET4:8 MOV:S.W R2,@H'A2:8 BRN SET4:8 MOV:S.W R3,@H'B2:8 RTS ; Align write instructions (MOV:S) at even address ; Write to FRC 1 (address H'FE92) 9 states ; 2-Byte dummy instruction 3 states ; Write to FRC 2 (address H'FEA2) Total 12 states ; 2-Byte dummy instruction ; Write to FRC 3 (address H'FEB2) Example b: ø/8 clock source, 16-state write interval (n = 2), on-chip memory LB: LDC.B LDC.W MOV.W MOV.W MOV.W BSR #H'FE,BR #H'0700,SR #m,R1 #m+2,R2 #m+4,R3 SET8 .ALIGN 2 SET8:MOV:S.W R1,@H'92:8 BRN SET8:8 XCH R1,R1 MOV:S.W R2,@H'A2:8 BRN SET8:8 XCH R2,R2 MOV:S.W R3,@H'B2:8 RTS ; 9 States ; 3 States ; 4 States 203 Total 16 states Example c: ø/32 clock source, 32-state write interval (n = 1), on-chip memory LC: LDC.B #H'FE,BR LDC.W #H'0700,SR MOV.W #m,R1 MOV.W #m+1,R2 MOV.W #m+2,R3 BSR SET32 ; Align on even address ; 2 Bytes, 9 states ; 2 Bytes, 9 states .ALIGN 2 SET32: MOV:S.W R1,@H'92:8 BSR WAIT:8 MOV:S.W R2,@H'A2:8 BSR WAIT:8 MOV:S.W R3,@H'B2:8 RTS WAIT: Total 32 states ; Align on even address ; 2 States ; 4 States ; 8 States .ALIGN 2 NOP XCH R1,R1 RTS Note: The stack is assumed to be in on-chip RAM. Example d: ø/4 clock source, 20-state write interval (n = 5), external memory LD: LDC.B #H'FE,BR LDC.W #H'0700,SR ; Set interrupt mask level to 7 CLR.B H'FF10 ; Disable wait states MOV.W #m,R1 MOV.W #m+5,R2 MOV.W #m+10,R3 MOV:S.W R1,@H'92:8 ; 13 States Total 20 states BRN LD:8 ; 2 Bytes, 7 states MOV:S.W R2,@H'A2:8 BRN LD:8 MOV:S.W R3,@H'B2:8 204 Example e: ø/8 clock source, 24-state write interval (n = 3), external memory LE: LDC.B #H'FF,BR LDC.W #H'0700,SR CLR.B @H'F8"8 MOV.W #m,R1 MOV.W #m+3,R2 MOV.W #m+6,R3 MOV:S.W R1,@H'92:8 ; 13 States BRN LE:8 ; 2 Bytes, 7 states Total 24 states NOP ; 1 Byte, 4 states MOV:S.W R2,@H'A2:8 BRN LE:8 NOP MOV:S.W R3,@H'B2:8 Example f: ø/32 clock source, 32-state write interval (n = 1), external memory LF: LDC.B #H'FF,BR LDC.W #H'0700,SR CLR.B @H'F8:8 MOV.W #m,R1 MOV.W #m+1,R2 MOV.W #m+2,R3 MOV:S.W R1,@H'92:8 ; External memory, so 13 states XCH R0,R0 ; 8 states Total 32 states BRN LF:8 ; 2 Bytes, 7 states NOP ; 4 states MOV:S.W R2,@H'A2:8 XCH R0,R0 BRN LF:8 NOP MOV:S.W R3,@H'B2:8 205 Synchronization on External Clock Source: When the external clock source is selected, the free-running timers can be synchronized by halting their external clock inputs, then writing identical values in their free-running counters. 10.7 Sample Application In the example below, one free-running timer channel is used to generate two square-wave outputs with a 50% duty factor and arbitrary phase relationship. The programming is as follows: 1. The CCLRA bit in the TCSR is set to 1. 2. Each time a compare-match interrupt occurs, software inverts the corresponding output level bit in the TCSR. FRC H'FFFF Clear counter OCRA OCRB H'0000 FTOA pin FTOB pin Figure 10-11 Square-Wave Output (Example) 10.8 Application Notes Application programmers should note that the following types of contention can occur in the freerunning timers. Contention between FRC Write and Clear: If an internal counter clear signal is generated during the T3 state of a write cycle to the lower byte of a free-running counter, the clear signal takes priority and the write is not performed. 206 Figure 10-12 shows this type of contention. Write cycle: CPU writes to lower byte of FRC T2 T1 T3 ø Internal address bus FRC address Internal write signal FRC clear signal FRC N H'0000 Figure 10-12 FRC Write-Clear Contention Contention between FRC Write and Increment: If an FRC increment pulse is generated during the T3 state of a write cycle to the lower byte of a free-running counter, the write takes priority and the FRC is not incremented. 207 Figure 10-13 shows this type of contention. Write cycle: CPU writes to lower byte of FRC T2 T1 T3 ø Internal address bus FRC address Internal write signal FRC clock pulse FRC N M Write data Figure 10-13 FRC Write-Increment Contention 208 Contention between OCR Write and Compare-Match: If a compare-match occurs during the T3 state of a write cycle to the lower byte of OCRA or OCRB, the write takes precedence and the compare-match signal is inhibited. Figure 10-14 shows this type of contention. Write cycle: CPU writes to lower byte of OCRA or OCRB T2 T1 T3 ø Internal address bus OCR address Internal write signal FRC N N+1 OCRA or OCRB N M Write data Compare-match A or B signal Inhibited Figure 10-14 Contention between OCR Write and Compare-Match Incrementation Caused by Changing of Internal Clock Source: When an internal clock source is changed, the changeover may cause the FRC to increment. This depends on the time at which the clock select bits (CKS1 and CKS0) are rewritten, as shown in table 10-5. The pulse that increments the FRC is generated at the falling edge of the internal clock source. If clock sources are changed when the old source is High and the new source is Low, as in case No. 3 in table 10-5, the changeover generates a falling edge that triggers the FRC increment pulse. Switching between an internal and external clock source can also cause the FRC to increment. 209 Table 10-5 Effect of Changing Internal Clock Sources No. 1 Description Low → Low: CKS1 and CKS0 are rewritten while both clock sources are Low. Timing Chart Old clock source New clock source FRC clock pulse FRC N N+1 CKS rewrite 2 Low → High: CKS1 and CKS0 are rewritten while old clock source is Low and new clock source is High. Old clock source New clock source FRC clock pulse FRC N N+1 N+2 CKS rewrite 3 High → Low: CKS1 and CKS0 are rewritten while old clock source is High and new clock source is Low. Old clock source New clock source * FRC clock pulse FRC N N+1 N+2 CKS rewrite ∗ The switching of clock sources is regarded as a falling edge that increments the FRC. 210 Table 10-5 Effect of Changing Internal Clock Sources (cont) No. 4 Description High → High: CKS1 and CKS0 are rewritten while both clock sources are High. Timing Chart Old clock source New clock source FRC clock pulse FRC N N+1 N+2 CKS rewrite 211 Section 11 8-Bit Timer 11.1 Overview The H8/534 and H8/536 have a single 8-bit timer based on an 8-bit counter (TCNT). The timer has two time constant registers (TCORA and TCORB) that are constantly compared with the TCNT value to detect compare-match events. One application of the 8-bit timer is to generate a rectangular-wave output with an arbitrary duty factor. 11.1.1 Features The features of the 8-bit timer are listed below. • Selection of four clock sources The counter can be driven by an internal clock signal (ø/8, ø/64, or ø/1024) or an external clock input (enabling use as an external event counter). • Selection of three ways to clear the counter The counter can be cleared on compare-match A or B, or by an external reset signal. • Timer output controlled by two time constants The single timer output (TMO) is controlled by two independent time constants, enabling the timer to generate output waveforms with an arbitrary duty factor. • Three types of interrupts Compare-match A and B and overflow interrupts can be requested independently. The compare match interrupts can be served by the data transfer controller (DTC), enabling interrupt-driven data transfer with minimal CPU programming. 213 11.1.2 Block Diagram Figure 11-1 shows a block diagram of 8-bit timer. External clocks Internal clocks ø/8 ø/64 TMCI ø/1024 Clock Clock select TCORA Compare-match A Comparator A TMO TCNT Clear Control logic Comparator B Compare-match B TCORB TCSR TCR CMIA CMIB OVI Interrupt signals TCORA: TCORB: TCNT: TCSR: TCR: Bus interface Overflow TMRI Time Constant Register A Time Constant Register B Timer Counter Timer Control/Status Register Timer Control Register Figure 11-1 Block Diagram of 8-Bit Timer 214 Module data bus Internal data bus 11.1.3 Input and Output Pins Table 11-1 lists the input and output pins of the 8-bit timer. Table 11-1 Input and Output Pins of 8-Bit Timer Name Timer output Timer clock input Timer reset input Abbreviation TMO TMCI TMRI I/O Output Input Input Function Output controlled by compare-match External clock source for the counter External reset signal for the counter 11.1.4 Register Configuration Table 11-2 lists the registers of the 8-bit timer. Table 11-2 8-Bit Timer Registers Name Abbreviation R/W Initial Value Address Timer control register TCR R/W H'00 H'FED0 Timer control/status register TCSR R/(W)* H'10 H'FED1 Timer constant register A TCORA R/W H'FF H'FED2 Timer constant register B TCORB R/W H'FF H'FED3 Timer counter TCNT R/W H'00 H'FED4 * Software can write a 0 to clear bits 7 to 5, but cannot write a 1 in these bits. 11.2 Register Descriptions 11.2.1 Timer Counter (TCNT)—H'FED4 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The timer counter (TCNT) is an 8-bit up-counter that increments on a pulse generated from one of four clock sources. The clock source is selected by clock select bits 2 to 0 (CKS2 to CKS0) of the timer control register (TCR). The CPU can always read or write the timer counter. 215 The timer counter can be cleared by an external reset input or by an internal compare-match signal generated at a compare-match event. Clock clear bits 1 and 0 (CCLR1 and CCLR0) of the timer control register select the method of clearing. When the timer counter overflows from H'FF to H'00, the overflow flag (OVF) in the timer control/status register (TCSR) is set to 1. The timer counter is initialized to H'00 at a reset and in the standby modes. 11.2.2 Time Constant Registers A and B (TCORA and TCORB)—H'FED2 and H'FED3 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W TCORA and TCORB are 8-bit readable/writable registers. The timer count is continually compared with the constants written in these registers. When a match is detected, the corresponding compare-match flag (CMFA or CMFB) is set in the timer control/status register (TCSR). The timer output signal (TMO) is controlled by these compare-match signals as specified by output select bits 1 to 0 (OS1 to OS0) in the timer status/control register (TCSR). TCORA and TCORB are initialized to H'FF at a reset and in the standby modes. 11.2.3 Timer Control Register (TCR)—H'FED0 Bit 7 6 5 4 3 2 1 0 CMIEB CMIEA OVIE CCLR1 CCLR0 CKS2 CKS1 CKS0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The TCR is an 8-bit readable/writable register that selects the clock source and the time at which the timer counter is cleared, and enables interrupts. The TCR is initialized to H'00 at a reset and in the standby modes. 216 Bit 7—Compare-Match Interrupt Enable B (CMIEB): This bit selects whether to request compare-match interrupt B (CMIB) when compare-match flag B (CMFB) in the timer status/control register (TCSR) is set to 1. Bit 7 CMIEB 0 1 Description Compare-match interrupt request B (CMIB) is disabled. Compare-match interrupt request B (CMIB) is enabled. (Initial value) Bit 6—Compare-Match Interrupt Enable A (CMIEA): This bit selects whether to request compare-match interrupt A (CMIA) when compare-match flag A (CMFA) in the timer status/control register (TCSR) is set to 1. Bit 6 CMIEA 0 1 Description Compare-match interrupt request A (CMIA) is disabled. Compare-match interrupt request A (CMIA) is enabled. (Initial value) Bit 5—Timer Overflow Interrupt Enable (OVIE): This bit selects whether to request a timer overflow interrupt (OVI) when the overflow flag (OVF) in the timer status/control register (TCSR) is set to 1. Bit 5 OVIE 0 1 Description The timer overflow interrupt request (OVI) is disabled. The timer overflow interrupt request (OVI) is enabled. (Initial value) Bits 4 and 3—Counter Clear 1 and 0 (CCLR1 and CCLR0): These bits select how the timer counter is cleared: by compare-match A or B or by an external reset input. Bit 4 CCLR1 0 0 1 1 Bit 3 CCLR0 0 1 0 1 Description Not cleared. (Initial value) Cleared on compare-match A. Cleared on compare-match B. Cleared on rising edge of external reset input signal. 217 Bits 2, 1, and 0—Clock Select (CKS2, CKS1, and CKS0): These bits select the internal or external clock source for the timer counter. For the external clock source they select whether to increment the count on the rising or falling edge of the clock input, or on both edges. Bit 2 CKS2 0 0 0 0 1 1 1 1 Bit 1 CKS1 0 0 1 1 0 0 1 1 Bit 0 CKS0 0 1 0 1 0 1 0 1 Description No clock source (timer stopped). (Initial value) Internal clock source (ø/8). Internal clock source (ø/64). Internal clock source (ø/1024). No clock source (timer stopped). External clock source, counted on the rising edge. External clock source, counted on the falling edge. External clock source, counted on both the rising and falling edges. 11.2.4 Timer Control/Status Register (TCSR)—H'FED1 Bit 7 6 5 4 3 2 1 0 CMFB CMFA OVF — OS3 OS2 OS1 OS0 Initial value 0 0 0 1 0 0 0 0 Read/Write R/(W)* R/(W)* R/(W)* — R/W R/W R/W R/W The TCSR is an 8-bit readable and partially writable* register that indicates compare-match and overflow status and selects the effect of compare-match events on the timer output signal (TMO). The TCSR is initialized to H'10 at a reset and in the standby modes. * Software can write a 0 in bits 7 to 5 to clear the flags, but cannot write a 1 in these bits. Bit 7—Compare-Match Flag B (CMFB): This status flag is set to 1 when the timer count matches the time constant set in TCORB. 218 Bit 7 CMFB 0 1 Description This bit is cleared from 1 to 0 when: (Initial value) 1. The CPU reads the CMFB bit after it has been set to 1, then writes a 0 in this bit. 2. Compare-match interrupt B is served by the data transfer controller (DTC). This bit is set to 1 when TCNT = TCORB. Bit 6—Compare-Match Flag A (CMFA): This status flag is set to 1 when the timer count matches the time constant set in TCORA. Bit 6 CMFA 0 1 Description This bit is cleared from 1 to 0 when: (Initial value) 1. The CPU reads the CMFA bit after it has been set to 1, then writes a 0 in this bit. 2. Compare-match interrupt A is served by the data transfer controller (DTC). This bit is set to 1 when TCNT = TCORA. Bit 5—Timer Overflow Flag (OVF): This status flag is set to 1 when the timer count overflows (changes from H'FF to H'00). Bit 5 OVF 0 1 Description This bit is cleared from 1 to 0 when the CPU reads (Initial value) the OVF bit after it has been set to 1, then writes a 0 in this bit. This bit is set to 1 when TCNT changes from H'FF to H'00. Bit 4—Reserved: This bit cannot be modified and is always read as 1. Bits 3 to 0—Output Select 3 to 0 (OS3 to OS0): These bits specify the effect of compare-match events on the timer output signal (TMO). Bits OS3 and OS2 control the effect of compare-match B on the output level. Bits OS1 and OS0 control the effect of compare-match A on the output level. When all four output select bits are cleared to 0 the TMO signal is not output. The TMO output is 0 before the first compare-match. Bit 3 OS3 0 0 1 1 Bit 2 OS2 0 1 0 1 Description No change when compare-match B occurs. (Initial value) Output changes to 0 when compare-match B occurs. Output changes to 1 when compare-match B occurs. Output inverts (toggles) when compare-match B occurs. 219 Bit 1 OS1 0 0 1 1 Bit 0 OS0 0 1 0 1 Description No change when compare-match A occurs. (Initial value) Output changes to 0 when compare-match A occurs. Output changes to 1 when compare-match A occurs. Output inverts (toggles) when compare-match A occurs. 11.3 Operation 11.3.1 TCNT Incrementation Timing The timer counter increments on a pulse generated once for each period of the selected (internal or external) clock source. If external clock input (TMCI) is selected, the timer counter can increment on the rising edge, the falling edge, or both edges of the external clock signal. The external clock pulse width must be at least 1.5·ø clock periods for incrementation on a single edge, and at least 2.5·ø clock periods for incrementation on both edges. The counter will not increment correctly if the pulse width is shorter than these values. ø TMCI Minimum TMCI Pulse Width (Single-Edge Incrementation) ø TMCI Minimum TMCI Pulse Width (Double-Edge Incrementation) 220 Figure 11-2 shows the count timing for incrementation on both edges. ø External clock source TCNT clock pulse TCNT N–1 N N+1 Figure 11-2 Count Timing for External Clock Input 11.3.2 Compare Match Timing Setting of Compare-Match Flags A and B (CMFA and CMFB): The compare-match flags are set to 1 by an internal compare-match signal generated when the timer count matches the time constant in TCORA or TCORB. The compare-match signal is generated at the last state in which the match is true, just before the timer counter increments to a new value. Accordingly, when the timer count matches one of the time constants, the compare-match signal is not generated until the next period of the clock source. Figure 11-3 shows the timing of the setting of the compare-match flags. 221 ø TCNT N TCOR N N+1 Internal compare-match signal CMF Figure 11-3 Setting of Compare-Match Flags Output Timing: When a compare-match event occurs, the timer output (TMO) changes as specified by the output select bits (OS3 to OS0) in the TCSR. Depending on these bits, the output can remain the same, change to 0, change to 1, or toggle. Figure 11-4 shows the timing when the output is set to toggle on compare-match A. ø Internal compare-match A signal Timer output (TMO) Figure 11-4 Timing of Timer Output 222 Timing of Compare-Match Clear: Depending on the CCLR1 and CCLR0 bits in the TCR, the timer counter can be cleared when compare-match A or B occurs. Figure 11-5 shows the timing of this operation. ø Internal compare-match signal N TCNT H'00 Figure 11-5 Timing of Compare-Match Clear 11.3.3 External Reset of TCNT When the CCLR1 and CCLR0 bits in the TCR are both set to 1, the timer counter is cleared on the rising edge of an external reset input. Figure 11-6 shows the timing of this operation. ø External reset input (TMRI) Internal clear pulse TCNT N–1 N Figure 11-6 Timing of External Reset 223 H'00 11.3.4 Setting of TCNT Overflow Flag The overflow flag (OVF) is set to 1 when the timer count overflows (changes from H'FF to H'00). Figure 11-7 shows the timing of this operation. ø H'FF TCNT H'00 Internal overflow signal OVF Figure 11-7 Setting of Overflow Flag (OVF) 11.4 CPU Interrupts and DTC Interrupts The 8-bit timer can generate three types of interrupts: compare-match A and B (CMIA and CMIB), and overflow (OVI). Each interrupt is requested when the corresponding enable and flag bits are set in the TCR and TCSR. Independent signals are sent to the interrupt controller for each type of interrupt. Table 11-3 lists information about these interrupts. Table 11-3 8-Bit Timer Interrupts Interrupt CMIA CMIB OVI Description Requested when CMFA is set Requested when CMFB is set Requested when OVF is set DTC Service Available? Yes Yes No Priority High Low The CMIA and CMIB interrupts can be served by the data transfer controller (DTC) to have a data transfer performed. When the DTC serves one of these interrupts, it automatically clears the CMFA or CMFB flag to 0. See section 6, “Data Transfer Controller” for further information on the DTC. 224 11.5 Sample Application In the example below, the 8-bit timer is used to generate a pulse output with a selected duty factor. The control bits are set as follows: 1. In the TCR, CCLR1 is cleared to 0 and CCLR0 is set to 1 so that the timer counter is cleared when its value matches the constant in TCORA. 2. In the TCSR, bits OS3 to OS0 are set to “0110,” causing the output to change to 1 on comparematch A and to 0 on compare-match B. With these settings, the 8-bit timer provides output of pulses at a rate determined by TCORA with a pulse width determined by TCORB. No software intervention is required. H'FF TCNT Clear counter TCORA TCORB H'00 TMO pin Figure 11-8 Example of Pulse Output 225 11.6 Application Notes Application programmers should note that the following types of contention can occur in the 8-bit timer. Contention between TCNT Write and Clear: If an internal counter clear signal is generated during the T3 state of a write cycle to the timer counter, the clear signal takes priority and the write is not performed. Figure 11-9 shows this type of contention. Write cycle: CPU writes to TCNT T2 T1 T3 ø Internal Address bus TCNT address Internal write signal Counter clear signal TCNT N H'00 Figure 11-9 TCNT Write-Clear Contention 226 Contention between TCNT Write and Increment: If a timer counter increment pulse is generated during the T3 state of a write cycle to the timer counter, the write takes priority and the timer counter is not incremented. Figure 11-10 shows this type of contention. Write cycle: CPU writes to TCNT T2 T1 T3 ø Internal Address bus TCNT address Internal write signal TCNT clock pulse TCNT N M Write data Figure 11-10 TCNT Write-Increment Contention 227 Contention between TCOR Write and Compare-Match: If a compare-match occurs during the T3 state of a write cycle to TCORA or TCORB, the write takes precedence and the comparematch signal is inhibited. Figure 11-11 shows this type of contention. Write cycle: CPU writes to TCORA or TCORB T2 T1 T3 ø Internal address bus TCNT address Internal write signal TCNT N TCORA or TCORB N N+1 M TCOR write data Compare-match A or B signal Inhibited Figure 11-11 Contention between TCOR Write and Compare-Match Contention between Compare-Match A and Compare-Match B: If identical time constants are written in TCORA and TCORB, causing compare-match A and B to occur simultaneously, any conflict between the output selections for compare-match A and B is resolved by following the priority order in table 11-4. 228 Table 11-4 Priority Order of Timer Output Output Selection Toggle 1 Output 0 Output No change Priority High Low Incrementation Caused by Changing of Internal Clock Source: When an internal clock source is changed, the changeover may cause the timer counter to increment. This depends on the time at which the clock select bits (CKS2 to CKS0) are rewritten, as shown in table 11-5. The pulse that increments the timer counter is generated at the falling edge of the internal clock source signal. If clock sources are changed when the old source is High and the new source is Low, as in case No. 3 in table 11-5, the changeover generates a falling edge that triggers the TCNT clock pulse and increments the timer counter. Switching between an internal and external clock source can also cause the timer counter to increment. Table 11-5 Effect of Changing Internal Clock Sources No. 1 Description Low → Low*1: CKS1 and CKS0 are rewritten while both clock sources are Low. Timing Chart Old clock source New clock source TCNT clock pulse TCNT N N+1 CKS rewrite Note: *1 Including a transition from Low to the stopped state (CKS1 = 0, CKS0 = 0), or a transition from the stopped state to Low. 229 Table 11-5 Effect of Changing Internal Clock Sources (cont) No. 2 Description Timing Chart Low → High*1: Old clock CKS1 and CKS0 are source rewritten while old clock source is Low and New clock new clock source is High. source TCNT clock pulse TCNT N N+1 N+2 CKS rewrite 3 High → Low*2: CKS1 and CKS0 are rewritten while old clock source is High and new clock source is Low. Old clock source New clock source *3 TCNT clock pulse TCNT N N+1 N+2 CKS rewrite Note: *1 Including a transition from the stopped state to High. *2 Including a transition from High to the stopped state. *3 The switching of clock sources is regarded as a falling edge that increments the TCNT. 230 Table 11-5 Effect of Changing Internal Clock Sources (cont) No. 4 Description High → High: CKS1 and CKS0 are rewritten while both clock sources are High. Timing Chart Old clock source New clock source TCNT clock pulse TCNT N N+1 N+2 CKS rewrite 231 Section 12 PWM Timer 12.1 Overview The H8/534 and H8/536 have an on-chip pulse-width modulation (PWM) timer module with three independent channels (PWM1, PWM2, and PWM3). All three channels are functionally identical. Using an 8-bit timer counter, each PWM channel generates a rectangular output pulse with a duty factor of 0 to 100%. The duty factor is specified in an 8-bit duty register (DTR). 12.1.1 Features The PWM timer module has the following features: • Selection of eight clock sources • Duty factors from 0 to 100% with 1/250 resolution • Output with positive or negative logic 12.1.2 Block Diagram Figure 12-1 shows a block diagram of one PWM timer channel. 233 DTR Output control Comparematch Comparator Bus interface PW TCNT Internal data bus Module data bus TCR Internal clock source ø/2 ø/8 ø/32 Clock Clock select ø/128 ø/256 ø/1024 DTR: Duty Register TCNT: Timer Counter TCR: Timer Control Register ø/2048 ø/4096 Figure 12-1 Block Diagram of PWM Timer 12.1.3 Input and Output Pins Table 12-1 lists the output pins of the PWM timer module. There are no input pins. Table 12-1 Output Pins of PWM Timer Module Name PWM1 output PWM2 output PWM3 output Abbreviation PW1 PW2 PW3 I/O Output Output Output Function Pulse output from PWM timer channel 1. Pulse output from PWM timer channel 2. Pulse output from PWM timer channel 3. 234 12.1.4 Register Configuration The PWM timer module has three registers for each channel as listed in table12-2. Table 12-2 PWM Timer Registers Initial Name Abbreviation R/W Value Address Timer control register TCR R/W H'38 H'FEC0 Duty register DTR R/W H'FF H'FEC1 Timer counter TCNT R/(W)* H'00 H'FEC2 2 Timer control register TCR R/W H'38 H'FEC4 Duty register DTR R/W H'FF H'FEC5 Timer counter TCNT R/(W)* H'00 H'FEC6 3 Timer control register TCR R/W H'38 H'FEC8 Duty register DTR R/W H'FF H'FEC9 Timer counter TCNT R/(W)* H'00 H'FECA * The timer counters are read/write registers, but the write function is for test purposes only. Application programs should never write to these registers. Channel 1 12.2 Register Descriptions 12.2.1 Timer Counter (TCNT)—H'FEC2, H'FEC4, H'FECA Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The PWM timer counters (TCNT) are 8-bit up-counters. When the output enable bit (OE) in the timer control register (TCR) is set to 1, the timer counter starts counting pulses of an internal clock source selected by clock select bits 2 to 0 (CKS2 to CKS0). After counting from H'00 to H'F9, the timer counter repeats from H'00. The PWM timer counters can be read and written, but the write function is for test purposes only. Application software should never write to a PW timer counter, because this may have unpredictable effects. 235 The PWM timer counters are initialized to H'00 at a reset and in the standby modes, and when the OE bit is cleared to 0. 12.2.2 Duty Register (DTR)—H'FEC1, H'FEC5, H'FEC9 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The duty registers (DTR) specify the duty factor of the output pulse. Any duty factor from 0 to 100% can be selected, with a resolution of 1/250. Writing 0 (H'00) in a DTR gives a 0% duty factor; writing 125 (H'7D) gives a 50% duty factor; writing 250 (H'FA) gives a 100% duty factor. The timer count is continually compared with the DTR contents. If the DTR value is not 0, when the count increments from H'00 to H'01 the PWM output signal is set to 1. When the count increments to the DTR value, the PWM output returns to 0. If the DTR value is 0 (duty factor 0%), the PWM output remains constant at 0. The DTRs are double-buffered. A new value written in a DTR while the timer counter is running does not become valid until after the count changes from H'F9 to H'00. When the timer counter is stopped (while the OE bit is 0), new values become valid as soon as written. When a DTR is read, the value read is the currently valid value. The DTRs are initialized to H'FF at a reset and in the standby modes. 12.2.3 Timer Control Register (TCR)—H'FEC0, H'FEC4, H'FEC8 Bit 7 6 5 4 3 2 1 0 OE OS — — — CKS2 CKS1 CKS0 Initial value 0 0 1 1 1 0 0 0 Read/Write R/W R/W — — — R/W R/W R/W The TCRs are 8-bit readable/writable registers that select the clock source and control the PWM outputs. The TCRs are initialized to H'38 at a reset and in the standby modes. 236 Bit 7—Output Enable (OE): This bit enables the timer counter and the PWM output. Bit 7 OE 0 1 Description PWM output is disabled. TCNT is cleared to H'00 and stopped. (Initial value) PWM output is enabled. TCNT runs. Bit 6—Output Select (OS): This bit selects positive or negative logic for the PWM output. Bit 6 OS 0 1 Description Positive logic; positive-going PWM pulse, 1 = High Negative logic; negative-going PWM pulse, 1 = Low (Initial value) Bits 5 to 3—Reserved: These bits cannot be modified and are always read as 1. Bits 2, 1, and 0—Clock Select (CKS2, CKS1, and CKS0): These bits select one of eight clock sources obtained by dividing the system clock (ø). Bit 2 CKS2 0 0 0 0 1 1 1 1 Bit 1 CKS1 0 0 1 1 0 0 1 1 Bit 0 CKS0 0 1 0 1 0 1 0 1 Description ø/2 (Initial value) ø/8 ø/32 ø/128 ø/256 ø/1024 ø/2048 ø/4096 From the clock source frequency, the resolution, period, and frequency of the PWM output can be calculated as follows. Resolution = 1/clock source frequency PWM period = resolution × 250 PWM frequency = 1/PWM period If the ø clock frequency is 10 MHz, then the resolution, period, and frequency of the PWM output for each clock source are given in table12-3. 237 Table 12-3 PWM Timer Parameters for 10 MHz System Clock Internal Clock Frequency Resolution PWM Period PWM Frequency ø/2 200 ns 50 µs 20 kHz ø/8 800 ns 200 µs 5 kHz ø/32 3.2 µs 800 µs 1.25 kHz ø/128 12.8 µs 3.2 ms 312.5 Hz ø/256 25.6 µs 6.4 ms 156.3 Hz ø/1024 102.4 µs 25.6 ms 39.1 Hz ø/2048 204.8 µs 51.2 ms 19.5 Hz ø/4096 409.6 µs 102.4 ms 9.8 Hz 12.3 Operation Figure 12-2 shows the timing of the PWM timer operation. 1. Positive Logic (OS = 0) (1) When OE = 0—(a) in Figure 12-2: The timer count is held at H'00 and PWM output is inhibited. (The pin is used for port 9 input/output, and its state depends on the corresponding port 9 data register and data direction register.) Any value (such as N in figure 12-2) written in the DTR becomes valid immediately. (2) When OE = 1 i) The timer counter begins incrementing, and the PWM output goes High. [(b) in figure 12-2] ii) When the count reaches the DTR value, the PWM output goes Low. [(c) in figure 12-2] iii)If the DTR value is changed (by writing the data M in figure 12-2), the new value becomes valid after the timer count changes from H'F9 to H'00. [(d) in figure 12-2] 2. Negative Logic (OS = 1): The operation is the same except that High and Low are reversed in the PWM output. [(e) in figure 12-2] 238 Figure 12-2 PWM Timing Fig. 12-2 239 (e) (a) N written in DTR H'FF (a) H'00 * * (b) (b) H'01 M written in DTR H'02 (c) N N N–1 (c) H'F9 N+1 * Used for port 9 input/output: state depends on values in data register and data direction register. (OS = “1”) PWM output (OS = “0”) DTR TCNT OE TCNT clock pulses ø (d) M (d) H'00 H'01 12.4 Application Notes Notes on the use of the PWM timer module are given below. To use port 9 for PWM output, first set the P9PWME bit to 1 and clear the P9SCI2E bit to 0 in system control register 2 (SYSCR2). Similarly, to use port 6 for PWM output, first set the P6PWME bit to 1 and clear the corresponding interrupt enable bit or bits (IRQ3E, IRQ4E, IRQ5E) to 0 in SYSCR2. 1. Any necessary changes to the clock select bits (CKS2 to CKS0) and output select bit (OS) should be made before the output enable bit (OE) is set to 1. 2. If the DTR value is H'00, the duty factor is 0% and PW output remains constant at 0. If the DTR value is H'FA to H'FF, the duty factor is 100% and PW output remains constant at 1. (For positive logic, 0 is Low and 1 is High. For negative logic, 0 is High and 1 is Low.) 3. PWM output and serial communication interface functions cannot be mixed among pins P94, P93, and P92. 240 Section 13 Watchdog Timer 13.1 Overview The H8/534 and H8/536 have an on-chip watchdog timer (WDT) module. This module can monitor system operation by generating a signal that resets the entire chip if a system crash allows the timer count to overflow. When this watchdog function is not needed, the WDT module can be used as an interval timer. In the interval timer mode, an interval timer interrupt is requested at each counter overflow. The WDT module is also used in recovering from the software standby mode. 13.1.1 Features The basic features of the watchdog timer module are summarized as follows: • Selection of eight clock sources • Selection of two modes: watchdog timer mode and interval timer mode • Counter overflow generates a reset signal or interrupt request Reset signal in watchdog timer mode; interval timer interrupt request in interval timer mode. • External output of reset signal The reset signal generated in watchdog timer mode resets the entire H8/534 or H8/536 chip. Depending on a reset output enable bit, the reset signal can also be output from the RES pin to reset devices controlled by the H8/534 or H8/536. 241 13.1.2 Block Diagram Figure 13-1 is a block diagram of the watchdog timer. Interrupt signal Overflow Interval timer mode TCNT Read/ write control Interrupt control TCSR Internal data bus Internal clock sources ø/2 ø/32 RSTCSR Reset (internal, external) ø/64 Reset control Clock Clock select ø/128 ø/256 ø/512 TCNT : Timer Counter TCSR : Timer Control/Status Register RSTCSR : Reset Control/Status Register ø/2048 ø/4096 Figure 13-1 Block Diagram of Timer Counter 13.1.3 Register Configuration Table 13-1 lists information on the watchdog timer registers. Table 13-1 Register Configuration Initial Addresses Name Abbreviation R/W Value Write Read Timer control/status register TCSR R/(W)* H'18 H'FEEC H'FEEC Timer counter TCNT R/W H'00 H'FEEC H'FEED Reset control/status register RSTCSR R/(W)* H'3F H'FF14 H'FF15 * Software can write a 0 to clear the status flag bits, but cannot write 1. 242 13.2 Register Descriptions 13.2.1 Timer Counter TCNT—H'FEEC (Write), H'FEED (Read) Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The watchdog timer counter (TCNT) is a readable/writable* 8-bit up-counter. When the timer enable bit (TME) in the timer control/status register (TCSR) is set to 1, the timer counter starts counting pulses of an internal clock source selected by clock select bits 2 to 0 (CKS2 to CKS0) in the TCSR. When the count overflows (changes from H'FF to H'00), an overflow flag (OVF) in the TCSR is set to 1. The watchdog timer counter is initialized to H'00 at a reset and when the TME bit is cleared to 0. * TCNT is write-protected by a password. See section 13.2.4, “Notes on Register Access” for details. 13.2.2 Timer Control/Status Register (TCSR)—H'FEEC Bit 7 6 5 4 3 2 1 0 OVF WT/IT TME — — CKS2 CKS1 CKS0 Initial value 0 0 0 1 1 0 0 0 Read/Write R/(W)*1 R/W R/W — — R/W R/W R/W The watchdog timer control/status register (TCSR) is an 8-bit readable/writable*2 register that selects the timer mode and clock source and performs other functions. Bits 7 to 5 are initialized to 0 at a reset and in the standby modes. Bits 2 to 0 are initialized to 0 at a reset, but retain their values in the standby modes. *1 Software can write a 0 in bit 7 to clear the flag, but cannot set this bit to 1. *2 The TCSR is write-protected by a password. See section 13.2.4, “Notes on Register Access” for details. 243 Bit 7—Overflow Flag (OVF): This bit indicates that the watchdog timer count has overflowed. Bit 7 OVF 0 Description This bit is cleared to from 1 to 0 when the CPU reads (Initial value) the OVF bit after it has been set to 1, then writes a 0 in this bit. 1 This bit is set to 1 when TCNT changes from H'FF to H'00.* * OVF is not set in watchdog timer mode. Bit 6—Timer Mode Select (WT/IT): This bit selects whether to operate in the watchdog timer mode or interval timer mode. Bit 6 WT/IT 0 1 Description Interval timer mode (interval timer interrupt request) Watchdog timer mode (reset) (Initial value) Bit 5—Timer Enable (TME): This bit enables or disables the timer. Bit 5 TME 0 1 Description TCNT is initialized to H'00 and stopped. (Initial value) TCNT runs. A reset or interrupt request is generated when the count overflows. Bits 4 and 3—Reserved: These bits cannot be modified and are always read as 1. Bits 2, 1, and 0—Clock Select (CKS2, CKS1, and CKS0): These bits select one of eight clock sources obtained by dividing the system clock (ø). The overflow interval listed in the table below is the time from when the watchdog timer counter begins counting from H'00 until an overflow occurs. 244 Bit 2 CKS2 0 0 0 0 1 1 1 1 Bit 1 CKS1 0 0 1 1 0 0 1 1 Bit 0 CKS0 0 1 0 1 0 1 0 1 Clock Source ø/2 ø/32 ø/64 ø/128 ø/256 ø/512 ø/2048 ø/4096 Description Overflow Interval (ø = 10 MHz) 51.2µs (Initial value) 819.2µs 1.6ms 3.3ms 6.6ms 13.1ms 52.4ms 104.9ms 13.2.3 Reset Control/Status Register (RSTCSR)—H'FF14 (Write), H'FF15 (Read) Bit 7 6 5 4 3 2 1 0 WRST RSTOE Initial value 0 0 1 1 1 1 1 1 Read/Write R/(W)*1 R/W — — — — — — The reset control/status register (RSTCSR) is an 8-bit readable/writable*2 register that indicates when a reset has been caused by a watchdog timer overflow, and controls external output of the reset signal. Bit 6 is not initialized by the reset caused by the watchdog timer overflow. It is initialized, however, by a reset caused by input at the RES pin. *1 Software can write a 0 in bit 7 to clear the flag, but cannot set this bit to 1. *2 The RSTCSR is write-protected by a password. See section 13.2.4, “Notes on Register Access” for details. Bit 7—Watchdog Timer Reset (WRST): This bit indicates that a reset signal has been generated by a watchdog timer overflow in the watchdog timer mode. The reset signal generated by the overflow resets the entire H8/534 or H8/536 chip. In addition, if the reset output enable (RSTOE) bit is set to 1, the reset signal (Low) is output at the RES pin to reset devices connected to the H8/534 or H8/536. The WRST bit can be cleared by software by writing a 0. It is also cleared when a reset signal from an external device is received at the RES pin. 245 Bit 7 WRST 0 1 Description This bit is cleared to 0 by a reset signal input from the RES pin, (Initial state) or when the CPU reads WRST after it has been set to 1, then writes a 0 in this bit. This bit is set to 1 when the watchdog timer overflows in the watchdog timer mode and an internal reset signal is generated. Bit 6—Reset Output Enable (RSTOE): This bit selects whether the reset signal generated by a watchdog timer overflow in the watchdog timer mode is output from the RES pin. Bit 6 RSTOE 0 1 Description The reset signal generated by watchdog timer overflow is not (Initial state) output to external devices. The reset signal generated by watchdog timer overflow is output to external devices. Bits 5 to 0—Reserved: These bits cannot be modified and are always read as 1. 13.2.4 Notes on Register Access The watchdog timer’s TCNT, TCSR, and RSTCSR registers differ from other registers in being more difficult to write. The procedures for writing and reading these registers are given below. Writing to TCNT and TCSR: These registers must be written by word access. Programs cannot write to them by byte access. The word must contain the write data and a password. The watchdog timer’s TCNT and TCSR registers both have the same write address. The write data must be contained in the lower byte of the word written at this address. The upper byte must contain H'5A (password for TCNT) or H'A5 (password for TCSR). See figure 13-2. The result of the access depicted in figure 13-2 is to transfer the write data from the lower byte to the TCNT or TCSR. 246 Write to TCNT 15 Address H'FFEC Write to TCSR 8 H'5A 15 Address 7 H'FFEC 0 Write data 8 7 H'A5 0 Write data Figure 13-2 Writing to TCNT and TCSR Writing to RSTCSR: The RSTCSR must be written by moving word data to address H'FF14. It cannot be written by byte access. The upper byte of the word must contain a password. Separate passwords are used for clearing the WRST bit and for writing a 1 or 0 to the RSTOE bit. To clear the WRST bit, the word written at address H'FF14 must contain the password H'A5 in the upper byte and the data H'00 in the lower byte. This clears the WRST bit to 0. To set or clear the RSTOE bit, the word written at address H'FF14 must contain the password H'5A in the upper byte and the write data in the lower byte. The value of bit 6 in the lower byte is written in the RSTOE bit. These write operations are illustrated in figure 13-3. To write 0 to the WRST bit Address 15 H'FF14 To write to the RSTOE bit Address 8 7 H'A5 15 H'FF14 H'00 8 H'5A Figure 13-3 Writing to RSTCSR 247 0 7 0 Write data Reading TCNT, TCSR, and RSTCSR: The read addresses are H'FEEC for TCSR, H'FEED for TCNT, and H'FF15 for RSTCSR as indicated in table 13-2. These three registers are read like other registers. Byte access instructions can be used. Table 13-2 Read Addresses of TCNT and TCSR Read Address H'FFEC H'FFED H'FF15 Register TCSR TCNT RSTCSR 13.3 Operation 13.3.1 Watchdog Timer Mode The watchdog timer function begins operating when software sets the WT/IT and TME bits to 1 in the TCSR. Thereafter, software should periodically rewrite the contents of the timer counter (normally by writing H'00) to prevent the count from overflowing. If a program crash allows the timer count to overflow, the watchdog timer generates a reset as shown in figure 13-4. The reset signal from the watchdog timer can also be output from the RES pin to reset external devices. This reset output signal is a Low pulse with a duration of 132 ø clock periods. The reset signal is output only if the RSTOE bit in the RSTCSR is set to 1. The reset generated by the watchdog timer has the same vector as a reset generated by Low input at the RES pin. Software should check the WRST bit in the RSTCSR to determine the source of the reset. If a watchdog timer overflow occurs at the same time as a Low input at the RES pin, priority is given to one type of reset or the other depending on the value of the RSTOE bit in the RSTCSR. If the RSTOE bit is set to 1 when both types of reset occur simultaneously, the watchdog timer’s reset signal takes precedence. The internal state of the H8/534 or H8/536 chip is reset and the RES pin is held Low for 132 ø clock periods. If at the end of 520 ø clock periods there is still an external Low input to the RES pin, the external reset takes effect, clearing the WRST and RSTOE bits to 0. Note that if the external reset occurs before the watchdog timer overflows, it takes effect immediately and clears the RSTOE bit. If the RSTOE bit is cleared to 0 when both types of reset occur simultaneously, the reset signal input from the RES pin takes precedence and the WRST bit is cleared to 0. 248 Watchdog timer overflow H'FF TCNT count H'00 OVF = 1 Start H'00 written to TCNT Reset Start H'00 written to TCNT Internal reset signal * External reset signal (RES) * The reset signals are output for 132 ø clock periods. The internal reset signal remains valid for 520 ø clock periods. Figure 13-4 Operation in Watchdog Timer Mode 13.3.2 Interval Timer Mode Interval timer operation begins when the WT/IT bit is cleared to 0 and the TME bit is set to 1. In the interval timer mode, an interval timer interrupt request is generated each time the timer count overflows. This function can be used to generate interrupts at regular intervals. See figure 13-5. H'FF TCNT count Time t H'00 WT/IT = 0 TME = 1 * * * * * Interval timer interrupt request Figure 13-5 Operation in Interval Timer Mode 249 * 13.3.3 Operation in Software Standby Mode The watchdog timer has a special function in recovery from software standby mode. Specific watchdog timer settings are required when the software standby mode is used. Before Transition to the Software Standby Mode: The TME bit must be cleared to 0 to stop the watchdog timer counter before a transition to the software standby mode. The chip cannot enter the software standby mode while the TME bit is set to 1. Before entering the software standby mode, software should also set the clock select bits (CKS2 to CKS0) to a value that makes the timer overflow interval equal to or greater than the stabilization time of the clock oscillator. Recovery from the Software Standby Mode: Recovery from the software standby mode can be triggered by an NMI request. In this case the recovery proceeds as follows: When an NMI request signal is received, the clock oscillator starts running and the watchdog timer starts counting at the rate selected by the clock select bits before the software standby mode was entered. When the count overflows from H'FF to H'00, the ø clock is presumed to be stable and usable, clock signals are supplied to all modules on the chip, the standby mode ends, and the NMI interrupt-handling routine starts executing. 13.3.4 Setting of Overflow Flag The OVF bit is set to 1 when the timer count overflows in the interval timer mode. Simultaneously, the WDT module requests an interval timer interrupt. The timing is shown in figure 13-6. ø TCNT H'FF H'00 Internal overflow signal OVF Figure 13-6 Setting of OVF Bit 250 13.3.5 Setting of Watchdog Timer Reset (WRST) Bit The WRST bit is valid when WT/IT = 1 and TME = 1. The WRST bit is set to 1 when the timer count overflows. An internal reset signal is simultaneously generated for the entire H8/534 or 536 chip. The timing is shown in figure 13-7. ø TCNT H'FF H'00 Overflow signal WRST Internal reset signal Figure 13-7 Setting of WRST Bit and Internal Reset Signal 251 13.4 Application Notes Contention between TCNT Write and Increment: If a timer counter clock pulse is generated during the T3 state of a write cycle to the timer counter, the write operation takes priority and the timer counter is not incremented. See figure 13-8. Write cycle: CPU writes to TCNT T1 T2 T3 ø Internal address bus TCNT address Internal write signal TCNT clock pulse TCNT N M Counter write data Figure 13-8 TCNT Write-Increment Contention Changing the Clock Select Bits (CKS2 to CKS0): Software should stop the watchdog timer (by clearing the TME bit to 0) before changing the value of the clock select bits. If the clock select bits are modified while the watchdog timer is running, the timer count may be incremented incorrectly. Use of Reset Output: When the reset signal is output to external devices, special circuitry is needed for input of the external reset signal. The reset output is an NMOS open-drain output. Figure 13-9 shows an example of a reset circuit. 252 4.7 kΩ H8/534 H8/536 74LS05 External reset signal RES 60 pF * 2SC2618 or equivalent 100 kΩ Reset switch 74HC14 1.0 kΩ 1.0 µF * Maximum value of wiring capacitance Figure 13-9 Reset Circuit (Example) 253 Section 14 Serial Communication Interface 14.1 Overview The H8/534 and H8/536 have two serial communication interface channels (SCI1 and SCI2) for transferring serial data to and from other chips. Each channel supports both synchronous and asynchronous data transfer. Communication control functions are provided by eight internal registers. 14.1.1 Features The features of the on-chip serial communication interface are: • Selection of asynchronous or synchronous mode — Asynchronous mode SCI1 and SCI2 can communicate with a UART (Universal Asynchronous Receiver/Transmitter), ACIA (Asynchronous Communication Interface Adapter), or other chip that employs standard asynchronous serial communication. Eight data formats are available. — Data length: 7 or 8 bits — Stop bit length: 1 or 2 bits — Parity: Even, odd, or none — Error detection: Parity, overrun, and framing errors — Synchronous mode SCI1 and SCI2 can communicate with chips able to synchronize data transfers with clock pulses. — Data length: 8 bits — Error detection: Overrun errors • Full duplex communication The transmitting and receiving sections are independent, so each channel can transmit and receive simultaneously. Both the transmit and receive sections use double buffering, so continuous data transfer is possible in either direction. • Built-in baud rate generator Any specified bit rate can be generated. • Internal or external clock source The baud rate generator can operate on an internal clock source, or an external clock signal input at the SCK pin. • Three interrupts Transmit-end, receive-end, and receive-error interrupts are requested independently. The transmit-end and receive-end interrupts can be served by the on-chip data transfer controller (DTC), providing a convenient way to transfer data with minimal CPU programming. 255 14.1.2 Block Diagram Bus interface Figure 14-1 shows a block diagram of one serial communication interface channel. Module data bus RDR TDR Internal clock source ø BRR SSR SCR Baud-rate generator SMR RXD RSR TSR ø/4 ø/16 Communication control TXD Internal data bus ø/64 Parity generator Parity check Clock External clock SCK TXI RXI RDR: Receive Data Register RSR: Receive Shift Register TDR: Transmit Data Register TSR: Transmit Shift Register SSR: Serial Status Register SCR: Serial Control Register SMR: Serial Mode Register BRR: Bit Rate Register ERI Interrupt signals Figure 14-1 Block Diagram of Serial Communication Interface 256 14.1.3 Input and Output Pins Table 14-1 lists the input and output pins used by the SCI module. Table 14-1 SCI Input/Output Pins Channel 1 2 Name Serial clock Receive data Transmit data Serial clock Receive data Transmit data Abbreviation SCK1 RXD1 TXD1 SCK2 RXD2 TXD2 I/O Input/output Input Output Input/output Input Output Function Serial clock input and output. Receive data input. Transmit data output. Serial clock input and output. Receive data input. Transmit data output. 14.1.4 Register Configuration Table 14-2 lists the SCI registers. Table 14-2 SCI Registers Channel 1 Name Abbreviation R/W Initial Value Receive shift register RSR — — Receive data register RDR R H'00 Transmit shift register TSR — — Transmit data register TDR R/W H'FF Serial mode register SMR R/W H'04 Serial control register SCR R/W H'0C Serial status register SSR R/(W)* H'87 Bit rate register BRR R/W H'FF 2 Receive shift register RSR — — Receive data register RDR R H'00 Transmit shift register TSR — — Transmit data register TDR R/W H'FF Serial mode register SMR R/W H'04 Serial control register SCR R/W H'0C Serial status register SSR R/(W)* H'87 Bit rate register BRR R/W H'FF * Software can write a 0 to clear the status flag bits, but cannot write a 1. 257 Address — H'FEDD — H'FEDB H'FED8 H'FEDA H'FEDC H'FED9 — H'FEF5 — H'FEF3 H'FEF0 H'FEF2 H'FEF4 H'FEF1 14.2 Register Descriptions 14.2.1 Receive Shift Register (RSR) Bit 7 6 5 4 3 2 1 0 Read/Write — — — — — — — — The RSR receives incoming data bits. When one data character has been received, it is transferred to the receive data register (RDR). The CPU cannot read or write the RSR directly. 14.2.2 Receive Data Register (RDR)—H'FEDD, H'FEF5 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R The RDR stores received data. As each character is received, it is transferred from the RSR to the RDR, enabling the RSR to receive the next character. This double-buffering allows the SCI to receive data continuously. The CPU can read but not write the RDR. The RDR is initialized to H'00 at a reset and in the standby modes. 14.2.3 Transmit Shift Register (TSR) Bit 7 6 5 4 3 2 1 0 Read/Write — — — — — — — — The TSR holds the character currently being transmitted. When transmission of this character is completed, the next character is moved from the transmit data register (TDR) to the TSR and transmission of that character begins. If the TDR does not contain valid data, the SCI stops transmitting. The CPU cannot read or write the TSR directly. 258 14.2.4 Transmit Data Register (TDR)—H'FEDB, H'FEF3 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The TDR is an 8-bit readable/writable register that holds the next character to be transmitted. When the TSR becomes empty, the character written in the TDR is transferred to the TSR. Continuous data transmission is possible by writing the next byte in the TDR while the current byte is being transmitted from the TSR. The TDR is initialized to H'FF at a reset and in the standby modes. 14.2.5 Serial Mode Register (SMR)—H'FED8, H'FEF0 Bit 7 6 5 4 3 2 1 0 C/A CHR PE O/E STOP — CKS1 CKS0 Initial value 0 0 0 0 0 1 0 0 Read/Write R/W R/W R/W R/W R/W — R/W R/W The SMR is an 8-bit readable/writable register that controls the communication format and selects the clock rate for the internal clock source. It is initialized to H'04 at a reset and in the standby modes. Bit 7—Communication Mode (C/A): This bit selects the asynchronous or synchronous communication mode. Bit 7 C/A 0 1 Description Asynchronous communication. (Initial value) Communication is synchronized with the serial clock. Bit 6—Character Length (CHR): This bit selects the character length in asynchronous mode. It is ignored in synchronous mode. Bit 6 CHR 0 1 Description 8 Bits per character. 7 Bits per character. (Initial value) 259 Bit 5—Parity Enable (PE): This bit selects whether to add a parity bit in asynchronous mode. It is ignored in synchronous mode. Bit 5 PE 0 1 Description Transmit: No parity bit is added. Receive: Parity is not checked. Transmit: A parity bit is added. Receive: Parity is not checked. (Initial value) Bit 4—Parity Mode (O/E): In asynchronous mode, when parity is enabled (PE = 1), this bit selects even or odd parity. Even parity means that a parity bit is added to the data bits for each character to make the total number of 1’s even. Odd parity means that the total number of 1’s is made odd. This bit is ignored when PE = 0 and in the synchronous mode. Bit 4 O/E 0 1 Description Even parity. Odd parity. (Initial value) Bit 3—Stop Bit Length (STOP): This bit selects the number of stop bits. It is ignored in the synchronous mode. Bit 3 STOP 0 1 Description 1 Stop bit. 2 Stop bits. (Initial value) Bit 2—Reserved: This bit cannot be modified and is always read as 1. Bits 1 and 0—Clock Select 1 and 0 (CKS1 and CKS0): These bits select the internal clock source when the baud rate generator is clocked from within the H8/534 or H8/536 chip. Bit 1 CKS1 0 0 1 1 Bit 0 CKS0 0 1 0 1 Description ø clock ø/4 clock ø/16 clock ø/64 clock (Initial value) 260 14.2.6 Serial Control Register (SCR)—H'FEDA, H'FEF2 Bit 7 6 5 4 3 2 1 0 TIE RIE TE RE — — CKE1 CKE0 Initial value 0 0 0 0 1 1 0 0 Read/Write R/W R/W R/W R/W — — R/W R/W The SCR is an 8-bit readable/writable register that enables or disables various SCI functions. It is initialized to H'0C at a reset and in the standby modes. Bit 7—Transmit Interrupt Enable (TIE): This bit enables or disables the transmit-end interrupt (TXI) requested when the transmit data register empty (TDRE) bit in the serial status register (SSR) is set to 1. Bit 7 TIE 0 1 Description The transmit-end interrupt request (TXI) is disabled. The transmit-end interrupt request (TXI) is enabled. (Initial value) Bit 6—Receive Interrupt Enable (RIE): This bit enables or disables the receive-end interrupt (RXI) requested when the receive data register full (RDRF) bit in the serial status register (SSR) is set to 1. It also enables and disables the receive-error interrupt (ERI) request. Bit 6 RIE 0 1 Description The receive-end interrupt (RXI) and receive-error interrupt (ERI) (Initial value) requests are disabled. The receive-end interrupt (RXI) and receive-error interrupt (ERI) requests are enabled. Bit 5—Transmit Enable (TE): This bit enables or disables the transmit function. When the transmit function is enabled, the TXD pin is automatically used for output. When the transmit function is disabled, the TXD pin can be used as a general-purpose I/O port. Bit 5 TE 0 1 Description The transmit function is disabled. The TXD pin can be used as a general-purpose I/O port. The transmit function is enabled. The TXD pin is used for output. 261 (Initial value) Bit 4—Receive Enable (RE): This bit enables or disables the receive function. When the receive function is enabled, the RXD pin is automatically used for input. When the receive function is disabled, the RXD pin is available as a general-purpose I/O port. Bit 4 RE 0 1 Description The receive function is disabled. The RXD pin can be used as a general-purpose I/O port. The receive function is enabled. The RXD pin is used for input. (Initial value) Bits 3 and 2—Reserved: These bits cannot be modified and are always read as 1. Bit 1—Clock Enable 1 (CKE1): This bit selects the internal or external clock source for the baud rate generator. When the external clock source is selected, the SCK pin is automatically used for input of the external clock signal. Bit 1 CKE1 0 1 Description Internal clock source. External clock source. (The SCK pin is used for input.) (Initial value) Bit 0—Clock Enable 0 (CKE0): When an internal clock source is used in synchronous mode, this bit enables or disables serial clock output at the SCK pin. This bit is ignored when the external clock is selected, or when the asynchronous mode is selected. For further information on the communication format and clock source selection, see tables 14-5 and 14-6 in section 14.3, “Operation.” Bit 0 CKE0 0 1 Description The SCK pin is not used by the SCI (and is available as a general-purpose I/O port). The SCK pin is used for serial clock output. 262 (Initial value) 14.2.7 Serial Status Register (SSR)—H'FEDC, H'FEF4 Bit 7 6 5 4 3 2 1 0 TDRE RDRF ORER FER PER — — — Initial value 1 0 0 0 0 1 1 1 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* — — — * Software can write a 0 to clear the flags, but cannot write a 1 in these bits. The SSR is an 8-bit register that indicates transmit and receive status. It is initialized to H'87 at a reset and in the standby modes. Bit 7—Transmit Data Register Empty (TDRE): This bit indicates when the TDR contents have been transferred to the TSR and the next character can safely be written in the TDR. Bit 7 TDRE 0 1 Description This bit is cleared from 1 to 0 when: 1. The CPU reads the TDRE bit after it has been set to 1, then writes a 0 in this bit. 2. The data transfer controller (DTC) writes data in the TDR. This bit is set to 1 at the following times: (Initial value) 1. The chip is reset or enters a standby mode. 2. When TDR contents are transferred to the TSR. 3. When TDRE = 0 and the TE bit is cleared to 0. Bit 6—Receive Data Register Full (RDRF): This bit indicates when one character has been received and transferred to the RDR. Bit 6 RDRF 0 1 Description This bit is cleared from 1 to 0 when: (Initial value) 1. The CPU reads the RDRF bit after it has been set to 1, then writes a 0 in this bit. 2. The data transfer controller (DTC) reads the RDR. 3. The chip is reset or enters a standby mode. This bit is set to 1 when one character is received without error and transferred from the RSR to the RDR. 263 Bit 5—Overrun Error (ORER): This bit indicates an overrun error during reception. Bit 5 ORER 0 1 Description This bit is cleared from 1 to 0 when: (Initial value) 1. The CPU reads the ORER bit after it has been set to 1, then writes a 0 in this bit. 2. The chip is reset or enters a standby mode. This bit is set to 1 if reception of the next character ends while the receive data register is still full (RDRF = 1). Bit 4—Framing Error (FER): This bit indicates a framing error during data reception in the synchronous mode. It has no meaning in the asynchronous mode. Bit 4 FER 0 1 Description This bit is cleared to from 1 to 0 when: (Initial value) 1. The CPU reads the FER bit after it has been set to 1, then writes a 0 in this bit. 2. The chip is reset or enters a standby mode. This bit is set to 1 if a framing error occurs (stop bit = 0). Bit 3—Parity Error (PER): This bit indicates a parity error during data reception in the asynchronous mode, when a communication format with parity bits is used. This bit has no meaning in the synchronous mode, or when a communication format without parity bits is used. Bit 3 PER 0 1 Description This bit is cleared from 1 to 0 when: (Initial value) 1. The CPU reads the PER bit after it has been set to 1, then writes a 0 in this bit. 2. The chip is reset or enters a standby mode. This bit is set to 1 when a parity error occurs (the parity of the received data does not match the parity selected by the bit in the SMR). Bits 2 to 0—Reserved: These bits cannot be modified and are always read as 1. 264 14.2.8 Bit Rate Register (BRR)—H'FED9, H'FEF1 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The BRR is an 8-bit register that, together with the CKS1 and CKS0 bits in the SMR, determines the bit rate output by the baud rate generator. The BRR is initialized to H'FF (the slowest rate) at a reset and in the standby modes. Tables 14-3 and 14-4 show examples of BRR (N) and CKS (n) settings for commonly used bit rates. Table 14-3 Examples of BRR Settings in Asynchronous Mode (1) 2 Bit Rate 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 1 0 0 0 0 0 — — — — — N 70 207 103 51 25 12 — — — — — Error (%) +0.03 +0.16 +0.16 +0.16 +0.16 +0.16 — — — — — n 1 0 0 0 0 0 0 0 0 — 0 XTAL Frequency (MHz) 2.4576 4 Error N (%) n N 86 +0.31 1 141 255 0 1 103 127 0 0 207 63 0 0 103 31 0 0 51 15 0 0 25 7 0 0 12 3 0 — — 1 0 — — — — 0 1 0 0 — — 265 Error (%) +0.03 +0.16 +0.16 +0.16 +0.16 +0.16 +0.16 — — 0 — n 1 1 0 0 0 0 0 — — — — 4.194304 Error N (%) 148 –0.04 108 +0.21 217 +0.21 108 +0.21 54 –0.70 26 +1.14 13 –2.48 — — — — — — — — Table 14-3 Examples of BRR Settings in Asynchronous Mode (2) Bit Rate 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 1 1 0 0 0 0 0 0 0 — 0 4.9152 Error N (%) 174 –0.26 127 0 255 0 127 0 63 0 31 0 15 0 7 0 3 0 — — 1 0 n 2 1 1 0 0 0 0 — — 0 — XTAL Frequency (MHz) 6 7.3728 Error Error N (%) n N (%) 52 +0.50 2 64 +0.70 155 +0.16 1 191 0 77 +0.16 1 95 0 155 +0.16 0 191 0 77 +0.16 0 95 0 38 +0.16 0 47 0 19 –2.34 0 23 0 — — 0 11 0 — — 0 5 0 2 0 — — — — — 0 2 0 8 Error (%) +0.03 +0.16 +0.16 +0.16 +0.16 +0.16 +0.16 +0.16 — 0 — n 2 1 1 0 0 0 0 0 — 0 — N 70 207 103 207 103 51 25 12 — 3 — n 2 2 1 1 0 0 0 0 0 0 0 12.288 Error N (%) 108 +0.08 79 0 159 0 79 0 159 0 79 0 39 0 19 0 9 0 5 +2.40 4 0 Table 14-3 Examples of BRR Settings in Asynchronous Mode (3) Bit Rate 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 2 1 1 0 0 0 0 0 0 0 0 9.8304 Error N (%) 86 +0.31 255 0 127 0 255 0 127 0 63 0 31 0 15 0 7 0 4 –1.70 3 0 n 2 2 1 1 0 0 0 0 0 0 0 XTAL Frequency (MHz) 10 12 Error N (%) n N 88 –0.25 2 106 64 +0.16 2 77 129 +0.16 1 155 64 +0.16 1 77 129 +0.16 0 155 64 +0.16 0 77 32 –1.36 0 38 15 +1.73 0 19 7 +1.73 — — 4 0 0 5 3 +1.73 — — 266 Error (%) –0.44 0 0 0 +0.16 +0.16 +0.16 –2.34 — 0 — Table 14-3 Examples of BRR Settings in Asynchronous Mode (4) Bit Rate 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 2 2 1 1 0 0 0 0 0 — 0 14.7456 Error N (%) 130 –0.07 95 0 191 0 95 0 191 0 95 0 47 0 23 0 11 0 — — 5 0 n 2 2 1 1 0 0 0 0 0 0 — 24 Bit Rate 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 2 2 2 1 1 0 0 0 0 0 0 N 212 155 77 155 77 155 77 38 19 11 9 Error (%) 0.03 0.16 0.16 0.16 0.16 0.16 0.16 0.16 –2.34 0.00 –2.34 n 2 2 2 1 1 0 0 0 0 0 0 XTAL Frequency (MHz) 16 19.6608 Error Error N (%) n N (%) 141 +0.03 2 174 –0.26 103 +0.16 2 127 0 207 +0.16 1 255 0 103 +0.16 1 127 0 207 +0.16 0 255 0 103 +0.16 0 127 0 51 +0.16 0 63 0 25 +0.16 0 31 0 12 +0.16 0 15 0 7 0 0 9 –1.70 — — 0 7 0 XTAL Frequency (MHz) 24.576 28 Error Error N (%) n N (%) 217 0.08 2 248 –0.17 159 0.00 2 181 0.16 79 0.00 2 90 0.16 159 0.00 1 181 0.16 79 0.00 1 90 0.16 159 0.00 0 181 0.16 79 0.00 0 90 0.16 39 0.00 0 45 –0.93 19 0.00 0 22 –0.93 11 2.40 0 13 0.00 9 0.00 0 10 3.57 n 3 2 2 1 1 0 0 0 0 0 0 Note: If possible, select a setting such that the error is 1% or less. B = OSC × 106/[64 × 22n × (N + 1)] B: N: OSC : n: Bit rate BRR value (0 ≤ N ≤ 255) Crystal oscillator frequency in MHz Internal clock source (0, 1, 2, or 3) 267 20 n 3 2 2 1 1 0 0 0 0 0 0 29.4912 Error N (%) 64 0.70 191 0.00 95 0.00 191 0.00 95 0.00 191 0.00 95 0.00 47 0.00 23 0.00 14 –1.70 11 0.00 N 43 129 64 129 64 129 64 32 15 9 7 Error (%) +0.88 +0.16 +0.16 +0.16 +0.16 +0.16 +0.16 –1.36 +1.73 0 +1.73 32 n 3 2 2 1 1 0 0 0 0 0 0 N 70 207 103 207 103 207 103 51 25 15 12 Error (%) 0.03 0.16 0.16 0.16 0.16 0.16 0.16 0.16 0.16 0.00 0.16 The meaning of n is given by the table below: n 0 1 2 3 CKS1 0 0 1 1 CKS0 0 1 0 1 Clock ø ø/4 ø/16 ø/64 The error in asynchronous mode is calculated as follows: Error (%) = { OSC × 106 B × 64 × 22n × (N + 1) –1 × 100 } 268 Table 14-4 Examples of BRR Settings in Synchronous Mode Bit Rate 100 250 500 1k 2.5k 5k 10k 25k 50k 100k 250k 500k 1M 2.5M 2 n — 1 1 0 0 0 0 0 0 — 0 4 N — 249 124 249 99 49 24 9 4 — 0* n — 2 1 1 0 0 0 0 0 0 0 0 N — 124 249 124 199 99 49 19 9 4 1 0* XTAL Frequency (MHz) 8 10 16 n N n N n N — — — — — — 2 249 — — 3 124 2 124 — — 2 249 1 249 — — 2 124 1 99 1 124 1 199 0 199 0 249 1 99 0 99 0 124 0 199 0 39 0 49 0 79 0 19 0 24 0 39 0 9 — — 0 19 0 3 0 4 0 7 0 1 — — 0 3 0 0* — — 0 1 Notes: Blank: No setting is available. —: A setting is available, but the bit rate is inaccurate. *: Continuous transfer is not possible. B = OSC/[8 × 22n × (N + 1)] B: N: OSC : n: Bit rate BRR value (0 ≤ N ≤ 255) Crystal oscillator frequency in MHz Internal clock source (0, 1, 2, or 3) The meaning of n is given by the table below: n 0 1 2 3 CKS1 0 0 1 1 CKS0 0 1 0 1 Clock ø ø/4 ø/16 ø/64 269 20 n — — — — 1 1 0 0 0 0 0 0 — 0 32 N — — — — 249 124 249 99 49 24 9 4 — 0* n — 3 3 2 2 1 1 0 0 0 0 0 0 — N — 249 124 249 99 199 99 159 79 39 15 7 3 — 14.3 Operation 14.3.1 Overview Each serial communication interface channel supports serial data transfer in both asynchronous and synchronous modes. The communication format depends on settings in the SMR as indicated in table 14-5. The clock source and usage of the SCK pin depend on settings in the SMR and SCR as indicated in table 14-6. Table 14-5 Communication Formats Used by SCI C/A 0 SMR CHR PE 0 0 1 1 0 1 1 — — STOP 0 1 0 1 0 1 0 1 — Mode Asynchronous Format 8-Bit data Parity None Yes 7-Bit data None Yes Synchronous 8-Bit data — Stop Bit Length 1 2 1 2 1 2 1 2 — Table 14-6 SCI Clock Source Selection SMR C/A 0 (Async mode) SCR Clock CKE1 CKE0 Source 0 0 Internal 1 1 0 External 1 1 0 0 Internal (Sync 1 mode) 1 0 External 1 * Cannot be used by the SCI. SCK Pin I/O port* Clock output at same frequency as baud rate Clock input at 16 times the baud rate frequency Serial clock output Serial clock input Transmitting and receiving operations in the two modes are described next. 270 14.3.2 Asynchronous Mode In asynchronous mode, each character is individually synchronized by framing it with a start bit and stop bit. Full duplex data transfer is possible because the SCI has independent transmit and receive sections. Double buffering in both sections enables the SCI to be programmed for continuous data transfer. Figure 14-2 shows the general format of one character sent or received in the asynchronous mode. The communication channel is normally held in the mark state (High). Character transmission or reception starts with a transition to the space state (Low). The first bit transmitted or received is the start bit (Low). It is followed by the data bits, in which the least significant bit (LSB) comes first. The data bits are followed by the parity bit, if present, then the stop bit or bits (High) confirming the end of the frame. In receiving, the SCI synchronizes on the falling edge of the start bit, and samples each bit at the center of bit (at the 8th cycle of the internal serial clock, which runs at 16 times the bit rate). Idle state Start bit 1 bit D0 D1 Dn 7 or 8 bits Parity bit Stop bit 0 or 1 bit 1 or 2 bits One character Figure 14-2 Data Format in Asynchronous Mode 1. Data Format: Table 14-7 lists the data formats that can be sent and received in asynchronous mode. Eight formats can be selected by bits in the SMR. 271 Table 14-7 Data Formats in Asynchronous Mode SMR Bits CHR PE STOP Data Format 0 0 0 START 8-Bit data STOP 0 0 1 START 8-Bit data STOP STOP 0 1 0 START 8-Bit data P STOP 0 1 1 START 8-Bit data P STOP 1 0 0 START 7-Bit data STOP 1 0 1 START 7-Bit data STOP STOP 1 1 0 START 7-Bit data P STOP 1 1 1 START 7-Bit data P STOP STOP STOP Note: START: Start bit STOP: Stop bit P: Parity bit 2. Clock: In the asynchronous mode it is possible to select either an internal clock created by the on-chip baud rate generator, or an external clock input at the SCK pin. Refer to table 14-6. If an external clock is input at the SCK pin, its frequency should be 16 times the desired baud rate. If the internal clock provided by the on-chip baud rate generator is selected and the SCK pin is used for clock output, the output clock frequency is equal to the baud rate, and the clock pulse rises at the center of the transmit data bits. Figure 14-3 shows the phase relationship between the output clock and transmit data. Output clock Transmit data Start bit D0 D1 D2 Figure 14-3 Phase Relationship between Clock Output and Transmit Data 272 Fig. 14-3 3. Data Transmission and Reception • SCI Initialization: Before data can be transmitted or received, the SCI must be initialized by software. To initialize the SCI, software must clear the TE and RE bits to 0, then execute the following procedure. (1) Set the desired communication format in the SMR. (2) Write the value corresponding to the desired bit rate in the BRR. (This step is not necessary if an external clock is used.) (3) Select the clock and enable desired interrupts in the SCR. (4) Set the TE and/or RE bit in the SCR to 1. The TE and RE bits must both be cleared to 0 whenever the operating mode or data format is changed. After changing the operating mode or data format, before setting the TE and RE bits to 1 software must wait for at least the transfer time for 1 bit at the selected baud rate, to make sure the SCI is initialized. If an external clock is used, the clock must not be stopped. When clearing the TDRE bit during data transmission, to assure transfer of the correct data, do not clear the TDRE bit until after writing data in the TDR. Similarly, in receiving data, do not clear the RDRF bit until after reading data from the RDR. • Data Transmission: The procedure for transmitting data is as follows. (1) Set up the desired transmitting conditions in the SMR, SCR, and BRR. (2) Set the TE bit in the SCR to 1. The TXD pin will automatically be switched to output and one frame* of all 1’s will be transmitted, after which the SCI is ready to transmit data. (3) Check that the TDRE bit is set to 1, then write the first byte of transmit data in the TDR. Next clear the TDRE bit to 0. * A frame is the data for one character, including the start bit and stop bit(s). 273 (4) The first byte of transmit data is transferred from the TDR to the TSR and sent in the designated format as follows. i) Start bit (one 0 bit) ii) Transmit data (seven or eight bits, starting from bit 0) iii) Parity bit (odd or even parity bit, or no parity bit) iv) Stop bit (one or two consecutive 1 bits) (5) Transfer of the transmit data from the TDR to the TSR makes the TDR empty, so the TDRE bit is set to 1. If the TIE bit is set to 1, a transmit-end interrupt (TXI) is requested. When the transmit function is enabled but the TDR is empty (TDRE = 1), the output at the TXD pin is held at 1 until the TDRE bit is cleared to 0. • Data Reception: The procedure for receiving data is as follows. (1) Set up the desired receiving conditions in the SMR, SCR, and BRR. (2) Set the RE bit in the SCR to 1. The RXD pin will automatically be switched to input and the SCI is ready to receive data. (3) The SCI synchronizes with the incoming data by detecting the start bit, and places the received bits in the RSR. At the end of the data, the SCI checks that the stop bit is 1. (4) When a complete frame has been received, the SCI transfers the received data to the RDR so that it can be read. If the character length is 7 bits, the most significant bit of the RDR is cleared to 0. At the same time, the SCI sets the RDRF bit in the SSR to 1. If the RIE bit is set to 1, a receive-end interrupt (RXI) is requested. (5) The RDRF bit is cleared to 0 when the CPU reads the SSR, then writes a 0 in the RDRF bit, or when the RDR is read by the data transfer controller (DTC). The RDR is then ready to receive the next character from the RSR. When a frame is not received correctly, a receive error occurs. There are three types of receive errors, listed in table 14-8. If a receive error occurs, the RDRF bit in the SSR is not set to 1. The corresponding error flag is set to 1 instead. If the RIE bit in the SCR is set to 1, a receive-error interrupt (ERI) is requested. 274 When a framing or parity error occurs, the RSR contents are transferred to the RDR. If an overrun error occurs, however, the RSR contents are not transferred to the RDR. If multiple receive errors occur simultaneously, all the corresponding error flags are set to 1. To clear a receive-error flag (ORER, FER, or PER), software must read the SSR, then write a 0 in the flag bit. Table 14-8 Receive Errors Name Overrun error Abbreviation ORER Framing error FER Parity error PER Description Reception of the next frame ends while the RDRF bit is still set to 1. The RSR contents are not transferred to the RDR. A stop bit is 0. The RSR contents are transferred to the RDR. The parity of a frame does not match the value selected by the bit in the SMR. The RSR contents are transferred to the RDR. 14.3.3 Synchronous Mode The synchronous mode is suited for high-speed, continuous data transfer. Each bit of data is synchronized with a serial clock pulse. Continuous data transfer is enabled by the double buffering employed in both the transmit and receive sections of the SCI. Full duplex communication is possible because the transmit and receive sections are independent. 1. Data Format: Figure 14-4 shows the communication format used in the synchronous mode. The data length is 8 bits for both the transmit and receive directions. The least significant bit (LSB) is sent and received first. Each bit of transmit data is output from the falling edge of the serial clock pulse to the next falling edge. Received bits are latched on the rising edge of the serial clock pulse. 275 Transmission direction Serial clock Data Bit 0 Bit 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Don’t-care Bit 7 Don’t-care Figure 14-4 Data Format in Synchronous Mode 2. Clock: Either the internal serial clock created by the on-chip baud rate generator or an external clock input at the SCK pin can be selected in the synchronous mode. See table 14-6 for details. 3. Data Transmission and Reception • SCI Initialization: Before data can be transmitted or received, the SCI must be initialized by software. To initialize the SCI, software must clear the TE and RE bits to 0 to disable both the transmit and receive functions, then execute the following procedure. (1) Write the value corresponding to the desired bit rate in the BRR. (This step is not necessary if an external clock is used.) (2) Select the clock in the SCR. (3) Select the synchronous mode in the SMR*. (4) Set the TE and/or RE bit to 1, and enable desired interrupts in the SCR. The TE and RE bits must both be cleared to 0 whenever the operating mode or data format is changed. After changing the operating mode or data format, before setting the TE and RE bits to 1 software must wait for at least 1 bit transfer time at the selected communication speed, to make sure the SCI is initialized. * The SCK pin is used for input or output according to the C/A bit in the serial mode register (SMR) and the CKE0 and CKE1 bits in the serial control register (SCR). (See table 14-6.) To prevent unwanted output at the SCK pin, pay attention to the order in which you set SMR and SCR. 276 When clearing the TDRE bit during data transmission, to assure correct data transfer, do not clear the TDRE bit until after writing data in the TDR. Similarly, in receiving data, do not clear the RDRF bit until after reading data from the RDR. • Data Transmission: The procedure for transmitting data is as follows. (1) Set up the desired transmitting conditions in the SMR, BRR, and SCR. (2) Set the TE bit in the SCR to 1. The TXD pin will automatically be switched to output, after which the SCI is ready to transmit data. (3) Check that the TDRE bit is set to 1, then write the first byte of transmit data in the TDR. Next clear the TDRE bit to 0. (4) The first byte of transmit data is transferred from the TDR to the TSR and sent, each bit synchronized with a clock pulse. Bit 0 is sent first. Transfer of the transmit data from the TDR to the TSR makes the TDR empty, so the TDRE bit is set to 1. If the TIE bit is set to 1, a transmit-end interrupt (TXI) is requested. The TDR and TSR function as a double buffer. Continuous data transmission can be achieved by writing the next transmit data in the TDR and clearing the TDRE bit to 0 while the SCI is transmitting the current data from the TSR. If an internal clock source is selected, after transferring the transmit data from the TDR to the TSR, while transmitting the data from the TSR the SCI also outputs a serial clock signal at the SCK pin. When all data bits in the TSR have been transmitted, if the TDR is empty (TDRE = 1), serial clock output is suspended until the next data byte is written in the TDR and the TDRE bit is cleared to 0. During this interval the TXD pin is held at the value of the last bit transmitted. If the external clock source is selected, data transmission is synchronized with the clock signal input at the SCK pin. When all data bits in the TSR have been transmitted, if the TDR is empty (TDRE = 1) but external clock pulses continue to arrive, the TXD output remains high. • Data Reception: The procedure for receiving data is as follows. (1) Set up the desired receiving conditions in the SMR, BRR, and SCR. 277 (2) Set the RE bit in the SCR to 1. The RXD pin will automatically be switched to input and the SCI is ready to receive data. (3) Incoming data bits are latched in the RSR on eight clock pulses. When 8 bits of data have been received, the SCI sets the RDRF bit in the SSR to 1. If the RIE bit is set to 1, a receive-end interrupt (RXI) is requested. (4) The SCI transfers the received data byte to the RDR so that it can be read. The RDRF bit is cleared when the program reads the RDRF bit in the SSR, then writes a 0 in the RDRF bit, or when the data transfer controller (DTC) reads the RDR. The RDR and RSR function as a double buffer. Data can be received continuously by reading each byte of data from the RDR and clearing the RDRF bit to 0 before the last bit of the next byte is received. In general, an external clock source should be used for receiving data. If an internal clock source is selected, the SCI starts receiving data as soon as the RE bit is set to 1. The serial clock is also output at the SCK pin. The SCI continues receiving until the RE bit is cleared to 0. If the last bit of the next data byte is received while the RDRF bit is still set to 1, an overrun error occurs and the ORER bit is set to 1. If the RIE bit is set to 1, a receive-error interrupt (ERI) is requested. The data received in the RSR are not transferred to the RDR when an overrun error occurs. After an overrun error, reception of the next data is enabled when the ORER bit is cleared to 0. • Simultaneous Transmit and Receive: The procedure for transmitting and receiving simultaneously is as follows: (1) Set up the desired communication conditions in the SMR, BRR, and SCR. (2) Set the TE and RE bits in the SCR to 1. The TXD and RXD pins are automatically switched to output and input, respectively, and the SCI is ready to transmit and receive data. (3) Data transmitting and receiving start when the TDRE bit in the SSR is cleared to 0. (4) Data are sent and received in synchronization with eight clock pulses. 278 (5) First, the transmit data are transferred from the TDR to the TSR. This makes the TDR empty, so the TDRE bit is set to 1. If the TIE bit is set to 1, a transmit-end interrupt (TXI) is requested. If continuous data transmission is desired, the CPU must read the TDRE bit in the SSR, write the next transmit data in the TDR, then clear the TDRE bit to 0. Alternatively, the DTC can write the next transmit data in the TDR, in which case the TDRE bit is cleared automatically. If the TDRE bit is not cleared to 0 by the time the SCI finishes sending the current byte from the TSR, the TXD pin continues to output the last bit in the TSR. (6) In the receiving section, when 8 bits of data have been received they are transferred from the RSR to the RDR and the RDRF bit in the SSR is set to 1. If the RIE bit is set to 1, a receive-end interrupt (RXI) is requested. (7) To clear the RDRF bit software read the RDRF bit in the SSR, read the data in the RDR, then write a 0 in the RDRF bit. Alternatively, the DTC can read the RDR, in which case the RDRF bit is cleared automatically. For continuous data reception, the RDRF bit must be cleared to 0 before the last bit of the next byte of data is received. If the last bit of the next byte is received while the RDRF bit is still set to 1, an overrun error occurs. The error is handled as described under “Data Reception” above. 14.4 CPU Interrupts and DTC Interrupts The SCI can request three types of interrupts: transmit-end (TXI), receive-end (RXI), and receive-error (ERI). Interrupt requests are enabled or disabled by the TIE and RIE bits in the SCR. Independent signals are sent to the interrupt controller for each type of interrupt. The transmit-end and receive-end interrupt request signals are obtained from the TDRE and RDRF flags. The receive-error interrupt request signal is the logical OR of the three error flags: overrun error (ORER), framing error (FER), and parity error (PER). Table 14-9 lists information about these interrupts. 279 Table 14-9 SCI Interrupts Interrupt ERI RXI TXI Description Receive-error interrupt, requested when ORER, FER, or PER is set. Receive-end interrupt, requested when RDRF is set. Transmit-end interrupt, requested when TDRE is set. DTC Service Available? No Priority High Yes Yes Low The TXI and RXI interrupts can be served by the data transfer controller (DTC) to have a data transfer performed. When the DTC serves one of these interrupts, it clears the TDRE or RDRF bit to 0 under the following conditions, which differ between the two bits. When invoked by a TXI request, if the DTC writes to the TDR, it automatically clears the TDRE bit to 0. When invoked by an RXI request, if the DTC reads from the RDR, it automatically clears the RDRF bit to 0. See section 6, “Data Transfer Controller” for further information on the DTC. 14.5 Application Notes Application programmers should note the following features of the SCI. 1. TDR Write: The TDRE bit in the SSR is simply a flag that indicates that the TDR contents have been transferred to the TSR. The TDR contents can be rewritten regardless of the TDRE value. If a new byte is written in the TDR while the TDRE bit is 0, before the old TDR contents have been moved into the TSR, the old byte will be lost. Normally, software should check that the TDRE bit is set to 1 before writing to the TDR. 2. Multiple Receive Errors: Table 14-10 lists the values of flag bits in the SSR when multiple receive errors occur, and indicates whether the RSR contents are transferred to the RDR. 280 Table 14-10 SSR Bit States and Data Transfer When Multiple Receive Errors Occur SSR Bits Receive Error RDRF ORER FER PER Overrun error 1*1 1 0 0 Framing error 0 0 1 0 Parity error 0 0 0 1 Overrun + framing errors 1*1 1 1 0 Overrun + parity errors 1*1 1 0 1 Framing + parity errors 0 0 1 1 *1 Overrun + framing + parity errors 1 1 1 1 Notes: *1 Set to 1 before the overrun error occurs. *2 Yes: The RSR contents are transferred to the RDR. No: The RSR contents are not transferred to the RDR. RSR to RDR*2 No Yes Yes No No Yes No 3. Line Break Detection: When the RXD pin receives a continuous stream of 0’s in the asynchronous mode (line-break state), a framing error occurs because the SCI detects a 0 stop bit. The value H'00 is transferred from the RSR to the RDR. Software can detect the linebreak state as a framing error accompanied by H'00 data in the RDR. The SCI continues to receive data, so if the FER bit is cleared to 0 another framing error will occur. 4. Sampling Timing and Receive Margin in Asynchronous Mode: The serial clock used by the SCI in asynchronous mode runs at 16 times the bit rate. The falling edge of the start bit is detected by sampling the RXD input on the falling edge of this clock. After the start bit is detected, each bit of receive data in the frame (including the start bit, parity bit, and stop bit or bits) is sampled on the rising edge of the serial clock pulse at the center of the bit. See figure 14-5. It follows that the receive margin can be calculated as in equation (1). When the absolute frequency deviation of the clock signal is 0 and the clock duty factor is 0.5, data can theoretically be received with distortion up to the margin given by equation (2). This is a theoretical limit, however. In practice, system designers should allow a margin of 20% to 30%. 281 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 2 3 4 5 Basic clock –7.5 pulses Receive data +7.5 pulses D0 Start bit D1 Sync sampling Data sampling Figure 14-5 Sampling Timing (Asynchronous Mode) M = {(0.5 – 1/2N) – (D – 0.5)/N – (L – 0.5)F} × 100 [%] M: N: D: L: F: (1) Receive margin Ratio of basic clock to bit rate (16) Duty factor of clock—ratio of High pulse width to Low width (0.5 to 1.0) Frame length (9 to 12) Absolute clock frequency deviation When D = 0.5 and F= 0 M = (0.5 –1/2 × 16) × 100 [%] = 46.875% (2) 5. Note on Transmitting in Synchronous Mode: When setting up serial communication interface 1 or 2 to transmit in synchronous mode, make sure the ORER bit is cleared to 0. Transmit operation will fail to start if the ORER bit is set to 1. The same is true in simultaneous transmitting and receiving. 282 Section 15 A/D Converter 15.1 Overview The H8/534 and H8/536 have an analog-to-digital converter module which can be programmed for input of analog signal on up to eight channels. A/D conversion is performed by the successive approximations method with 10-bit resolution. 15.1.1 Features The features of the on-chip A/D module are: • • • • • • • • Eight analog input channels Sample and hold circuit 10-Bit resolution Rapid conversion Conversion time is 13.8 µs per channel (at ø = 10 MHz) Single and scan modes — Single mode: A/D conversion is performed once. — Scan mode: A/D conversion is performed in a repeated cycle on one to four channels. Four 16-bit data registers These registers store A/D conversion results for up to four channels. A/D conversion can be started by external trigger input. A CPU interrupt (ADI) can be requested at the completion of each A/D conversion cycle. This interrupt can also be served by the on-chip data transfer controller (DTC), providing a convenient way to move results into memory. 283 15.1.2 Block Diagram Bus interface Figure 15-1 shows a block diagram of A/D converter. AVSS Internal data bus ADCR ADCSR ADDRD ADDRC ADDRB 10-Bit D/A ADDRA AVCC Successive approximations register Module data bus AN0 AN1 AN3 AN4 AN5 AN6 Analog multiplexer AN2 + ø/8 – Control circuit ø/16 ADTRG External trigger input Sample & hold circuit AN7 ADI Interrupt signal ADDRA: ADDRB: ADDRC: ADDRD: ADCSR: ADCR: A/D Data Register A A/D Data Register B A/D Data Register C A/D Data Register D A/D Control/Status Register A/D Control Register Figure 15-1 Block Diagram of A/D Converter Fig. 15-1 284 15.1.3 Input Pins Table 15-1 lists the input pins used by the A/D converter module. The eight analog input pins are divided into two groups, consisting of analog inputs 0 to 3 (AN0 to AN3) and analog inputs 4 to 7 (AN4 to AN7), respectively. Table 15-1 A/D Input Pins Name Analog supply voltage Analog ground Analog input 0 Analog input 1 Analog input 2 Analog input 3 Analog input 4 Analog input 5 Analog input 6 Analog input 7 A/D external trigger input Abbreviation AVCC I/O Input AVSS AN0 AN1 AN2 AN3 AN4 AN5 AN6 AN7 ADTRG Input Input Input Input Input Input Input Input Input Input Function Power supply and reference voltage for the analog circuits. Ground and reference voltage for the analog circuits. Analog input pins, group 0 Analog input pins, group 1 External trigger input 15.1.4 Register Configuration Table 15-2 lists the registers of the A/D converter module. Table 15-2 A/D Registers Name Abbreviation R/W Initial Value A/D data register A (High) ADDRA (H) R H'00 A/D data register A (Low) ADDRA (L) R H'00 A/D data register B (High) ADDRB (H) R H'00 A/D data register B (Low) ADDRB (L) R H'00 A/D data register C (High) ADDRC (H) R H'00 A/D data register C (Low) ADDRC (L) R H'00 A/D data register D (High) ADDRD (H) R H'00 A/D data register D (Low) ADDRD (L) R H'00 A/D control/status register ADCSR R/(W)* H'00 A/D control register ADCR R/W H'7F * Software can write 0 to clear the status flag bits but cannot write 1. 285 Address H'FEE0 H'FEE1 H'FEE2 H'FEE3 H'FEE4 H'FEE5 H'FEE6 H'FEE7 H'FEE8 H'FEE9 15.2 Register Descriptions 15.2.1 A/D Data Registers (ADDR)—H'FEE0 to H'FEE7 Bit 7 6 5 4 3 2 1 0 AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R ADDRn H (n = A to D) Bit 7 6 5 4 3 2 1 0 AD1 AD0 — — — — — — Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R ADDRn H (n = A to D) The four A/D data registers (ADDRA to ADDRD) are 16-bit read-only registers that store the results of A/D conversion. Each result consist of 10 bits. The first 8 bits are stored in the upper byte of the data register corresponding to the selected channel. The last two bits are stored in the lower data register byte. Each data register is assigned to two analog input channels as indicated in table 15-3. The A/D data registers are always readable by the CPU. The upper byte can be read directly. The lower byte is read via a temporary register. See section 15-3, “CPU Interface” for details. The unused bits (bits 5 to 0) of the lower data register byte are always read as 0. The A/D data registers are initialized to H'0000 at a reset and in the standby modes. Table 15-3 Assignment of Data Registers to Analog Input Channels Analog Input Channel Group 0 Group 1 AN0 AN4 AN1 AN5 AN2 AN6 AN3 AN7 A/D Data Register ADDRA ADDRB ADDRC ADDRD 286 15.2.2 A/D Control/Status Register (ADCSR)—H'FEE8 Bit 7 6 5 4 3 2 1 0 ADF ADIE ADST SCAN CKS CH2 CH1 CH0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/(W)* R/W R/W R/W R/W R/W R/W R/W * Software can write a 0 in bit 7 to clear the flag, but cannot write a 1 in this bit. The A/D control/status register (ADCSR) is an 8-bit readable/writable register that controls the operation of the A/D converter module. The ADCSR is initialized to H'00 at a reset and in the standby modes. Bit 7—A/D End Flag (ADF): This status flag indicates the end of one cycle of A/D conversion. Bit 7 ADF 0 1 Description This bit is cleared from 1 to 0 when: (Initial value) 1. The chip is reset or placed in a standby mode. 2. The CPU reads the ADF bit after it has been set to 1, then writes a 0 in this bit. 3. An A/D interrupt is served by the data transfer controller (DTC). This bit is set to 1 at the following times: 1. Single mode: when one A/D conversion is completed. 2. Scan mode: when inputs on all selected channels have been converted. Bit 6—A/D Interrupt Enable (ADIE): This bit selects whether to request an A/D interrupt (ADI) when A/D conversion is completed. Bit 6 ADIE 0 1 Description The A/D interrupt request (ADI) is disabled. The A/D interrupt request (ADI) is enabled. 287 (Initial value) Bit 5—A/D Start (ADST): The A/D converter operates while this bit is set to 1. In the single mode, this bit is automatically cleared to 0 at the end of each A/D conversion. Bit 5 ADST 0 1 Description A/D conversion is halted. (Initial value) 1. Single mode: One A/D conversion is performed. The ADST bit is automatically cleared to 0 at the end of the conversion. 2. Scan mode: A/D conversion starts and continues cyclically on the selected channels until the ADST bit is cleared to 0. Bit 4—Scan Mode (SCAN): This bit selects the scan mode or single mode of operation. See section 15.4, “Operation” for descriptions of these modes. The mode should be changed only when the ADST bit is cleared to 0. Bit 4 SCAN 0 1 Description Single mode Scan mode (Initial value) Bit 3—Clock Select (CKS): This bit controls the A/D conversion time. The conversion time should be changed only when the ADST bit is cleared to 0. Bit 3 CKS 0 1 Description Conversion time = 274 states (maximum) Conversion time = 138 states (maximum) (Initial value) Bits 2 to 0—Channel Select 2 to 0 (CH2 to CH0): These bits and the SCAN bit combine to select one or more analog input channels. The channel selection should be changed only when the ADST bit is cleared to 0. 288 Group Select CH2 0 1 CH1 0 0 1 1 0 0 1 1 Channel Select CH0 0 1 0 1 0 1 0 1 Selected Channels Single Mode Scan Mode AN0 AN0 AN1 AN0 and AN1 AN2 AN0 to AN2 AN3 AN0 to AN3 AN4 AN4 AN5 AN4 and AN5 AN6 AN4 to AN6 AN7 AN4 to AN7 15.2.3 A/D Control Register (ADCR)—H'FEE9 Bit 7 6 5 4 3 2 1 0 TRGE — — — — — — — Initial value 0 1 1 1 1 1 1 1 Read/Write R/W — — — — — — — The A/D control register (ADCR) is an 8-bit readable/writable register that enables or disables the A/D external trigger signal. The ADCR is initialized to H'7F at a reset and in the standby modes. Bit 7—Trigger Enable (TRGE): This bit enables or disables the ADTRG (A/D external trigger) signal. Bit 7 TRGE 0 1 Description External triggering of A/D conversion is disabled. A High-to-Low transition of ADTRG starts A/D conversion. (Initial value) Bit 6 to 0—Reserved: These bits cannot be modified and are always read as 1. 289 15.3 CPU Interface The A/D data registers (ADDRA to ADDRD) are 16-bit registers. The upper byte of each register can be read directly, but the lower byte is accessed through an 8-bit temporary register (TEMP). When the CPU or DTC reads the upper byte of an A/D data register, at the same time as the upper byte is placed on the internal data bus, the lower byte is transferred to TEMP. When the lower byte is accessed, the value in TEMP is placed on the internal data bus. A program that requires all 10 bits of an A/D result should perform word access, or should read first the upper byte, then the lower byte of the A/D data register. Either way, it is assured of obtaining consistent data. Consistent data are not assured if the program reads the lower byte first. A program that requires only 8-bit A/D accuracy should perform byte access to the upper byte of the A/D data register. The value in TEMP can be left unread. Figure 15-2 shows the data flow when the CPU (or DTC) reads an A/D data register. < Upper byte read > Module data bus CPU receives data H'AA Bus interface TEMP [H'40] ADDRn H [H'AA] ADDRn L [H'40] (n = A to D) < Lower byte read > Module data bus CPU receives data H'40 Bus interface TEMP [H'40] ADDRn H [H'AA] ADDRn L [H'40] (n = A to D) Figure 15-2 Read Access to A/D Data Register (When Register Contains H'AA40) 290 15.4 Operation The A/D converter performs 10 successive approximations to obtain a result ranging from H'0000 (corresponding to AVSS) to H'FFC0 (corresponding to AVCC). Only the first 10 bits of the result are significant. The A/D converter module can be programmed to operate in single mode or scan mode as explained below. 15.4.1 Single Mode (SCAN = 0) The single mode is suitable for obtaining a single data value from a single channel. A/D conversion starts when the ADST bit is set to 1. During the conversion process the ADST bit remains set to 1. When conversion is completed, the ADST bit is automatically cleared to 0. When the conversion is completed, the ADF bit is set to 1. If the interrupt enable bit (ADIE) is also set to 1, an A/D conversion end interrupt (ADI) is requested, so that the converted data can be processed by an interrupt-handling routine. Alternatively, the interrupt can be served by the data transfer controller (DTC). When an A/D interrupt is served by the DTC, the DTC automatically clears the ADF bit to 0. When an A/D interrupt is served by the CPU, however, the ADF bit remains set until the CPU reads the ADCSR, then writes a 0 in the ADF bit. Before selecting the single mode, clock, and analog input channel, software should clear the ADST bit to 0 to make sure the A/D converter is stopped. Changing the mode, clock, or channel selection while A/D conversion is in progress can lead to conversion errors. The following example explains the A/D conversion process in single mode when channel 1 (AN1) is selected. Figure 15-3 shows the corresponding timing chart. 1. Software clears the ADST bit to 0, then selects the single mode (SCAN = 0) and channel 1 (CH2 to CH0 = “001”), enables the A/D interrupt request (ADIE = 1), and sets the ADST bit to 1 to start A/D conversion. (Selection of mode, clock channel and setting the ADST bit can be done at same time.) Coding Example: (when using the slow clock, CKS = 0) BCLR #5, @H'FEE8 MOV.B #H'61, @H'FEE8 2. The A/D converter samples the AN1 input and converts the voltage level to a digital value. At the end of the conversion process the A/D converter transfers the result to register ADDRB, sets the ADF bit is set to 1, clears the ADST bit to 0, and halts. 291 3. ADF = 1 and ADIE = 1, so an A/D interrupt is requested. 4. The user-coded A/D interrupt-handling routine is started. 5. The interrupt-handling routine reads the ADCSR value, then writes a 0 in the ADF bit to clear this bit to 0. 6. The interrupt-handling routine reads and processes the A/D conversion result. 7. The routine ends. Steps 2 to 7 can now be repeated by setting the ADST bit to 1 again. If the data transfer enable (DTE) bit is set to 1, the interrupt is served by the data transfer controller (DTC). Steps 4 to 7 then change as follows. 4’. 5’. 6’. 7’. The DTC is started. The DTC automatically clears the ADF bit to 0. The DTC transfers the A/D conversion result from ADDRB to a specified destination address. The DTC ends. 292 Figure 15-3 A/D Operation in Single Mode (When Channel 1 is Selected) 293 Waiting Channel 3 (AN 3 ) * A/D conversion ➀ Set * Set * indicates execution of a software instruction ADDRD ADDRC ADDRB ADDRA Waiting Waiting Channel 1 (AN 1 ) Channel 2 (AN 2 ) Waiting A/D conversion starts Channel 0 (AN 0 ) ADF ADST ADIE Interrupt (ADI) Read result A/D conversion result ➀ Waiting Clear * A/D conversion ➁ Set * Read result A/D conversion result ➁ Waiting Clear * 15.4.2 Scan Mode (SCAN = 1) The scan mode can be used to monitor analog inputs on one or more channels. When the ADST bit is set to 1, A/D conversion starts from the first channel selected by the CH bits. When CH2 = 0 the first channel is AN0. When CH2 = 1 the first channel is AN4. If the scan group includes more than one channel (i.e. if bit CH1 or CH0 is set), conversion of the next channel begins as soon as conversion of the first channel ends. Conversion of the selected channels continues cyclically until the ADST bit is cleared to 0. The conversion results are placed in the data registers corresponding to the selected channels. Before selecting the scan mode, clock, and analog input channels, software should clear the ADST bit to 0 to make sure the A/D converter is stopped. Changing the mode, clock, or channel selection while A/D conversion is in progress can lead to conversion errors. The following example explains the A/D conversion process when three channels in group 0 are selected (AN0, AN1, and AN2). Figure 15-4 shows the corresponding timing chart. 1. Software clears the ADST bit to 0, then selects the scan mode (SCAN = 1), scan group 0 (CH2 = 0), and analog input channels AN0 to AN2 (CH1 and CH0 = 0) and sets the ADST bit to 1 to start A/D conversion. Coding Example: (with slow clock and ADI interrupt enabled) BCLR #5, @H'FEE8 MOV.B #H'72, @FEE8 2. The A/D converter samples the input at AN0, converts the voltage level to a digital value, and transfers the result to register ADDRA. 3. Next the A/D converter samples and converts AN1 and transfers the result to ADDRB. Then it samples and converts AN2 and transfers the result to ADDRC. 4. After all selected channels (AN0 to AN2) have been converted, the AD converter sets the ADF bit to 1. If the ADIE bit is set to 1, an A/D interrupt (ADI) is requested. Then the A/D converter begins converting AN0 again. 5. Steps 2 to 4 are repeated cyclically as long as the ADST bit remains set to 1. To stop the A/D converter, software must clear the ADST bit to 0. 294 Figure 15-4 A/D Operation in Scan Mode (When Channels 0 to 2 are Selected) Fig. 15-4 295 * Waiting Waiting indicates execution of a software instruction ADDRD ADDRC ADDRB ADDRA Channel 3 (AN 3 ) Channel 2 (AN 2 ) Channel 1 (AN 1 ) Transfer A/D conversion ➁ A/D conversion ➂ A/D conversion ➀ Waiting Waiting Waiting Waiting Waiting Clear * A/D conversion ➃ A/D conversion ➄ A/D conversion ➂ A/D conversion ➁ A/D conversion ➃ Waiting Channel 0 (AN 0 ) A/D conversion ➀ A/D conversion time Waiting Set* ADF ADST Continuous A/D conversion Clear * 15.4.3 Input Sampling Time and A/D Conversion Time The A/D converter includes a built-in sample-and-hold circuit. Sampling of the input starts at a time tD after the ADST bit is set to 1. The sampling process lasts for a time tSPL. The actual A/D conversion begins after sampling is completed. Figure 15-5 shows the timing of these steps, and table 15-4 lists the total conversion times (tCONV) for the single mode. The total conversion time includes tD and tSPL. The purpose of tD is to synchronize the ADCSR write time with the A/D conversion process, so the length of tD is variable. The total conversion time therefore varies within the minimum to maximum ranges indicated in table 15-4. In the scan mode, the ranges given in table 15-4 apply to the first conversion. The length of the second and subsequent conversion processes is fixed at 256 states (when CKS = 0) or 128 states (when CKS = 1). (1) ø Internal address bus (2) Write signal Input sampling timing ADF tD t SPL t CONV (1) (2) tD t SPL t CONV : : : : : ADCSR write cycle ADCSR address Synchronization delay Input sampling time Total A/D conversion time Figure 15-5 A/D Conversion Timing 296 Table 15-4 A/D Conversion Time (Single Mode) Item Synchronization delay Input sampling time Total A/D conversion time Symbol tD tSPL tCONV Min 18 — 259 CKS = 0 Typ — 63 — Max 33 — 274 Min 10 — 131 CKS = 1 Typ — 31 — Max 17 — 138 Note: Values in the table are numbers of states. 15.4.4 External Triggering of A/D Conversion A/D conversion can be started by an external trigger input. External trigger input is enabled at the ADTRG pin when the TRGE bit in the ADCR is set to 1. Between 1.5 and 2 ø clock cycles after the ADTRG input goes Low, the ADST bit in the ADCSR is set to 1 and A/D conversion commences. The timing of external triggering is shown in figure 15-6. ø ADTRG 1.0 to 2.0 cycles ADST A/D conversion Figure 15-6 Timing of Setting of ADST Bit 297 15.5 Interrupts and the Data Transfer Controller The ADI interrupt request is enabled or disabled by the ADIE bit in the ADCSR. When the ADI bit in data transfer enable register DTEF (bit 4 at address H'FF0D) is set to 1, the ADI interrupt is served by the data transfer controller. The DTC can be used to transfer A/D results to a buffer in memory, or to an I/O port. The DTC automatically clears the ADF bit to 0. Note: In scan mode, the DTC can transfer data for only one channel per interrupt, even if two or more channels are selected. 298 Section 16 RAM 16.1 Overview The H8/534 and H8/536 include 2 kbytes of on-chip static RAM, connected to the CPU by a 16-bit data bus. Both byte and word access to the on-chip RAM are performed in two states, enabling rapid data transfer and instruction execution. The on-chip RAM is assigned to addresses H'F680 to H'FE7F in the chip’s address space. A RAM control register (RAMCR) can enable or disable the on-chip RAM, permitting these addresses to be allocated to external memory instead, if so desired. 16.1.1 Block Diagram Figure 16-1 shows the block diagram of the on-chip RAM. Internal data bus (upper 8 bits) Internal data bus (lower 8 bits) Address H'F680 RAMCR H'F682 On-chip RAM H'FE7E Even addresses Odd addresses RAMCR: RAM Control Register Figure 16-1 Block Diagram of On-Chip RAM 299 16.1.2 Register Configuration The on-chip RAM is controlled by the register described in table 16-1. Table 16-1 RAM Control Register Name RAM control register Abbreviation RAMCR R/W R/W Initial Value H'FF Address H'FF11 16.2 RAM Control Register (RAMCR) Bit 7 6 5 4 3 2 1 0 RAME — — — — — — — Initial value 1 1 1 1 1 1 1 1 Read/Write R/W — — — — — — — The RAM control register (RAMCR) is an 8-bit register that enables or disable the on-chip RAM. Bit 7—RAM Enable (RAME): This bit enables or disables the on-chip RAM. The RAME bit is initialized on the rising edge of the reset signal. It is not initialized in the software standby mode. Bit 7 RAME 0 1 Description On-chip RAM is disabled. On-chip RAM is enabled. (Initial value) Bits 6 to 0—Reserved: These bits cannot be modified and are always read as 1. 16.3 Operation 16.3.1 Expanded Modes (Modes 1, 2, 3, and 4) If the RAME bit is set to 1, accesses to addresses H'F680 to H'FE7F are directed to the on-chip RAM. If the RAME bit is cleared to 0, accesses to addresses H'F680 to H'FE7F are directed to the external data bus. 300 16.3.2 Single-Chip Mode (Mode 7) If the RAME bit is set to 1, accesses to addresses H'F680 to H'FE7F are directed to the on-chip RAM. If the RAME bit is cleared to 0, access of any type (instruction fetch or data read or write) to addresses H'F680 to H'FE7F causes an address error and initiates the CPU’s exception-handling sequence. 301 Section 17 ROM 17.1 Overview The H8/534 includes 32 kbytes of high-speed, on-chip ROM. The H8/536 has 62 kbytes of onchip ROM. The on-chip ROM is connected to the CPU via a 16-bit data bus and is accessed in two states. Users wishing to program the chip themselves can request electrically programmable ROM (PROM). The PROM version has a PROM mode in which the chip can be programmed with a standard, external PROM writer. The chip is also available with masked ROM. The on-chip ROM is enabled or disabled depending on the MCU operating mode, which is determined by the inputs at the mode pins when the chip comes out of the reset state. See table 17-1. Table 17-1 ROM Usage in Each MCU Mode Mode Mode 1 (expanded minimum mode) Mode 2 (expanded minimum mode) Mode 3 (expanded maximum mode) Mode 4 (expanded maximum mode) Mode 7 (single-chip mode) Mode Pins MD2 MD1 MD0 0 0 1 0 1 0 0 1 1 1 0 0 1 1 1 17.1.1 Block Diagram Figure 17-1 shows the block diagram of the on-chip ROM. 303 ROM Disabled (external addresses) Enabled Disabled (external addresses) Enabled Enabled Internal data bus (upper 8 bits) Internal data bus (lower 8 bits) Addresses H8/534 H8/536 H'0000 H'0000 H'0002 H'0002 On-chip ROM H'7FFE H'F67E Even addresses Odd addresses Figure 17-1 Block Diagram of On-Chip ROM 17.2 PROM Mode 17.2.1 PROM Mode Setup The PROM version has a PROM mode in which the usual microcomputer functions of the H8/534 or H8/536 are halted to allow the on-chip PROM to be programmed. To select the PROM mode, apply the signal inputs listed in table 17-2. Table 17-2 Selection of PROM Mode Pin Mode pins (MD2, MD1, and MD0) STBY pin P61 and P60 Input Low Low High 304 17.2.2 Socket Adapter Pin Arrangements and Memory Map The H8/534 or H8/536 can be programmed with a general-purpose PROM writer by attaching a socket adapter as listed in table 17-3. The socket adapter depends on the type of package. Figure 17-2(a) and (b) show the socket adapter pin arrangements. Figure 17-3 is a memory map. Table 17-3 Socket Adapter Chip H8/534 Package 84-Pin PLCC (CP-84) 84-Pin windowed LCC (CG-84) 80-Pin QFP (FP-80A) 80-Pin TQFP (TFP-80C) H8/536 84-Pin PLCC (CP-84) 84-Pin windowed LCC (CG-84) 80-Pin QFP (FP-80A) 80-Pin TQFP (TFP-80C) Note: * Under development. Socket Adapter HS538ESC01H HS538ESG01H HS538ESH01H HS5348ESN01H* HS538ESC02H HS538ESG02H HS538ESH02H HS5368ESN01H* 305 H8/534 FP-80A 10 11 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 30 31 32 33 34 35 36 37 38 39 60 5 42 6 7 8 9 51 12 29 71 — — — CG-84, CP-84 Pin 21 RES 22 NMI 25 P30 26 P31 27 P32 28 P33 29 P34 30 P35 31 P36 32 P37 33 P40 34 P41 35 P42 36 P43 37 P44 38 P45 39 P46 40 P47 43 P50 44 P51 45 P52 46 P53 47 P54 48 P55 49 P56 50 P57 51 P60 52 P61 74 AVCC 16 VCC 55 VCC 17 MD0 18 MD1 19 MD2 20 STBY 65 AVss 2 Vss 24 Vss 41 Vss 42 Vss 64 Vss 83 Vss EPROM socket • • • • • • • • • • • • • • Pin VPP EA9 EO0 EO1 EO2 EO3 EO4 EO5 EO6 EO7 EA0 EA1 EA2 EA3 EA4 EA5 EA6 EA7 EA8 OE EA10 EA11 EA12 EA13 EA14 CE VCC HN27C256 (28 pins) 1 24 11 12 13 15 16 17 18 19 10 9 8 7 6 5 4 3 25 22 21 23 2 26 27 20 28 Vss 14 VPP: E7 to E0: EA14 to EA0: OE: CE: Programming power (12.5 V) Data input/output Address input Output enable Chip enable Note: All pins not shown in this figure should be left open. Figure 17-2(a) Socket Adapter Pin Arrangements (H8/534) 306 H8/536 FP-80A 10 11 76 77 78 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 30 31 32 33 34 35 36 37 38 39 60 5 42 6 7 8 9 51 12 29 71 — — — CG-84, CP-84 Pin 21 RES 22 NMI 7 P14 8 P15 9 P16 25 P30 26 P31 27 P32 28 P33 29 P34 30 P35 31 P36 32 P37 33 P40 34 P41 35 P42 36 P43 37 P44 38 P45 39 P46 40 P47 43 P50 44 P51 45 P52 46 P53 47 P54 48 P55 49 P56 50 P57 51 P60 52 P61 74 AVCC 16 VCC 55 VCC 17 MD0 18 MD1 19 MD2 20 STBY 65 AVSS 2 VSS 24 VSS 41 VSS 42 VSS 64 VSS 83 VSS EPROM socket Pin VPP EA9 EA15 EA16 PGM EO0 EO1 EO2 EO3 EO4 EO5 EO6 EO7 EA0 EA1 EA2 EA3 EA4 EA5 EA6 EA7 EA8 OE EA10 EA11 EA12 EA13 EA14 CE VCC • • • • • • • • • • • • • • VSS VPP: E7 to E0: EA16 to EA0: OE: CE: PGM: HN27C101 (32 pins) 1 26 3 2 31 13 14 15 17 18 19 20 21 12 11 10 9 8 7 6 5 27 24 23 25 4 28 29 22 32 16 Programming power (12.5 V) Data input/output Address input Output enable Chip enable Program Note: All pins not shown in this figure should be left open. Figure 17-2(b) Socket Adapter Pin Arrangements (H8/536) 307 Address in MCU mode Address in PROM mode H'0000 Address in MCU mode H'0000 Address in PROM mode H'0000 H8/534 On-chip ROM H'0000 H8/536 On-chip ROM H'EE80* H'7FFF H'7FFF H'F67F H'F67F * In mode 2, H'EE80 to H'F67F are external addresses. Do not attempt to program these addresses if the H8/536 will be used in mode 2. Figure 17-3 Memory Map in PROM Mode 17.3 H8/534 Programming The write, verify, and inhibited sub-modes of the PROM mode are selected as shown in table 17-4. Table 17-4 Selection of Sub-Modes in PROM Mode (H8/534) Pins Mode CE OE VPP VCC 07 to 00 Write Low High VPP VCC Data input Verify High Low VPP VCC Data output Programming inhibited High High VPP VCC High-impedance Note: The VPP and VCC pins must be held at the VPP and VCC voltage levels. A14 to A0 Address input Address input Address input The H8/534 PROM uses the same, standard read/write specifications as the HN27C256 and HN27256. 17.3.1 Writing and Verifying An efficient, high-speed programming procedure can be used to write and verify PROM data. This procedure writes data quickly without subjecting the chip to voltage stress and without sacrificing data reliability. It leaves the data H'FF written in unused addresses. 308 Figure 17-4 shows the basic high-speed programming flowchart. Tables 17-5 and 17-6 list the electrical characteristics of the chip in the PROM mode. Figure 17-5 shows a write/verify timing chart. START SET PROG./VERIFY MODE V CC = 6.0 V ±0.25 V, V PP = 12.5 V ±0.5 V Address = 0 n=0 n + 1→n Y N Program tpw = 1 ms ±5% n<S S = 25 N Verify Address + 1 → Address GO Program topw = 3n ms N Last address? Y SET READ MODE VCC = 5.0 V, V PP = V CC NOGO FAIL Read all addresses GO END Figure 17-4 High-Speed Programming Flowchart (H8/534) 309 Table 17-5 DC Characteristics (H8/534) (When VCC = 6.0 V ±0.25 V, VPP = 12.5 V ±0.3 V, VSS = 0 V, Ta = 25˚C ±5˚C) Item Input High voltage O7 to O0, A14 to A0, OE, CE Input Low voltage O7 to O0, A14 to A0, OE, CE Input High voltage O7 to O0 Input Low voltage Input leakage current VCC current VPP current Symbol Min VIH 2.4 VIL –0.3 VOH 2.4 O7 to O0 VOL — O7 to O0, A14 to A0, OE, CE |ILI| — ICC IPP — — Typ — — — Max VCC + 0.3 0.8 — — — 0.45 2 — — 40 40 Measurement Unit Conditions V V V IOH = –200 µA V IOL = 1.6 mA µA Vin = 5.25 V/0.5 V mA mA Table 17-6 AC Characteristics (H8/534) (When VCC = 6.0 V ±0.25 V, VPP = 12.5 V ±0.3 V, Ta = 25˚C ±5˚C) SymItem bol Min Typ Max Address setup time tAS 2 — — OE setup time tOES 2 — — Data setup time tDS 2 — — Address hold time tAH 0 — — Data hold time tDH 2 — — Data output disable time tDF — — 130 VPP setup time tVPS 2 — — Program pulse width tPW 0.95 1.0 1.05 OE pulse width for tOPW 2.85 — 78.75 overwrite-programming VCC setup time tVCS 2 — — Data output delay time tOE 0 — 500 * Input pulse level: 0.8 V to 2.2 V Input rise/fall time ≤ 20 ns Timing reference levels: input—1.0 V, 2.0 V; output—0.8 V, 2.0 V 310 Measurement Unit Conditions µs See figure µs 17-5* µs µs µs ns µs ms ms µs ns Write Verify Address t AS Data t AH Input data Output data t DH t DS t DF VPP VPP VCC t VPS VCC +1 VCC VCC t VCS CE t PW t OES t OE OE Figure 17-5 PROM Write/Verify Timing (H8/534) 17.3.2 Notes on Writing 1. Write with the specified voltages and timing. The programming voltage (VPP) in the PROM mode is 12.5 V. Caution: Applied voltages in excess of the specified values can permanently destroy to the chip. Be particularly careful about the PROM writer’s overshoot characteristics. If the PROM writer is set to Intel specifications or Hitachi HN27256 or HN27C256 specifications, Vpp will be 12.5 V. 2. Before writing data, check that the socket adapter and chip are correctly mounted in the PROM writer. Overcurrent damage to the chip can result if the index marks on the PROM writer, socket adapter, and chip are not correctly aligned. 311 3. Don’t touch the socket adapter or chip while writing. Touching either of these can cause contact faults and write errors. 17.4 H8/536 Programming The write, verify, and other sub-modes of PROM mode are selected as shown in table 17-7. Table 17-7 Selection of Sub-Modes in PROM Mode (H8/536) Pins CE OE PGM VPP VCC 07 to 00 Low High Low VPP VCC Data input Low Low High VPP VCC Data output Low Low Low VPP VCC High-impedance Low High High High Low Low High High High Note: The VPP and VCC pins must be held at the VPP and VCC voltage levels. Mode Write Verify Programming inhibited A16 to A0 Address input Address input Address input Standard EPROM read/write specifications are used, the same as for the HN27C101. The HN27C101 has two programming modes: page programming and byte programming. The H8/536 does not support page programming, so select byte programming. 17.4.1 Writing and Verifying An efficient, high-speed programming procedure can be used to write and verify PROM data. This procedure writes data quickly without subjecting the chip to voltage stress and without sacrificing data reliability. It leaves the data H'FF written in unused addresses. Figure 17-6 shows the basic high-speed programming flowchart. Tables 17-8 and 17-9 list the electrical characteristics of the chip during programming. Figure 17-7 shows a timing diagram. 312 START SET PROG./VERIFY MODE VCC = 6.0 V ±0.25 V, V PP = 12.5 V ±0.3 V Address = 0 n=0 n + 1→n Y N Program tpw = 0.2 ms ±5% n<S S = 25 N Verify Address + 1 → Address GO Program topw = 0.2n ms N Last address? Y SET READ MODE V CC = 5.0 V, V PP = V CC NOGO FAIL Read all addresses GO END Figure 17-6 High-Speed Programming Flowchart (H8/536) 313 Table 17-8 DC Characteristics (H8/536) (When VCC = 6.0 V ±0.25 V, VPP = 12.5 V ±0.3 V, VSS = 0 V, Ta = 25˚C ±5˚C) Item Input high voltage Input low voltage Output high voltage Output low voltage Input leakage current VCC current VPP current O7 to O0, A16 to A0, OE, CE, PGM O7 to O0, A16 to A0, OE, CE, PGM O7 to O0 O7 to O0 O7 to O0, A16 to A0, OE, CE, PGM SymTest bol Min Typ Max Unit Conditions VIH 2.4 — VCC + 0.3 V VIL –0.3 — 0.8 V VOH 2.4 VOL — |ILI| — — — — — 0.45 2 V V µA ICC IPP — — 40 40 mA mA — — IOH = –200 µA IOL = 1.6 mA Vin = 5.25 V/ 0.5 V Table 17-9 AC Characteristics (H8/536) (When VCC = 6.0 V ±0.25 V, VPP = 12.5 V ±0.3 V, Ta = 25˚C ±5˚C) SymItem bol Min Typ Max Address setup time tAS 2 — — OE setup time tOES 2 — — Data setup time tDS 2 — — Address hold time tAH 0 — — Data hold time tDH 2 — — Data output disable time tDF — — 130 VPP setup time tVPS 2 — — Program pulse width tPW 0.19 0.20 0.21 OE pulse width for tOPW 0.19 — 5.25 overwrite-programming VCC setup time tVCS 2 — — OE setup time tCES 2 — — Data output delay time tOE 0 — 150 * Input pulse level: 0.8 V to 2.2 V Input rise/fall time ≤ 20 ns Timing reference levels: input—1.0 V, 2.0 V; output—0.8 V, 2.0 V 314 Test Unit Conditions µs See figure µs 17-7* µs µs µs ns µs ms ms µs µs ns Write Verify Address t AS Data t AH Input data Output data t DH t DS t DF VPP VPP VCC t VPS VCC +1 VCC VCC t VCS CE t CES PGM t PW t OES t OE OE Figure 17-7 PROM Write/Verify Timing (H8/536) 17.4.2 Notes on Programming 1. Program with the specified voltages and timing. The programming voltage (VPP) in PROM mode is 12.5 V. Caution: Applied voltages in excess of the specified values can permanently destroy the chip. Be particularly careful about the PROM writer’s overshoot characteristics. If the PROM writer is set to Hitachi HN27C101 specifications, VPP will be 12.5 V. 2. Before programming, check that the socket adapter and chip are correctly mounted in the PROM writer. Overcurrent damage to the chip can result if the index marks on the PROM writer, socket adapter, and chip are not correctly aligned. 315 3. Don’t touch the socket adapter or chip while programming. Touching either of these can cause contact faults and write errors. 4. The H8/536 uses the HN27C101’s byte programming mode. Note that some PROM writers do not support the HN27C101’s byte programming mode. Table 17-10 lists the PROM writers recommended for use with the HD6475368R. Table 17-10 PROM Writers Recommended PROM Writers Vendor Model Data I/O 29B + Unipak 2B V21.0* 212 V2.0* 288A V4.1* SI000 V15.0* UNISITE 40 V3.0* 2900 V1.0* Aval Data PKW-3100 PKW-1100 Minato Electronics Model 1892 80-pin QFP type: GA91-15 84-pin PLCC type: GA91-16 Model 1891 80-pin QFP type: GA91-15 84-pin PLCC type: GA91-16 Note: * Use PROM writers with the indicated or higher version numbers. 5. The H8/536 PROM size is 62 kbytes. When programming, leave data H'FF in addresses H'F680 to H'1FFFF. 316 17.5 Reliability of Written Data An effective way to assure the data holding characteristics of the programmed chips is to bake them at 150˚C, then screen them for data errors. This procedure quickly eliminates chips with PROM memory cells prone to early failure. Figure 17-8 shows the recommended screening procedure. Write program Bake with power off 150°C 48 Hr Read and check program VCC = 5.0 V Install Figure 17-8 Recommended Screening Procedure If a series of write errors occur while the same PROM writer is in use, stop programming and check the PROM writer and socket adapter for defects, using a microcomputer with a windowed package and on-chip EPROM. Please inform Hitachi of any abnormal conditions noted during programming or in screening of program data after high-temperature baking. 317 17.6 Erasing of Data The windowed package enables data to be erased by illuminating the window with ultraviolet light. Table 17-11 lists the erasing conditions. Table 17-11 Erasing Conditions Item Ultraviolet wavelength Minimum illumination Value 253.7 nm 15 W·s/cm2 The conditions in table 17-11 can be satisfied by placing a 12000-µW/cm2 ultraviolet lamp 2 or 3 centimeters directly above the chip and leaving it on for about 20 minutes. 318 17.7 Handling of Windowed Packages 1. Glass Erasing Window: Rubbing the glass erasing window of a windowed package with a plastic material or touching it with an electrically charged object can create a static charge on the window surface which may cause the chip to malfunction. If the erasing window becomes charged, the charge can be neutralized by a short exposure to ultraviolet light. This returns the chip to its normal condition, but it also reduces the charge stored in the floating gates of the PROM, so it is recommended that the chip be reprogrammed afterward. Accumulation of static charge on the window surface can be prevented by the following precautions: (1) When handling the package, ground yourself. Don’t wear gloves. Avoid other possible sources of static charge. (2) Avoid friction between the glass window and plastic or other materials that tend to accumulate static charge. (3) Be careful when using cooling sprays, since they may have a slight ion content. (4) Cover the window with an ultraviolet-shield label, preferably a label including a conductive material. Besides protecting the PROM contents from ultraviolet light, the label protects the chip by distributing static charge uniformly. 2. Handling after Programming: Fluorescent light and sunlight contain small amounts of ultraviolet, so prolonged exposure to these types of light can cause programmed data to invert. In addition, exposure to any type of intense light can induce photoelectric effects that may lead to chip malfunction. It is recommended that after programming the chip, you cover the erasing window with a light-proof label (such as an ultraviolet-shield label). 3. 84-Pin LCC Package Mounting: When mounted on a printed circuit board, the 84-pin LCC package must be mounted in a socket. The recommended socket is listed in table 17-12. Table 17-12 Socket for 84-Pin LCC Package Manufacturer Sumitomo 3-M Product Code 284-1273-00-1102J 319 Section 18 Power-Down State 18.1 Overview The H8/534 and H8/536 have a power-down state that greatly reduces power consumption by stopping the CPU functions. The power-down state includes three modes: 1. Sleep mode— a software-triggered mode in which the CPU halts but the rest of the chip remains active 2. Software standby mode— a software-triggered mode in which the entire chip is inactive 3. Hardware standby mode— a hardware-triggered mode in which the entire chip is inactive The sleep mode and software standby mode are entered from the program execution state by executing the SLEEP instruction under the conditions given in table 18-1. The hardware standby mode is entered from any other state by a Low input at the STBY pin. Table 18-1 lists the conditions for entering and leaving the power-down modes. It also indicates the status of the CPU, on-chip supporting modules, etc., in each power-down mode. Table 18-1 Power-Down State Clock Run CPU Halt CPU Reg’s. Held Sup. Mod’s. Run Halt Halt Held HardHalt Halt Not ware held standby mode * The watchdog timer must also be stopped. Mode Sleep mode Software standby mode Entering Procedure Execute SLEEP instruction Set SSBY bit in SBYCR to 1, then execute SLEEP instruction* Set STBY pin to Low level Notes: SBYCR Software standby control register SSBY Software standby bit 321 RAM Held I/O Ports Held Halt and initialized Held Held Halt and initialized Held High impedance state Exiting Methods • Interrupt • RES Low • STBY Low • NMI • RES Low • STBY Low • STBY High, then RES Low → High 18.2 Sleep Mode 18.2.1 Transition to Sleep Mode Execution of the SLEEP instruction causes a transition from the program execution state to the sleep mode. After executing the SLEEP instruction, the CPU halts, but the contents of its internal registers remain unchanged. The functions of the on-chip supporting modules do not stop in the sleep mode. 18.2.2 Exit from Sleep Mode The chip wakes up from the sleep mode when it receives an internal or external interrupt request, or a Low input at the RES or STBY pin. 1. Wake-Up by Interrupt: An interrupt releases the sleep mode and starts either the CPU’s interrupt-handling sequence or the data transfer controller (DTC). If the interrupt is served by the DTC, after the data transfer is completed the CPU executes the instruction following the SLEEP instruction, unless the count in the data transfer count register (DTCR) is 0. If an interrupt on a level equal to or less than the mask level in the CPU’s status register (SR) is requested, the interrupt is left pending and the sleep mode continues. Also, if an interrupt from an on-chip supporting module is disabled by the corresponding enable/disable bit in the module’s control register, the interrupt cannot be requested, so it cannot wake the chip up. 2. Wake-Up by RES pin: When the RES pin goes Low, the chip exits from the sleep mode to the reset state. 3. Wake-Up by STBY pin: When the STBY pin goes Low, the chip exits from the sleep mode to the hardware standby mode. 18.3 Software Standby Mode 18.3.1 Transition to Software Standby Mode A program enters the software standby mode by setting the standby bit (SSBY) in the software standby control register (SBYCR) to 1, then executing the SLEEP instruction. Table 18-2 lists the attributes of the software standby control register. 322 Table 18-2 Software Standby Control Register Name Software standby control register Abbreviation SBYCR R/W R/W Initial Value H'7F Address H'FF13 In the software standby mode, the CPU, clock, and the on-chip supporting module functions all stop, reducing power consumption to an extremely low level. The on-chip supporting modules and their registers are reset to their initial state, but as long as a minimum necessary voltage supply is maintained (at least 2 V), the contents of the CPU registers and on-chip RAM remain unchanged. The I/O ports also remain in their current states. 18.3.2 Software Standby Control Register (SBYCR) Bit 7 6 5 4 3 2 1 0 SSBY — — — — — — — Initial value 0 1 1 1 1 1 1 1 Read/Write R/W — — — — — — — The software standby control register (SBYCR) is an 8-bit register that controls the action of the SLEEP instruction. Bit 7—Software Standby (SSBY): This bit enables or disables the transition to the software standby mode. Bit 7 SSBY 0 1 Description The SLEEP instruction causes a transition to the sleep mode. (Initial value) The SLEEP instruction causes a transition to the software standby mode. The watchdog timer must be stopped before the chip can enter the software standby mode. To stop the watchdog timer, clear the timer enable bit (TME) in the watchdog timer’s timer control/status register (TCSR) to 0. The SSBY bit cannot be set to 1 while the TME bit is set to 1. When the chip is recovered from the software standby mode by a nonmaskable interrupt (NMI), the SSBY bit is automatically cleared to 0. It is also cleared to 0 by a reset or transition to the hardware standby mode. Bits 6 to 0—Reserved: These bits cannot be modified and are always read as 1. 323 18.3.3 Exit from Software Standby Mode The chip can be brought out of the software standby mode by an input at one of three pins: the NMI pin, RES pin, or STBY pin. 1. Recovery by NMI Pin: When an NMI request signal is received, the clock oscillator begins operating but clock pulses are supplied only to the watchdog timer (WDT). The watchdog timer begins counting from H'00 at the rate determined by the clock select bits (CKS2 to CKS0) in its timer status/control register (TCSR). This rate should be set slow enough to allow the clock oscillator to stabilize before the count reaches H'FF. When the count overflows from H'FF to H'00, clock pulses are supplied to the whole chip, the software standby mode ends, and execution of the NMI interrupt-handling sequence begins. The clock select bits (CKS2 to CKS0) should be set as follows. (1) Crystal oscillator: Set CKS2 to CKS0 to a value that makes the watchdog timer interval equal to or greater than 10ms, which is the clock stabilization time. (2) External clock input: CKS2 to CKS0 can be set to any value. The minimum value (CKS2 = CKS1 = CKS0 = 0) is recommended. 2. Recovery by RES Pin: When the RES pin goes Low, the clock oscillator starts. Next, when the RES pin goes High, the CPU begins executing the reset sequence. When the chip recovers from the software standby mode by a reset, clock pulses are supplied to the entire chip at once. Be sure to hold the RES pin Low long enough for the clock to stabilize. 3. Recovery by STBY Pin: When STBY the pin goes Low, the chip exits from the software standby mode to the hardware standby mode. 18.3.4 Sample Application of Software Standby Mode In this example the chip enters the software standby mode on the falling edge of the NMI input and recovers from the software standby mode on the rising edge of NMI. Figure 18-1 shows a timing chart of the transitions. The nonmaskable interrupt edge bit (NMIEG) in the port 1 control register (P1CR) is originally cleared to 0, selecting the falling edge as the NMI trigger. After accepting an NMI interrupt in this condition, software changes the NMIEG bit to 1, sets the SSBY bit to 1, and executes the SLEEP instruction to enter the software standby mode. The chip recovers from the software standby mode on the next rising edge at the NMI pin. 324 Oscillator ø NMI NMEG SSBY Clock settling time NMI interrupt handling NMIEG = 1 SSBY = 1 SLEEP instruction Software standby mode (Power-down state) NMI interrupt handling WDT interval (tOSC2 ) Clock start-up time WDT overflow Figure 18-1 NMI Timing of Software Standby Mode (Application Example) 18.3.5 Application Notes The I/O ports remain in their current states in the software standby mode. If a port is in the High output state, the output current is not reduced in the software standby mode. 18.4 Hardware Standby Mode 18.4.1 Transition to Hardware Standby Mode Regardless of its current state, the chip enters the hardware standby mode whenever the STBY pin goes Low. The hardware standby mode reduces power consumption drastically by halting the CPU, stopping all the functions of the on-chip supporting modules, and placing I/O ports in the high-impedance state. The registers of the on-chip supporting modules are reset to their initial values. Only the on-chip RAM is held unchanged, provided the minimum necessary voltage supply is maintained (see note 1). 325 Notes: 1. The RAME bit in the RAM control register should be cleared to 0 before the STBY pin goes Low, to disable the on-chip RAM during the hardware standby mode. 2. Do not change the inputs at the mode pins (MD2, MD1, MD0) during hardware standby mode. Be particularly careful not to let all three mode inputs go low, since that would place the chip in PROM mode, causing increased current dissipation. 18.4.2 Recovery from Hardware Standby Mode Recovery from the hardware standby mode requires inputs at both the STBY and RES pins. When the STBY pin goes High, the clock oscillator begins running. The RES pin should be Low at this time and should be held Low long enough for the clock to stabilize. When the RES pin changes from Low to High, the reset sequence is executed and the chip returns to the program execution state. Note: During standby mode, power must still be supplied to AVCC, and the mode pins must be held at the selected mode. 18.4.3 Timing Sequence of Hardware Standby Mode Figure 18-2 shows the usual sequence for entering and leaving the hardware standby mode. First the RES pin goes Low, placing the chip in the reset state. Then the STBY pin goes Low, placing the chip in the hardware standby mode and stopping the clock. In the recovery sequence first the STBY pin goes High; then after the clock stabilizes, the RES pin is returned to the High level. Oscillator RES STBY Clock settling time Restart Figure 18-2 Hardware Standby Sequence 326 Section 19 E Clock Interface 19.1 Overview For interfacing to E clock based peripheral devices, the H8/534 and H8/536 can generate an E clock output. Special instructions (MOVTPE, MOVFPE) perform data transfers synchronized with the E clock. The E clock is created by dividing the system clock (ø) by 8. The E clock is output at the P11 pin when the P11DDR bit in the port 1 data direction register (P1DDR) is set to 1. When the CPU executes an instruction that synchronizes with the E clock, the address is output on the address bus as usual, but the data bus and the R/W, DS, RD, and WR signal lines do not become active until the falling edge of the E clock is detected. The length of the access cycle for an instruction synchronized with the E clock is accordingly variable. Figures 19-1 and 19-2 show the timing in the cases of maximum and minimum synchronization delay. The wait state controller (WSC) does not insert any wait states (Tw) during the execution of an instruction synchronized with the E clock. 327 Figure 19-1 Execution Cycle of Instruction Synchronized with E Clock in Expanded Modes (Maximum Synchronization Delay) 328 D7 to D0 (Write access) D7 to D0 (Read access) WR DS (Write access), RD DS (Read access), AS, R/W A19 to A0 E ø Last state T1 T2 TE TE TE TE TE TE TE TE TE TE TE TE TE TE T3 Last state T1 T2 TE TE TE TE TE TE TE T3 ø E A19 to A0 R/W AS, DS (Read access), RD DS (Write access), WR D7 to D0 (Read access) D7 to D0 (Write access) Figure 19-2 Execution Cycle of Instruction Synchronized with E Clock in Expanded Modes (Minimum Synchronization Delay) 329 –Preliminary– Section 20 Electrical Specifications 20.1 Absolute Maximum Ratings Table 20-1 lists the absolute maximum ratings. Table 20-1 Absolute Maximum Ratings Item Supply voltage Programming R-mask voltage S-mask Input voltage (except Port 8) (Port 8) Analog supply voltage Analog input voltage Operating temperature Symbol VCC VPP Storage temperature Tstg Vin Vin AVCC VAN Topr Rating –0.3 to +7.0 –0.3 to +13.5 –0.3 to +13.0 –0.3 to VCC + 0.3 –0.3 to AVCC + 0.3 –0.3 to +7.0 –0.3 to AVCC + 0.3 Regular specifications: –20 to +75 Wide-range specifications: –40 to +85 –55 to +125 Unit V V V V V V V ˚C ˚C ˚C Note: Permanent LSI damage may occur if maximum ratings are exceeded. Normal operation should be under recommended operating conditions. 20.2 Electrical Characteristics 20.2.1 DC Characteristics Table 20-2 lists the DC characteristics. 331 Table 20-2 DC Characteristics (5-V Versions) – Preliminary for S-Mask Versions– Conditions: VCC = 5.0 V ±10%, AVCC = 5.0 V ±10%*1, VSS = AVSS = 0 V, Ta = –20 to +75˚C (Regular Specifications) Ta = –40 to +85˚C (Wide-Range Specifications) Item Input High voltage Input Low voltage Schmitt trigger input voltage Input leakage current Leakage current in 3-state (off state) Input pull-up MOS current Output High voltage Output Low voltage RES, STBY, MD2, MD1, MD0 EXTAL Port 8 Other input pins (except port 7) RES, STBY, MD2, MD1, MD0 Other input pins (except port 7) Port 7 RES STBY, NMI, MD2, MD1, MD0 Port 8 Symbol VIH VIL VT– VT+ VT+ – VT– | Iin | Min VCC – 0.7 Typ – Test Max Unit Conditions VCC + 0.3 V VCC × 0.7 2.2 2.2 – – – VCC + 0.3 V AVCC + 0.3 V VCC + 0.3 V –0.3 – 0.5 V –0.3 – 0.8 V 1.0 2.0 0.4 – – – – – – – 2.5 3.5 – 10.0 1.0 V V V µA µA – – 1.0 µA Vin = 0.5 to VCC – 0.5 V Vin = 0.5 to AVCC – 0.5 V Vin = 0.5 to VCC – 0.5 V Port 9, ports 7 to 1 | ITSI | – – 1.0 µA Ports 6 R-mask and 5 S-mask All output pins –IP 50 50 VCC – 0.5 3.5 – – – – – – 200 300 – – 0.4 µA µA V V V Vin = 0 V – – – – – – – – 1.0 1.2 1.0 0.4 V V V V IOL = 8 mA IOL = 10 mA IOL = 10 mA IOL = 2.6 mA All output pins (except RES) Port 4 R-mask S-mask RES VOH VOL IOH = –200 µA IOH = –1 mA IOL = 1.6 mA Note: *1 AVcc must be connected to a power supply line, even when the A/D converter is not used and even in standby mode. 332 Table 20-2 DC Characteristics (5-V Versions) (cont) Item Input capacitance Current dissipation*2 RES H8/534 H8/536 NMI R-mask S-mask All input pins except RES, NMI Normal R-mask operation – Preliminary for S-Mask Versions– Symbol Cin ICC Min – – – – – Typ – – – – – Max 60 100 30 50 15 Unit pF pF pF pF pF Test Conditions Vin = 0 V f = 1 MHz Ta = 25°C – 25 40 mA f = 6 MHz – 30 50 mA f = 8 MHz – 35 60 mA f = 10 MHz S-mask – 40 60 mA f = 16 MHz Sleep R-mask – 12 25 mA f = 6 MHz mode – 16 30 mA f = 8 MHz – 20 35 mA f = 10 MHz S-mask – 23 35 mA f = 16 MHz Standby – 0.01 5.0 µA Ta ≤ 50°C – – 20.0 µA Ta > 50°C Analog supply During A/D R-mask AICC – 1.2 2.0 mA current conversion S-mask – 1.5 3.0 mA While waiting – 0.01 5.0 µA RAM standby voltage VRAM 2.0 – – V Note: *2 Current dissipation values assume that VIH min = VCC – 0.5 V, VIL max = 0.5 V, all output pins are in the no-load state, and all MOS input pull-ups are off. 333 Table 20-3 DC Characteristics (3-V S-Mask Versions) –Preliminary– Conditions: VCC = 3.0 to 5.5 V, VSS = AVSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), AVCC = 3.0 to 5.5 V*1 Test Item Input High voltage Input Low voltage Symbol Min VIH VCC × 0.85 – VCC + 0.3 V EXTAL VCC × 0.7 – VCC + 0.3 V Port 8 2.2 – AVCC + 0.3 V Other input pins (except port 7) 2.2 – VCC + 0.3 V –0.3 – 0.4 V –0.3 – 0.8 V VCC ≥ 4.0 V VCC < 4.0 V RES, STBY, MD2 to MD0 RES, STBY, MD2 to MD0, EXTAL VIL Other input pins (except port 7) Schmitt Port 7 trigger input voltages Input leakage current Typ Max Unit Conditions –0.3 – VCC × 0.2 V VT– VCC × 0.2 – VCC × 0.5 V VT+ VCC × 0.4 – VCC × 0.7 V VT+ – VT– VCC × 0.07 – – V |Iin| Vin = 0.5 to VCC – 0.5 V – – 10.0 µA STBY, NMI, MD2, MD1, MD0 – – 1.0 µA Port 8 – – 1.0 µA Vin = 0.5 to AVCC – 0.5 V |ITSI| – – 1.0 µA Vin = 0.5 to VCC – 0.5 V Input pull-up Ports 6 and 5 MOS current –IP 15 – 300 µA Vin = 0 V Output High All output pins voltage VOH VCC – 0.4 – – V IOH = –200 µA VCC – 1.0 – – V IOH = –1 mA Leakage current in 3-state (off-state) RES Port 9, ports 7 to 1 Note: *1 AVCC must be connected to a power supply line, even when the A/D converter is not used, and even in standby mode. 334 Table 20-3 DC Characteristics (3-V S-Mask Versions) (cont) Item Output Low voltage All output pins (except RES) Symbol Min Typ Max Test Unit Conditions VOL – – 0.4 V IOL = 1.6 mA – – 1.0 V IOL = 5 mA Port 4 – – 0.4 V IOL = 1.6 mA – – 60 pF NMI – – 50 pF Vin = 0 V f = 1 MHz Ta = 25°C All input pins except RES and NMI – – 15 pF – 27 40 mA f = 10 MHz, VCC = 5 V – 17 25 mA f = 10 MHz, VCC = 3 V – 15 25 mA f = 10 MHz, VCC = 5 V – 10 15 mA f = 10 MHz, VCC = 3 V – 0.01 5.0 µA Ta ≤ 50°C – – 20.0 µA 50°C < Ta – 1.5 3.0 mA AVCC = 5 V – 0.5 1.0 mA AVCC = 3 V – 0.01 5.0 µA 2.0 – V RES Input capacitance Current dissipation*2 RES H8/534 Cin H8/536 Normal operation 100 ICC Sleep mode Standby Analog supply current –Preliminary– During A/D conversion AICC While waiting RAM standby voltage VRAM – Note: *2 Current dissipation values assume that VIH min = VCC – 0.5 V and VIL max = 0.5 V, all output pins are in the no-load state, and all MOS input pull-ups are off. 335 Table 20-4 DC Characteristics (2.7-V S-Mask Versions) Conditions: VCC = 2.7 to 5.5 V, VSS = AVSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), AVCC = 2.7 to 5.5 V*1 Item Input High voltage Input Low voltage Min VIH VCC × 0.85 – VCC + 0.3 V EXTAL VCC × 0.7 – VCC + 0.3 V Port 8 2.2 – AVCC + 0.3 V Other input pins (except port 7) 2.2 – VCC + 0.3 V –0.3 – 0.4 V –0.3 – 0.8 V VCC ≥ 4.0 V VCC < 4.0 V RES, STBY, MD2 to MD0 RES, STBY, MD2 to MD0, EXTAL VIL Input leakage current Port 7 Typ Max Test Unit Conditions Symbol Other input pins (except port 7) Schmitt trigger input voltages –Preliminary– –0.3 – VCC × 0.2 V VT– VCC × 0.2 – VCC × 0.5 V VT+ VCC × 0.4 – VCC × 0.7 V VT+ – VT– VCC × 0.07 – – V |Iin| Vin = 0.5 to VCC – 0.5 V – – 10.0 µA STBY, NMI, MD2, MD1, MD0 – – 1.0 µA Port 8 – – 1.0 µA Vin = 0.5 to AVCC – 0.5 V RES Leakage current in 3-state (off-state) Port 9, ports 7 to 1 |ITSI| – – 1.0 µA Vin = 0.5 to VCC – 0.5 V Input pull-up MOS current Ports 6 and 5 –IP 15 – 300 µA Vin = 0 V Output High voltage All output pins VOH VCC – 0.4 – – V IOH = –200 µA VCC – 1.0 – – V IOH = –1 mA Note: *1 AVCC must be connected to a power supply line, even when the A/D converter is not used, and even in standby mode. 336 Table 20-4 DC Characteristics (2.7-V S-Mask Versions) (cont) Item Output Low voltage All output pins (except RES) Symbol Min Typ Max Test Unit Conditions VOL – – 0.4 V IOL = 1.6 mA – – 1.0 V IOL = 5 mA Port 4 – – 0.4 V IOL = 1.6 mA – – 60 pF Vin = 0 V NMI – – 50 pF All input pins except RES and NMI – – 15 pF – 23 35 mA f = 8 MHz, VCC = 5 V – 14 22 mA f = 8 MHz, VCC = 3 V – 12 22 mA f = 8 MHz, VCC = 5 V – 8 14 mA f = 8 MHz, VCC = 3 V – 0.01 5.0 µA Ta ≤ 50°C – – 20.0 µA 50°C < Ta – 1.5 3.0 mA AVCC = 5 V – 0.5 1.0 mA AVCC = 3 V – 0.01 5.0 µA 2.0 – – V RES Input capacitance Current dissipation*2 RES H8/534 Cin H8/536 Normal operation 100 ICC Sleep mode Standby Analog supply current –Preliminary– During A/D conversion AICC While waiting RAM standby voltage VRAM f = 1 MHz Ta = 25°C Note: *2 Current dissipation values assume that VIH min = VCC – 0.5 V and VIL max = 0.5 V, all output pins are in the no-load state, and all MOS input pull-ups are off. 337 Table 20-5 Allowable Output Current Values (5-V Versions) – Preliminary for S-Mask Versions– Conditions: VCC = 5.0 V ±10%, AVCC = 5.0 V ±10%, VSS = AVSS = 0 V, Ta = –20 to +75˚C (Regular Specifications) Ta = –40 to +85˚C (Wide-Range Specifications) Item Allowable output Low current (per pin) Port 4 Symbol Min Typ Max Unit IOL – – 10 mA – – 3.0 mA RES Other output pins – – 2.0 mA Σ IOL – – 40 mA – – 80 mA All output pins –IOH – – 2.0 mA Total of all output pins Σ –IOH – – 25 mA Allowable output Low current (total) Port 4, total of 8 pins Allowable output High current (per pin) Allowable output High current (total) Total of all output pins Table 20-6 Allowable Output Current Values (3-V S-Mask Versions) –Preliminary– Conditions: VCC = 3.0 to 5.5 V, VSS = AVSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), AVCC = 3.0 to 5.5 V*1 Item Allowable output Low current (per pin) Symbol Min Typ Max Unit IOL – – 10 mA RES – – 3.0 mA Other output pins – – 2.0 mA – – 40 mA – – 80 mA Port 4 Σ IOL Allowable output Low current (total) Port 4, total of 8 pins Allowable output High current (per pin) All output pins –IOH – – 2.0 mA Allowable output High current (total) Total of all output pins Σ –IOH – – 25 mA Total of all output pins Note: *1 To avoid degrading the reliability of the chip, be careful not to exceed the output current sink values in table 20-5. In particular, when driving a Darlington transistor pair or LED directly, be sure to insert a current-limiting resistor in the output path. See figures 20-1 and 20-2. 338 Table 20-7 Allowable Output Current Values (2.7-V S-Mask Versions) –Preliminary– Conditions: VCC = 2.7 to 5.5 V, VSS = AVSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), AVCC = 2.7 to 5.5 V*1 Item Allowable output Low current (per pin) Symbol Min Typ Max Unit IOL – – 10 mA RES – – 3.0 mA Other output pins – – 2.0 mA – – 40 mA – – 80 mA Port 4 Σ IOL Allowable output Low current (total) Port 4, total of 8 pins Allowable output High current (per pin) All output pins –IOH – – 2.0 mA Allowable output High current (total) Total of all output pins Σ –IOH – – 25 mA Total of all output pins Note: *1 To avoid degrading the reliability of the chip, be careful not to exceed the output current sink values in table 20-5. In particular, when driving a Darlington transistor pair or LED directly, be sure to insert a current-limiting resistor in the output path. See figures 20-1 and 20-2. The S-mask versions (high-speed and low-voltage versions) are identical to the existing R-mask versions functionally and in their pin arrangement. Due to the higher-speed design, however, there are differences in the fabrication process, which lead to some differences in electrical specifications, operating margin, noise margin, and other characteristics. These differences should be noted during board design, and when switching from an R-mask to an S-mask version. –Preliminary– H8/534 H8/536 H8/534 H8/536 VCC 2 kΩ 600Ω Port Darlington pair Port 4 LED Figure 20-1 Example of Circuit for Driving a Darlington Transistor Pair Figure 20-2 Example of Circuit for Driving an LED 339 20.2.2 AC Characteristics The AC characteristics of the H8/534 and H8/536 are listed in three tables. Bus timing parameters are given in table 20-8, control signal timing parameters in table 20-9, and timing parameters of the on-chip supporting modules in table 20-10. Table 20-8 (1) Bus Timing (R-Mask Versions) Condition A (R-mask): VCC = 5.0 V ±10%, ø = 0.5 to 10 MHz, VSS = 0 V Ta = –20 to +75˚C (Regular Specifications) Ta = –40 to +85˚C (Wide-Range Specifications) Condition A 6 MHz Max 8 MHz Min Max 10 MHz Test Min Max Unit Conditions Item Symbol Min Clock cycle time tcyc 166.7 2000 125 2000 100 2000 ns Clock pulse width Low tCL 65 – 35 Clock pulse width High tCH Clock rise time tCr Clock fall time – 45 – ns 65 – 45 – – 15 – 15 35 – ns – 15 ns tCf – 15 – 15 – 15 ns Address delay time tAD – 70 – 60 – 55 ns Address hold time tAH 30 – Data strobe delay time 1 tDSD1 – 70 25 – 20 – ns – 60 – 40 ns Data strobe delay time 2 tDSD2 – 70 – 60 – 50 ns Data strobe delay time 3 tDSD3 – 70 – 60 – 50 ns Write data strobe pulse width tDSWW 200 – 150 – 120 – ns Address setup time 1 tAS1 25 – 20 – 15 – ns Address setup time 2 tAS2 105 – 80 – 65 – ns Read data setup time tRDS 60 – 50 – 40 – ns Read data hold time tRDH 0 – 0 – 0 – ns Read data access time tACC – 280 – 190 – 160 ns Write data delay time tWDD – 70 – 65 – 65 ns Write data setup time tWDS 30 – 15 – 10 – ns Write data hold time tWDH 30 – 25 – 20 – ns 340 See figure 20-4 Table 20-8 (1) Bus Timing (R-Mask Versions) (cont) Condition A 8 MHz 10 MHz 16 MHz Max Min Max Min Max Test Unit Conditions 40 – 40 – 40 – ns 10 – 10 – 10 – ns Item Symbol Min Wait setup time tWTS Wait hold time tWTH Bus request setup time tBRQS 40 – 40 – 40 – ns Bus acknowledge delay time 1 tBACD1 – 70 – 60 – 55 ns Bus acknowledge delay time 2 tBACD2 – 70 – 60 – 55 ns Bus floating delay time tBZD – tBACD1 – tBACD1 – tBACD1 ns E clock delay time tED – 20 – 15 – 15 ns E clock rise time tEr – 15 – 15 – 15 ns E clock fall time tEf – 15 – 15 – 15 ns Read data hold time (E clock sync) tRDHE 0 – 0 – 0 – ns Write data hold time (E clock sync) tWDHE 50 – 40 – 30 – ns 341 See figure 20-5 See figure 20-10 See figure 20-11 See figure 20-6 Table 20-8 (2) Bus Timing (S-Mask Versions) –Preliminary– Condition B (5-V S-mask): VCC = 5.0 V ±10%, ø = 2.0 to 16 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), Ta = –40 to +85˚C (Wide-Range Specifications) Condition C (3-V S-mask): VCC = 3.0 to 5.5 V, ø = 2.0 to 10 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications) Condition D (2.7-V S-mask): VCC = 2.7 to 5.5 V, ø = 2.0 to 8 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications) Condition D Condition C Condition B 8 MHz 10 MHz 16 MHz Symbol Min Max Min Max Min Clock cycle time tcyc 125 500 100 500 62.5 500 ns Clock pulse width Low tCL 35 – 30 – 20 – ns Clock pulse width High tCH 35 – 30 – 20 – ns Clock rise time tCr – 20 – 20 – 10 ns Clock fall time tCf – 20 – 20 – 10 ns Address delay time tAD – 60 – 55 – 30 ns Address hold time tAH 20 – 10 – 5 – ns Data strobe delay time 1 tDSD1 – 60 – 40 – 30 ns Data strobe delay time 2 tDSD2 – 60 – 50 – 30 ns Data strobe delay time 3 tDSD3 – 60 – 50 – 30 ns Write data strobe pulse width tDSWW 150 – 120 – 70 – ns Address setup time 1 tAS1 20 – 15 – 10 – ns Address setup time 2 tAS2 80 – 65 – 30 – ns Read data setup time tRDS 50 – 40 – 20 – ns Read data hold time tRDH 0 – 0 – 0 – ns Read data access time tACC – 190 – 160 – 100 ns Write data delay time tWDD – 75 – 70 – 50 ns Write data setup time tWDS 15 – 10 – 10 – ns Write data hold time tWDH 25 – 20 – 10 – ns Wait setup time tWTS 40 – 40 – 30 – ns Wait hold time tWTH 10 – 10 – 10 – ns Bus request setup time tBRQS 40 – 40 – 30 – ns Bus acknowledge delay time 1 tBACD1 – 60 – 55 – 30 ns 342 Max Test Unit Conditions Item See figure 20-4 See figure 20-5 See figure 20-10 Table 20-8 (2) Bus Timing (S-Mask Versions) (cont) –Preliminary– Conditions D Conditions C Conditions B 8 MHz 10 MHz 16 MHz Item Symbol Min Max Min Max Min Max Test Unit Condition Bus acknowledge delay time 2 tBACD2 – 60 – 55 – 30 ns Bus floating delay time tBZD – tBACD1 – tBACD1 – tBACD1 ns E clock delay time tED – 20 – 20 – 10 ns E clock rise time tEr – 20 – 20 – 10 ns E clock fall time tEf – 20 – 20 – 10 ns Read data hold time (E clock sync) tRDHE 0 – 0 – 0 – ns Write data hold time (E clock sync) tWDHE 40 – 30 – 10 – ns 343 See figure 20-10 See figure 20-11 See figure 20-6 Table 20-9 (1) Control Signal Timing (R-Mask Versions) Condition A (R-mask): VCC = 5.0 V ±10%, ø = 0.5 to 10 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), Ta = –40 to +85˚C (Wide-Range Specifications) Condition A 6 MHz Item Symbol Min 8 MHz Max Min Max 10 MHz Min Max Test Unit Condition See figure 20-7 RES setup time tRESS 200 – 200 – 200 – ns RES pulse width 1* tRESW1 6.0 – 6.0 – 6.0 – tcyc RES pulse width 2* tRESW2 520 – 520 – 520 – tcyc RES output delay time tRESD – 100 – 100 – 100 ns RES output pulse width tRESOW 132 – 132 – 132 – tcyc NMI setup time tNMIS 150 – 150 – 150 – ns NMI hold time tNMIH 10 – 10 – 10 – ns IRQ0 setup time tIRQ0S 50 – 50 – 50 – ns IRQ1 setup time tIRQ1S 50 – 50 – 50 – ns IRQ1 hold time tIRQ1H 10 – 10 – 10 – ns A/D trigger setup time tTRGS 50 – 50 – 50 – ns A/D trigger hold time tTRGH 10 – 10 – 10 – ns NMI pulse width (for recovery from software standby mode) tNMIW 200 – 200 – 200 – ns Crystal oscillator settling time (reset) tOSC1 20 – 20 – 20 – ms See figure 20-12 Crystal oscillator settling time (software standby) tOSC2 10 – 10 – 10 – ms See figure 18-1 See figure 20-8 See figure 20-9 See figure 20-22 Note: * tRESW2 applies at power-on and when the RSTOE bit in the reset control/status register (RSTCSR) is set to 1. tRESW1 applies when RSTOE is cleared to 0. 344 Table 20-9 (2) Control Signal Timing (S-Mask Versions) –Preliminary– Condition B (5-V S-mask): VCC = 5.0 V ±10%, ø = 2.0 to 16 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), Ta = –40 to +85˚C (Wide-Range Specifications) Condition C (3-V S-mask): VCC = 3.0 to 5.5 V, ø = 2.0 to 10 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications) Condition D (2.7-V S-mask): VCC = 2.7 to 5.5 V, ø = 2.0 to 8 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications) Condition D Condition C 8 MHz Item Symbol Min Max Condition B 10 MHz Min Max 16 MHz Min Max Unit RES setup time tRESS 200 – 200 – 200 – ns RES pulse width 1* tRESW1 6.0 – 6.0 – 6.0 – tcyc RES pulse width 2* tRESW2 Test Conditions See figure 20-7 520 – 520 – 520 – tcyc RES output delay time tRESD – 100 – 100 – 100 ns RES output pulse width tRESOW 132 – 132 – 132 – tcyc NMI setup time tNMIS 200 – 200 – 150 – ns NMI hold time tNMIH 10 – 10 – 10 – ns IRQ0 setup time tIRQ0S 50 – 50 – 50 – ns IRQ1 setup time tIRQ1S 50 – 50 – 50 – ns IRQ1 hold time tIRQ1H 10 – 10 – 10 – ns A/D trigger setup time tTRGS 50 – 50 – 50 – ns A/D trigger hold time tTRGH 10 – 10 – 10 – ns NMI pulse width (for recovery from software standby mode) tNMIW 200 – 200 – 200 – ns Crystal oscillator settling time (reset) tOSC1 20 – 20 – 20 – ms See figure 20-12 Crystal oscillator settling time (software standby) tOSC2 10 – 10 – 10 – ms See figure 18-1 See figure 20-8 See figure 20-9 See figure 20-22 Note: * tRESW2 applies at power-on and when the RSTOE bit in the reset contol/status register (RSTCSR) is set to 1. tRESW1 applies when RSTOE is cleared to 0. 345 Table 20-10 Timing Conditions of On-Chip Supporting Modules – Preliminary for S-Mask Versions– Condition A (R-mask): VCC = 5.0 V ±10%, ø = 0.5 to 10 MHz, VSS = 0 V, Ta = –20 to +75˚C(Regular Specifications), Ta = –40 to +85˚C (Wide-Range Specifications) Condition B (5-V S-mask): VCC = 5.0 V ±10%, ø = 2.0 to 16 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), Ta = –40 to +85˚C (Wide-Range Specifications) Condition C (3-V S-mask): VCC = 3.0 to 5.5 V, ø = 2.0 to 10 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications) Condition D (2.7-V S-mask): VCC = 2.7 to 5.5 V, ø = 2.0 to 8 MHz, VSS = 0 V, Ta = –20 to +75˚C (Regular Specifications) Condition A Condition D 6 MHz TMR 10 MHz 16 MHz Max Min Max Min Max Min Max Test Unit Conditions Timer output delay time tFTOD – 100 – 100 – 100 – 100 ns Timer input setup time tFTIS 50 – 50 – 50 – 50 – ns Timer clock input setup time tFTCS 50 – 50 – 50 – 50 – ns Timer clock pulse width tFTCWL, 1.5 tFTCWH – 1.5 – 1.5 – 1.5 – tcyc Timer output delay time tTMOD – 100 – 100 – 100 – 100 ns See figure 20-16 50 – 50 – 50 – 50 – ns See figure 20-17 tTMCWL, 1.5 tTMCWH – 1.5 – 1.5 – 1.5 – tcyc Timer clock tTMCS input setup time Timer clock pulse width PWM 8 MHz Condition B Symbol Min Item FRT Condition C See figure 20-14 See figure 20-15 Timer reset tTMRS input setup time 50 – 50 – 50 – 50 – ns See figure 20-18 Timer output delay time – 100 – 100 – 100 – 100 ns See figure 20-19 tPWOD 346 Table 20-10 Timing Conditions of On-Chip Supporting Modules (cont) – Preliminary for S-Mask Versions– Condition A Condition D Condition C 8 MHz 10 MHz 6 MHz Item SCI Symbol Min Condition B 16 MHz Max Min Max Min Max Min Max Test Unit Conditions – 2 – 2 – 2 tcyc Input (Async) tScyc clock cycle (Sync) 2 4 – 4 – 4 – 4 – tcyc Input pulse width 0.4 0.6 0.4 0.6 0.4 0.6 0.4 0.6 tScyc Transmit (Sync) tTXD data delay – 100 – 100 – 100 – 100 ns Receive (Sync) tRXS data setup time 100 – 100 – 100 – 100 – ns Receive data hold time 100 – 100 – 100 – 100 – ns – 100 – 100 – 100 – 100 ns Input data setup time tPRS 50 – 50 – 50 – 50 – ns Input data hold time 50 – 50 – 50 – 50 – ns tSCKW (Sync) tRXH Port Output data delay time tPWD tPRH – • Measurement Conditions for AC Characteristics 5V RL H8/534 (H8/536) output pin C C = 90 pF: P1, P2, P3, P4, P5, P6 = 30 pF: P7, P9 R L = 2.4 k Ω R H = 12 k Ω Input/output timing reference levels Low: 0.8 V High: 2.0 V RH Figure 20-3 Output Load Circuit 347 See figure 20-20 See figure 20-21 See figure 20-13 tAH, tDSWW, tAS1, tAS2, and tACC depend on tcyc as shown below. (1) VCC = 5.0 V ±10% (S-mask) tAH = 0.5 × tcyc – 26 (ns) tDSWW = 1.5 × tcyc – 24 (ns) tAS1 = 0.5 × tcyc – 21 (ns) tAS2 = tcyc – 32 (ns) tACC = 2.5 × tcyc – 56 (ns) (2) VCC = 3.0 V (S-mask) tAH = 0.5 × tcyc – 40 (ns) tDSWW = 1.5 × tcyc – 30 (ns) tAS1 = 0.5 × tcyc – 35 (ns) tAS2 = tcyc – 35 (ns) tACC = 2.5 × tcyc – 90 (ns) (3) VCC = 2.7 V (S-mask) tAH = 0.5 × tcyc – 42 (ns) tDSWW = 1.5 × tcyc – 37 (ns) = 0.5 × tcyc – 42 (ns) tAS1 tAS2 = tcyc – 45 (ns) tACC = 2.5 × tcyc – 122 (ns) 348 –Preliminary– 20.2.3 A/D Converter Characteristics Tables 20-11 and 20-12 list the characteristics of the on-chip A/D converter. Tables 20-11 A/D Converter Characteristics (5-V Versions) – Preliminary for S-Mask Versions– Conditions: VCC = 5.0V ±10%, AVCC = 5.0V ±10%, VSS = AVSS = 0V, Ta = –20 to +75˚C (Regular Specifications) Ta = –40 to +85˚C (Wide-Range Specifications) R-Mask 6 MHz S-Mask 8 MHz 10 MHz 16 MHz Item Min Typ Max Min Typ Max Min Typ Max Min Typ Max Unit Resolution 10 10 10 10 10 10 10 10 10 Bits 10 10 10 Conversion time — — 23.0 — — 17.25 — — 13.8 — — 8.625 µs Analog input capacitance — — 20 — — 20 — — 20 — — 20 pF Allowable signalsource impedance — — 10 — — 10 — — 10 — — 5 kΩ Nonlinearity error — — ±2.0 — — ±2.0 — — ±2.0 — — ±2.0 LSB Offset error — — ±2.0 — — ±2.0 — — ±2.0 — — ±2.0 LSB Full-scale error — — ±2.0 — — ±2.0 — — ±2.0 — — ±2.0 LSB Quantizing error — — ±0.5 — — ±0.5 — — ±0.5 — — ±0.5 LSB Absolute accuracy — — ±2.5 — — ±2.5 — — ±2.5 — — ±2.5 LSB 349 Table 20-12 A/D Converter Characteristics –Preliminary– Condition C (3-V S-mask): VCC = 3.0 to 5.5 V, VSS = AVSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), AVCC = 3.0 to 5.5 V Condition D (2.7-V S-mask): VCC = 2.7 to 5.5 V, VSS = AVSS = 0 V, Ta = –20 to +75˚C (Regular Specifications), AVCC = 2.7 to 5.5 V Condition D*1 Condition C*2 8 MHz 10 MHz Item Min Typ Max Min Typ Max Unit Resolution 10 10 10 10 10 10 Bits Conversion time – – 17.25 – – 13.8 µs Analog input capacitance – – 20 – – 20 pF Allowable signal-source impedance – – 5 – – 5 kΩ Nonlinearity error – – ±3.5 – – ±3.5 LSB Offset error – – ±3.5 – – ±3.5 LSB Full-scale error – – ±3.5 – – ±3.5 LSB Quantizing error – – ±0.5 – – ±0.5 LSB Absolute accuracy – – ±4.0 – – ±4.0 LSB Notes: Maximum operating frequency of A/D converter: *1 AVCC = 2.7 to 3.0 V: 8 MHz (conversion time: 17.25 µs) *2 AVCC = 3.0 to 4.5 V: 10 MHz (conversion time: 13.8 µs) 20.3 MCU Operational Timing This section provides the following timing charts: 20.3.1 20.3.2 20.3.3 20.3.4 20.3.5 20.3.6 20.3.7 20.3.8 Bus timing Control Signal Timing Clock Timing I/O Port Timing 16-Bit Free-Running Timer Timing 8-Bit Timer Timing Pulse Width Modulation Timer Timing Serial Communication InterfaceTiming Figures 20-4 to 20-6 Figures 20-7 to 20-10 Figures 20-11 and 20-12 Figure 20-13 Figures 20-14 and 20-15 Figures 20-16 to 20-18 Figure 20-19 Figure 20-20 and 20-21 350 20.3.1 Bus Timing 1. Basic Bus Cycle (without Wait States) in Expanded Modes T1 t cyc T2 T3 t CL t CH ø t Cf t AD t Cr A19 to A0 R/W t DSD1 t AS1 t DSD3 t AH AS, DS (Read), RD t RDS t ACC D7 to D0 (Read) t RDH t DSD2 t DSD3 t AS2 t DSWW t AH DS (Write), WR t WDD t WDH t WDS D7 to D0 (Write) Figure 20-4 Basic Bus Cycle (without Wait States) in Expanded Modes 351 2. Basic Bus Cycle (with 1 Wait State) in Expanded Modes T1 T2 TW T3 ø A19 to A0 R/W DS (Read), RD D7 to D0 (Read) DS (Write), RD D7 to D0 (Write) t WTS t WTH t WTS t WTH WAIT Figure 20-5 Basic Bus Cycle (with 1 Wait State) in Expanded Modes 352 3. Bus Cycle Synchronized with E Clock ø t ED E A19 to A0 R/W t DSD3 t AH AS, DS (Read), t RDS RD t RDHE D7 to D0 (Read) t DSD3 t AH DS (Write), WR t WDHE D7 to D0 (Write) Figure 20-6 Bus Cycle Synchronized with E Clock 353 20.3.2 Control Signal Timing 1. Reset Input Timing ø t RESS t RESS RES t RESW1, t RESW2 Figure 20-7 Reset Input Timing 2. Reset Output Timing ø t RESD t RESD RES t RESOW Figure 20-8 Reset Output Timing 3. NMI Pulse Width ø t NMIS t NMIH t IRQ1S t IRQ1H NMI IRQ1 to IRQ 5 t IRQ0S IRQ0 Figure 20-9 Interrupt Input Timing 354 4. Bus Release State Timing ø t BRQS t BRQS BREQ (Input) t BACD1 t BACD2 BACK (Output) t BZD t AD A19 to A0 , R/W, DS, RD, WR, AS Figure 20-10 Bus Release State Timing 20.3.3 Clock Timing 1. E Clock Timing Fig. 20-10 ø tED tED E tEf tEr Figure 20-11 E Clock Timing Fig. 20-11 355 RES STBY VCC ø tOSC1 tOSC1 2. Clock Oscillator Stabilization Timing Figure 20-12 Clock Oscillator Stabilization Timing Fig. 20-12 356 20.3.4 I/O Port Timing Port read/write cycle T1 T2 T3 ø t PRS t PRH Port 1 to (Input) port 9 t PWD Port 1* to (Output) port 9 * Except P11, P10, and P8 7 to P8 0 Figure 20-13 I/O Port Input/Output Timing Fig. 20-13 357 20.3.5 16-Bit Free-Running Timer Timing 1. Free-Running Timer Input/Output Timing ø Free-running timer counter Compare-match t FTOD FTOA 1 , FTOB 1 , FTOA 2 , FTOB 2 , FTOA 3 , FTOB 3 t FTIS FTI 1, FTI 2, FTI 3 Figure 20-14 Free-Running Timer Input/Output Timing 2. External Clock Input Timing for Free-Running Timers Fig. 20-14 ø t FTCS FTCI 1 , FTCI 2 , FTCI 3 t FTCWL t FTCWH Figure 20-15 External Clock Input Timing for Free-Running Timers 358 20.3.6 8-Bit Timer Timing 1. 8-Bit Timer Output Timing ø Timer counter Compare-match t TMOD TMO Figure 20-16 8-Bit Timer Output Timing 2. 8-Bit Timer Clock Input Timing Fig. 20-16 ø t TMCS t TMCS TMCI t TMCWL t TMCWH Figure 20-17 8-Bit Timer Clock Input Timing Fig. 20-17 3. 8-Bit Timer Reset Input Timing ø t TMRS TMRI Timer counter n H'00 Figure 20-18 8-Bit Timer Reset Input Timing Fig. 20-18 359 20.3.7 Pulse Width Modulation Timer Timing ø Timer counter Compare-match t PWOD PW1 , PW2 , PW3 Figure 20-19 PWM Timer Output Timing 20.3.8 Serial Communication Interface Timing t SCKW t Scyc Figure 20-20 SCI Input Clock Timing t Scyc Serial clock t rXD Transmit data t RXS t RXH Receive data Figure 20-21 SCI Input/Output Timing (Synchronous Mode) 360 20.3.9 A/D Trigger Signal Input Timing ø t TRGS t TRGH ADTRG Figure 20-22 A/D Trigger Signal Input Timing 361 Appendix A Instructions A.1 Instruction Set Operation Notation Rd Rs Rn (EAd) (EAs) CCR N Z V C CR PC CP SP General register (destination operand) General register (source operand) General register Destination operand Source operand Condition code register N (Negative) flag in CCR Z (Zero) flag in CCR V (Overflow) flag in CCR C (Carry) flag in CCR Control register Program counter Code page register Stack pointer Condition Code Notation ↕ 0 1 — ∆ Changed after instruction execution Cleared to 0 Set to 1 Value before operation is retained Changed depending on condition 363 FP #IMM disp + – × ÷ ∧ ∨ ⊕ → ↔ ¬ Frame pointer Immediate data Displacement Add Subtract Multiply Divide Logical AND Logical OR Logical exclusive OR Move Swap Logical NOT Size Mnemonic Operation B/W Data MOV: G (EAs) → Rd B/W transfer Rs → (EAd) #IMM → (EAd) MOV: E #IMM → Rd (short format) B MOV: F @ (d: 8, FP) → Rd B/W Rs → @ (d: 8, FP)(short format) MOV: I #IMM → Rd (short format) W MOV: L (@aa: 8) → Rd (short format) B/W MOV: S Rs → (@aa: 8) (short format) B/W LDM @ SP + → Rn (register list) W STM Rn (register list) → @ – SP W XCH Rs ←→ Rd W SWAP Rd (upper byte) ←→ Rd (lower byte) B MOVTPE Rs → (EAd) Synchronized with E clock B MOVFPE (EAs) → Rd Synchronized with E clock B ArithADD: G Rd + (EAs) → Rd B/W metic ADD: Q (EAd) + #IMM → (EAd) B/W opera(#IMM = ±1, ±2) (short format) tions ADDS Rd + (EAs) → Rd B/W (Rd is always word size) ADDX Rd + (EAs) + C → Rd B/W B DADD (Rd)10 + (Rs)10 + C → (Rd)10 SUB Rd – (EAs) → Rd B/W SUBS Rd – (EAs) → Rd B/W SUBX Rd – (EAs) – C → Rd B/W DSUB (Rd)10 – (Rs)10 – C → (Rd)10 B MULXU Rd × (EAs) → Rd 8 × 8 B/W (Unsigned) 16 × 16 DIVXU Rd ÷ (EAs) → Rd 16 ÷ 8 B/W (Unsigned) 32 ÷ 16 CMP: G Rd – (EAs), Set CCR B/W (EAd) – #IMM, Set CCR CMP: E Rd – #IMM, Set CCR (short format) B CMP: I Rd – #IMM, Set CCR (short format) W 364 N ↕ CCR Bit Z V ↕ 0 C — ↕ ↕ ↕ ↕ 0 0 — — ↕ ↕ ↕ — — — ↕ — — ↕ ↕ ↕ ↕ ↕ — — — ↕ — — ↕ ↕ 0 0 0 — — — 0 — — ↕ ↕ — — — — — — — — — ↕ ↕ — — — — ↕ — ↕ — ↕ — ↕ ↕ ↕ ↕ — ↕ ↕ ↕ ↕ — ↕ — ↕ — 0 ↕ ↕ ↕ — ↕ ↕ 0 ↕ ↕ ↕ 0 ↕ ↕ ↕ ↕ ↕ ↕ ↕ ↕ ↕ ↕ ↕ ↕ Arithmetic operations Shift operations Mnemonic Operation EXTS (< Bit 7 > of < Rd >) → (< Bit 15 to 8 > of < Rd >) EXTU 0 → (<Bit 15 to 8 > of < Rd >) TST (EAd) – 0, Set CCR NEG 0 – (EAd) → (EAd) CLR 0 → (EAd) TAS (EAd) – 0, Set CCR (1)2 → (< Bit 7 > of < EAd >) MSB LSB SHAL C SHAR Size B/W B N ↕ CCR Bit Z V ↕ 0 B B/W B/W B/W B 0 ↕ ↕ 0 ↕ ↕ ↕ ↕ 1 ↕ 0 0 0 0 0 0 0 ↕ 0 0 B/W ↕ ↕ ↕ ↕ B/W ↕ ↕ 0 ↕ B/W ↕ ↕ 0 ↕ B/W 0 ↕ 0 ↕ B/W ↕ ↕ 0 ↕ B/W ↕ ↕ 0 ↕ B/W ↕ ↕ 0 ↕ B/W ↕ ↕ 0 ↕ B/W B/W B/W B/W B/W ↕ ↕ ↕ ↕ — ↕ ↕ ↕ ↕ ↕ 0 0 0 0 — — — — — — B/W — ↕ — — B/W B/W — — ↕ ↕ — — — — C 0 0 MSB LSB C SHLL SHLR ROTL MSB LSB C 0 MSB LSB 0 C ROTR C MSB LSB MSB LSB C ROTXL ROTXR MSB LSB MSB LSB C C Logic operations AND OR XOR NOT BSET Bit manipulations BCLR BTST BNOT Rd ∧ (EAs) → Rd Rd ∨ (EAs) → Rd Rd ⊕ (EAs) → Rd ¬ (EAd) → (EAd) ¬ (< Bit number > of < EAd >) → Z 1 → (< Bit number > of < EAd >) ¬ (< Bit number > of < EAd >) → Z 0 → (< Bit number > of < EAd >) ¬ (< Bit number > of < EAd >) → Z ¬ (< Bit number > of < EAd >) → Z → (< Bit number > of < EAd >) 365 Mnemonic Operation Branch- Bcc If condition is true then ing PC + disp → PC instrucelse next; Mnemonic Description tions BRA BRN BHI BLS BCC BCS BNE BEQ BVC BVS BPL BMI BGE BLT BGT BLE (BT) (BF) (BHS) (BLO) Always (True) Never (False) HIgh Low or Same Carry Clear (High or Same) Carry Set (LOw) Not Equal EQual oVerflow Clear oVerflow Set PLus MInus Greater or Equal Less Than Greater Than Less or Equal Effective address → PC Effective address → CP, PC PC → @ – SP PC + disp → PC JSR PC → @ – SP Effective address → PC PJSR PC → @ – SP CP → @ – SP Effective address → CP, PC RTS @ SP + → PC PRTS @ SP + → CP @ SP + → PC RTD @ SP + → PC SP + #IMM → SP PRTD @ SP + → CP @ SP + → PC SP + #IMM → SP SCB If condition is true then next; SCB/F else Rn – 1 → Rn; SCB/NE If Rn = –1 then next; SCB/EQ else PC + disp → PC; JMP PJMP BSR Mnemonic SCB/F SCB/NE SCB/EQ Description Not Equal Equal Condition False Z=0 Z=1 366 Size B/W — N — CCR Bit Z V C — — — Condition True False C∨Z=0 C∨Z=1 C=0 C=1 Z=0 Z=1 V=0 V=1 N=0 N=1 N⊕V=0 N⊕V=1 Z ∨ (N ⊕ V) = 0 Z ∨ (N ⊕ V) = 1 — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — Mnemonic Operation System TRAPA PC → @ – SP control (If MAX MODE CP → @ – SP) SR → @ – SP (If MAX MODE < vector > → CP) < vector > → PC TRAP/VS If V bit = “1” then TRAP else next; RTE @ SP + → SR (If MAX MODE @ SP + → CP) @ SP + → PC LINK FP (R6) → @ – SP SP → FP (R6) SP + #IMM → SP UNLK FP (R6) → SP @SP + → FP SLEEP Normal running mode → power-down state LDC (EAs) → CR STC CR → (EAd) ANDC CR ∧ #IMM → CR ORC CR ∨ #IMM → CR XORC CR ⊕ #IMM → CR NOP PC + 1 → PC * Depends on the CR. 367 Size B/W — N — CCR Bit Z V — — — — — — — — ↕ ↕ ↕ ↕ — — — — — — — — — — — B/W* B/W* B/W* B/W* B/W* — — — — — — — — — — — — — C — A.2 Instruction Codes Table A-1(a) to (d) shows the machine-language coding of each instruction. • How to read table A-1 (a) to (d) The general operand format consists of an effective address (EA) field and operation-code (OP) field specified in the following order. EA field 1 2 Op field 3 4 5 Bytes 2, 3, 5, 6 are not present in all instructions. 368 6 address (H) 1 0 1 1 Sz r r r 1 1 0 0 Sz r r r 0 0 0 0 Sz 1 0 1 0 0 0 1 Sz 1 0 1 0000 0 100 0000 1 100 @–Rn @Rn+ @aa:8 @aa:16 #xx:8 #xx:16 data (L) address 1 1 1 1 Sz r r r @(d:16, Rn) 4 2 2 3 4 3 3 4 2 2 3 4 MOV:G.B Rs , <EA d > 2 3 4 2 2 3 4 MOV:G.W Rs , <EAd > 2 3 4 2 2 3 4 1 Byte length of instruction data (H) disp (H) 1 1 1 0 Sz r r r @(d:8, Rn) 3 2 data disp 1 1 0 1 Sz r r r @Rn 2 2 Addressing mode Instruction address (L) disp (L) 3 2 MOV:G.W <EAs >, Rd 2 1 0 1 0 Sz r r r Rn Operation code (EA) MOV:G.B <EAs >, Rd Instruction Operation code (OP) 4 1 0 0 0 0 rd r d rd 4 1 0 0 0 0 rd r d rd 3 1 0 0 1 0 rs r s rs 4 1 0 0 1 0 rs r s rs Shading indicates addressing modes not available for this instruction. Some instructions have a special format in which the operation code comes first. The following notation is used in the tables. • Sz: 5 Operand size (byte or word) Byte: Sz = 0 Word: Sz = 1 369 6 • rrr : General register number field rrr Sz = 0 (Byte) 15 Sz = 1 (Word) 8 7 0 15 0 000 Not used R0 R0 001 Not used R1 R1 010 Not used R2 R2 011 Not used R3 R3 100 Not used R4 R4 101 Not used R5 R5 110 Not used R6 R6 111 Not used R7 R7 • ccc : Control register number field ccc Sz = 0 (Byte) 000 Sz = 1 (Word) 15 (Not allowed*) 7 0 SR 0 001 CCR (Not allowed) 010 (Not allowed) (Not allowed) 011 BR (Not allowed) 100 EP (Not allowed) 101 DP (Not allowed) 110 (Not allowed) (Not allowed) 111 TP (Not allowed) * “Not allowed” means that this combination of bits must not be specified. Specifying a disallowed combination may cause abnormal results. 370 • register list: A byte in which bits indicate general registers as follows Bit 7 6 5 4 3 2 1 0 R7 R6 R5 R4 R3 R2 R1 R0 • #VEC: Four bits designating a vector number from 0 to 15. The vector numbers correspond to addresses of entries in the exception vector table as follows: #VEC 0 1 2 3 4 5 6 7 Vector Address Minimum Mode Maximum Mode H'0020 – H'0021 H'0040 – H'0043 H'0022 – H'0023 H'0044 – H'0047 H'0024 – H'0025 H'0048 – H'004B H'0026 – H'0027 H'004C – H'004F H'0028 – H'0029 H'0050 – H'0053 H'002A – H'002B H'0054 – H'0057 H'002C – H'002D H'0058 – H'005B H'002E – H'002F H'005C – H'005F #VEC 8 9 10 11 12 13 14 15 Vector Address Minimum Mode Maximum Mode H'0030 – H'0031 H'0060 – H'0063 H'0032 – H'0033 H'0064 – H'0067 H'0034 – H'0035 H'0068 – H'006B H'0036 – H'0037 H'006C – H'006F H'0038 – H'0039 H'0070 – H'0073 H'003A – H'003B H'0074 – H'0077 H'003C – H'003D H'0078 – H'007B H'003E – H'003F H'007C – H'007F • Examples of machine-language coding Example 1: ADD:G.B @R0, R1 Table A-1 (a) Machine code EA Field OP Field 1101Szrrr 00100rdrdrd 11010000 00100 0 0 1 H'D021 Notes Machine code for ADD:G.B @Rs, Rd Sz = 0 (byte) Rs = R0, Rd = R1 Example 2: ADD:G.W @H'11:8, R1 Table A-1 (a) Machine code EA Field OP Field 0000Sz101 00010001 00100rdrdrd 0000 1 101 00010001 00100 0 0 1 H'0D1121 371 Notes Machine code for ADD:G.W @aa:8, Rd Sz = 1 (word) aa = H'11, Rd = R1 data (L) 1 1 0 0 Sz r r r 0 0 0 0 Sz 1 0 1 0 0 0 1 Sz 1 0 1 0000 0 100 0000 1 100 @Rn+ @aa:8 @aa:16 #xx:8 #xx:16 data (H) 1 0 1 1 Sz r r r @–Rn data 1 1 1 1 Sz r r r @(d:16, Rn) address (H) address disp (L) 1 1 1 0 Sz r r r @(d:8, Rn) disp 1 1 0 1 Sz r r r @Rn 2 3 4 2 2 3 4 3 MOV:G.W <EAs >, Rd 2 Addressing mode Data transfer instruction disp (H) 3 2 1 0 1 0 Sz r r r Rn Operation code (EA) 2 1 MOV:G.B <EAs >, Rd Instruction Arithmetic operation instruction address (L) Table A-1 (a) Machine Language Coding [General Format] Operation code (OP) 4 5 6 0 0 0 0 0 1 1 1 data (H) data (L) 1 0 0 0 0 rd rd rd 2 3 4 2 2 3 4 MOV:G.B Rs , <EA d > 2 3 4 2 2 3 4 1 0 0 1 0 rs rs rs MOV:G.W Rs , <EAd > 2 3 4 2 2 3 4 4 1 0 0 1 0 rs rs rs MOV:G.B #xx:8, <EA d> 3 4 5 3 3 4 5 0 0 0 0 0 1 1 0 data MOV:G.W #xx:8, <EA d > 3 4 5 3 3 4 5 0 0 0 0 0 1 1 0 data MOV:G.W #xx:16, <EA d > 4 5 6 4 4 5 6 LDM.W @SP+, 4 1 0 0 0 0 rd rd rd 2 <register list> 0 0 0 0 0 0 1 0 register list 2 STM.W <register list>,@–SP XCH.W Rs ,Rd 2 SWAP.B Rd 2 0 0 0 0 0 0 1 0 register list 1 0 0 1 0 rd rd rd 00010000 MOVTPE.B Rs , <EA d> 3 4 5 3 3 4 5 MOVTPE.B <EA s >, R d 3 4 5 3 3 4 5 ADD:G.B <EA s>, Rd 2 2 3 4 2 2 3 4 ADD:G.W <EA s >, Rd 2 2 3 4 2 2 3 4 0 0 0 0 0 0 0 0 1 0 0 1 0 rs rs rs 0 0 0 0 0 0 0 0 1 0 0 1 0 rd rd rd 3 0 0 1 0 0 rd rd rd 4 0 0 1 0 0 rd rd rd ADD:Q.B #1, <EA d>* 2 2 3 4 2 2 3 4 00001000 ADD:Q.W #1, <EAd >* 2 2 3 4 2 2 3 4 00001000 ADD:Q.B #2, <EA d >* 2 2 3 4 2 2 3 4 00001001 ADD:Q.W #2, <EAd >* 2 2 3 4 2 2 3 4 00001001 ADD:Q.B #-1, <EA d >* 2 2 3 4 2 2 3 4 00001100 ADD:Q.W #-1, <EA d>* 2 2 3 4 2 2 3 4 00001100 ADD:Q.B #-2, <EA d> * 2 2 3 4 2 2 3 4 00001101 ADD:Q.W #-2, <EA d >* 2 2 3 4 2 2 3 4 ADDS.B <EA s >, R d 2 2 3 4 2 2 3 4 ADDS.W <EA s >, Rd 2 2 3 4 2 2 3 4 ADDX.B <EA s >, R d 2 2 3 4 2 2 3 4 ADDX.W <EA s >, Rd 2 2 3 4 2 2 3 4 00001101 3 0 0 1 0 1 rd rd rd 4 0 0 1 0 1 rd rd rd 3 1 0 1 0 0 rd rd rd 4 1 0 1 0 0 rd rd rd Note: * Short format instruction 372 data (H) 1 0 1 1 Sz r r r 1 1 0 0 Sz r r r 0 0 0 0 Sz 1 0 1 0 0 0 1 Sz 1 0 1 0000 0 100 0000 1 100 @–Rn @Rn+ @aa:8 @aa:16 #xx:8 #xx:16 data (L) data 1 1 1 1 Sz r r r @(d:16, Rn) disp (H) disp Instruction address 1 1 1 0 Sz r r r @(d:8, Rn) address (H) disp (L) 1 1 0 1 Sz r r r @Rn 3 2 1 0 1 0 Sz r r r Rn Operation code (EA) Addressing mode 1 address (L) Table A-1 (a) Machine Language Coding [General Format] (cont) 5 6 0 0 0 0 0 0 0 0 1 0 1 0 0 rd rd rd DADD.B Rs ,Rd Arithmetic operation instruction Operation code (OP) 4 3 SUB.B <EA s >, R d 2 2 3 4 2 2 3 4 SUB.W <EA s >, R d 2 2 3 4 2 2 3 4 0 0 1 1 0 rd rd rd SUBS.B <EA s>, R d 2 2 3 4 2 2 3 4 SUBS.W <EA s >,R d 2 2 3 4 2 2 3 4 SUBX.B <EA s>, R d 2 2 3 4 2 2 3 4 SUBX.W <EA s >, R d 2 2 3 4 2 2 3 4 DSUB.B R s , R d 3 MULXU.B <EA s >, R d 2 2 3 4 2 2 3 4 MULXU.X <EA s >, R d 2 2 3 4 2 2 3 4 DIVXU.B <EA s >, R d 2 2 3 4 2 2 3 4 DIVXU.W <EA s >, R d 2 2 3 4 2 2 3 4 CMP:G.B <EA s>, R d 2 3 4 5 3 3 4 5 CMP:G.W <EAs >, R d 2 2 3 4 2 2 3 4 CMP:G.B #xx, <EAd > 3 4 5 3 3 4 5 0 0 0 0 0 1 0 0 data CMP:G.W #xx, <EA d > 4 5 6 4 4 5 6 0 0 0 0 0 1 0 1 data (H) 4 0 0 1 1 0 rd rd rd 3 0 0 1 1 1 rd rd rd 4 0 0 1 1 1 rd rd rd 3 1 0 1 1 0 rd rd rd 4 1 0 1 1 0 rd rd rd 0 0 0 0 0 0 0 0 1 0 1 1 0 rd rd rd 3 1 0 1 0 1 rd rd rd 4 1 0 1 0 1 rd rd rd 3 1 0 1 1 1 rd rd rd 4 1 0 1 1 1 rd rd rd 3 0 1 1 1 0 rd rd rd 4 0 1 1 1 0 rd rd rd EXTS.B R d 2 00010001 EXTU.B R d 2 TST.B <EAd > 2 2 3 4 2 2 3 4 00010110 TST.W <EA d > 2 2 3 4 2 2 3 4 00010110 NEG.B <EA d > 2 2 3 4 2 2 3 4 00010100 NEG.W <EAd > 2 2 3 4 2 2 3 4 00010100 CLR.B <EAd > 2 2 3 4 2 2 3 4 00010011 CLR.W <EA d > 2 2 3 4 2 2 3 4 00010011 TAS.B <EA d > 2 2 3 4 2 2 3 4 00010111 00010010 373 data (L) data (L) 1 0 1 1 Sz r r r 1 1 0 0 Sz r r r 0 0 0 0 Sz 1 0 1 0 0 0 1 Sz 1 0 1 0000 0 100 0000 1 100 @–Rn @Rn+ @aa:8 @aa:16 #xx:8 #xx:16 data (H) 1 1 1 1 Sz r r r @(d:16, Rn) 4 2 2 3 4 00011000 SHAL.W <EA d > 2 2 3 4 2 2 3 4 00011000 SHAR.B <EAd > 2 2 3 4 2 2 3 4 00011001 SHAR.W <EA d > 2 2 3 4 2 2 3 4 00011001 SHLL.B <EA d> 2 2 3 4 2 2 3 4 00011010 SHLL.W <EAd > 2 2 3 4 2 2 3 4 00011010 SHLR.B <EA d > 2 2 3 4 2 2 3 4 00011011 SHLR.W <EA d > 2 2 3 4 2 2 3 4 00011011 ROTL.B <EAd > 2 2 3 4 2 2 3 4 00011100 ROTL.W <EA d > 2 2 3 4 2 2 3 4 00011100 ROTR.B <EA d> 2 2 3 4 2 2 3 4 00011101 ROTR.W <EA d > 2 2 3 4 2 2 3 4 00011101 ROTXL.B <EA d > 2 2 3 4 2 2 3 4 00011110 ROTXL.W <EA d> 2 2 3 4 2 2 3 4 00011110 ROTXR.B <EA d > 2 2 3 4 2 2 3 4 00011111 ROTXR.W <EAd > 2 2 3 4 2 2 3 4 AND.B <EA s >, R d 2 2 3 4 2 2 3 4 AND.W <EA s >, R d 2 2 3 4 2 2 3 4 OR.B.B <EA s >, R d 2 2 3 4 2 2 3 4 OR.B.W <EA s >, Rd 2 2 3 4 2 2 3 4 XOR.B <EA s >, Rd 2 2 3 4 2 2 3 4 XOR.W <EAs >, R d 2 2 3 4 2 2 3 4 NOT.B <EAd > 2 2 3 4 2 2 3 4 00010101 NOT.W <EA d> 2 2 3 4 2 2 3 4 00010101 374 1 Addressing mode data disp (H) 1 1 1 0 Sz r r r @(d:8, Rn) address (H) disp 1 1 0 1 Sz r r r @Rn 3 SHAL.B <EA d > Shift instruction address disp (L) 3 2 2 1 0 1 0 Sz r r r Rn Operation code (EA) 2 Instruction Logic operation instruction address (L) Table A-1 (a) Machine Language Coding [General Format] (cont) Operation code (OP) 4 00011111 3 0 1 0 1 0 rd rd rd 4 0 1 0 1 0 rd rd rd 3 0 1 0 0 0 rd rd rd 4 0 1 0 0 0 rd rd rd 3 0 1 1 0 0 rd rd rd 4 0 1 1 0 0 rd rd rd 5 6 data (L) data (H) 0000 1 100 #xx:16 @aa:16 data 0 0 0 0 Sz 1 0 1 @aa:8 address (H) 1 1 0 0 Sz r r r @Rn+ 0000 0 100 1 0 1 1 Sz r r r @–Rn #xx:8 address 1 1 1 1 Sz r r r @(d:16, Rn) 0 0 0 1 Sz 1 0 1 disp (L) 1 1 1 0 Sz r r r @(d:8, Rn) disp 1 1 0 1 Sz r r r @Rn 3 4 2 2 3 4 1 1 0 0 (data) BSET.W #xx, <EA d > 2 2 3 4 2 2 3 4 1 1 0 0 (data) BSET.B R s , <EA d > 2 2 3 4 2 2 3 4 0 1 0 0 1 rs rs rs BSET.W Rs , <EA d > 2 2 3 4 2 2 3 4 0 1 0 0 1 rs rs rs BCLR.B #xx, <EAd > 2 2 3 4 2 2 3 4 1 1 0 1 (data) BCLR.W #xx, <EA d > 2 2 3 4 2 2 3 4 1 1 0 1 (data) BCLR.B R s , <EA d> 2 2 3 4 2 2 3 4 0 1 0 1 1 rs rs rs BCLR.W Rs , <EAd > 2 2 3 4 2 2 3 4 0 1 0 1 1 rs rs rs BTST.B #xx, <EAd > 2 2 3 4 2 2 3 4 1 1 1 1 (data) BTST.W #xx, <EA d> 2 2 3 4 2 2 3 4 1 1 1 1 (data) BTST.B Rs , <EA d > 2 2 3 4 2 2 3 4 0 1 1 1 1 rs rs rs BTST.W Rs , <EA d > 2 2 3 4 2 2 3 4 0 1 1 1 1 rs rs rs 1 1 1 0 (data) Addressing mode Bit manipulate instruction disp (H) 3 2 2 1 0 1 0 Sz r r r Rn Operation code (EA) 2 1 BSET.B #xx, <EA d > Instruction System control instruction address (L) Table A-1 (a) Machine Language Coding [General Format] (cont) Operation code (OP) 4 BNOT.B #xx, <EAd > 2 2 3 4 2 2 3 4 BNOT.W #xx, <EA d > 2 2 3 4 2 2 3 4 1 1 1 0 (data) BNOT.B R s , <EA d > 2 2 3 4 2 2 3 4 0 1 1 0 1 rs rs rs BNOT.W Rs , <EA d > 2 2 3 4 2 2 3 4 LDC.B <EAs >, CR 2 2 3 4 2 2 3 4 LDC.W <EA s >, CR 2 2 3 4 2 2 3 4 4 10001ccc STC.B CR, <EA d > 2 2 3 4 2 2 3 4 10011ccc STC.W CR, <EA d > 2 2 3 4 2 2 3 4 0 1 1 0 1 rs rs rs 3 10011ccc 3 ANDC.B #xx:8, CR 10001ccc 01011ccc 4 01011ccc ANDC.W #xx:16, CR 3 ORC.B #xx:8, CR 01001ccc 4 01001ccc ORC.W #xx:16, CR XORC.B #xx:8, CR 3 01101ccc 4 01101ccc XORC.W #xx:16, CR 375 5 6 Table A-1 (b) Machine Language Coding [Special Format: Short Format] Instruction MOV:E,B #xx:8,Rd MOV:I.W #xx:16,Rd MOV:L.B @aa:8,Rd MOV:L.W @aa:8,Rd MOV:S.B Rs,@aa:8 MOV:S.W Rs,@aa:8 MOV:F.B @(d:8,R6),Rd MOV:F.W @(d:8,R6),Rd MOV:F.B Rs @(d:8,R6) MOV:F.W Rs,@(d:8,R6) CMP:E #xx:8,Rd CMP:I #xx:16,Rd Bytes 2 3 2 2 2 2 2 2 2 2 2 3 1 01010rdrdrd 01011rdrdrd 01100rdrdrd 01101rdrdrd 01110rsrsrs 01111rsrsrs 10000rdrdrd 10001rdrdrd 10010rsrsrs 10011rsrsrs 01000rdrdrd 01001rdrdrd 376 Operation code 2 3 data data (H) address (L) address (L) address (L) address (L) disp disp disp disp data data (H) data (L) data (L) 4 Table A-1 (c) Machine Language Coding [Special Format: Branch Instruction] Instruction Bcc d:8 Bcc d:16 BRA (BT) BRN (BF) BHI BLS BCC (BHS) BCS (BLO) BNE BEQ BVC BVS BPL BMI BGE BLT BGT BLE BRA (BT) BRN (BF) BHI BLS BCC (BHS) BCS (BLO) BNE BEQ BVC BVS BPL BMI BGE BLT BGT BLE JMP @Rn JMP @aa:16 Bytes 2 3 2 3 1 00100000 00100001 00100010 00100011 00100100 00100101 00100110 00100111 00101000 00101001 00101010 00101011 00101100 00101101 00101110 00101111 00110000 00110001 00110010 00110011 00110100 00110101 00110110 00110111 00111000 00111001 00111010 00111011 00111100 00111101 00111110 00111111 00010001 00010000 377 Operation code 2 3 disp disp disp disp disp disp disp disp disp disp disp disp disp disp disp disp disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) disp (H) 11010rrr address (H) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) disp (L) address (L) 4 Table A-1 (c) Machine Language Coding [Special Format: Branch Instruction] (cont) Instruction Bytes JMP @(d:8,Rn) JMP @(d:16,Rn) BSR d:8 BSR d:16 JSR @Rn JSR @aa:16 JSR @(d:8,Rn) JSR @(d:16,Rn) RTS RTD #xx:8 RTD #xx:16 SCB/cc Rn,disp SCB/F SCB/NE SCB/EQ PJMP @aa:24 PJMP @Rn PJSR @aa:24 PJSR @Rn PRTS PRTD #xx:8 PRTD #xx:16 3 4 2 3 2 3 3 4 1 2 3 3 4 2 4 2 2 3 4 1 00010001 00010001 00001110 00011110 00010001 00011000 00010001 00010001 00011001 00010100 00011100 00000001 00000110 00000111 00010011 00010001 00000011 00010001 00010001 00010001 00010001 Operation code 2 3 11100rrr disp 11110rrr disp (H) disp disp (H) disp (L) 11011rrr address (H) address (L) 11101rrr disp 11111rrr disp (H) data data (H) 10111rrr 10111rrr 10111rrr page 11000rrr page 11001rrr 00011001 00010100 00011100 4 disp (L) disp (L) data (L) disp disp disp address (H) address (L) address (H) address (L) data data (H) data (L) Table A-1 (d) Machine Language Coding [Special Format: System Control Instructions] Instruction TRAPA #xx TRAP/VS RTE LINK FP,#xx:8 LINK FP,#xx:16 UNLK FP SLEEP NOP Bytes 2 1 1 2 3 1 1 1 1 00001000 00001001 00001010 00010111 00011111 00001111 00011010 00000000 378 Operation code 2 3 0001 #VEC data data (H) data (L) 4 A.3 Operation Code Map Tables A-2 through A-6 are maps of the operation codes. Table A-2 shows the meaning of the first byte of the instruction code, indicating both operation codes and addressing modes. Tables A-2 through A-6 indicate the meanings of operation codes in the second and third bytes. Table A-2 Operation Codes in Byte 1 LO 0 NOP HI 0 JMP 1 2 3 4 5 6 7 8 9 A B C D E F BRA d:8 BRA d:16 R0 1 SCB/F See Tbl. A-6 See Tbl. A-6 * BRN 2 LDM 3 PJSR @aa:24 STM PJMP @aa:24 4 #xx:8 See Tbl. A-5 RTD #xx:8 BHI BLS BRN BHI BLS R1 7 8 SCB/EQ TRAPA See Tbl. A-6 LINK JSR #xx:8 9 TRAP/V S A RTE RTS SLEEP Bcc 5 6 #aa:8.B SCB/NE See See Tbl. Tbl. A-4 A-6 @aa:16.B See Tbl. A-4 BCS BNE BEQ BVC BVS BPL BMI C D #xx:16 @aa:8.W See See Tbl. Tbl. A-5 A-4 @aa:16.W RTD #xx:16 See Tbl. A-4 BLT BGE Bcc BCS BEQ BVC BVS BPL BMI BGE R7 R0 CMP:E #xx:8, Rn R2 R3 R4 MOV:E #xx:8, Rn MOV:L.B @aa:8, Rn MOV:S.B Rn, @aa:8 MOV:F.B @ (d:8, R6), Rn MOV:F.B Rn, @ (d:8, R6) Rn @–Rn @Rn+ @Rn @(d:8,Rn) @(d:16,Rn) R5 (Byte) (Byte) (Byte) (Byte) (Byte) (Byte) BNE R6 See Table A-3 See Table A-4 See Table A-4 See Table A-4 See Table A-4 See Table A-4 R1 B BLT CMP:I #xx:16, Rn R2 R3 R4 R5 MOV:I #xx:16, Rn MOV:L.W @aa:8, Rn MOV:S.W Rn, @aa:8 MOV:F.W @ (:8, R6), Rn MOV:F.W Rn, @ (d:8,R6) (Word) Rn (Word) @–Rn (Word) @Rn+ (Word) @Rn (Word) @(d:8,Rn) (Word) @(d:16,Rn) Notes: References to tables A-3 through A-6 indicate that the instruction code has one or more additional bytes, described in those tables. * H'11 is the first operation code byte of the following instructions: JMP, JSR, PJSR (register indirect addressing mode) JMP, JSR (register indirect addressing mode with displacement) PRTS, PRTD (all addressing modes) E BSR d:8 F UNLK BSR d:16 LINK #xx:16 BGT BLE BGT BLE R6 R7 See Table A-3 See Table A-4 See Table A-4 See Table A-4 See Table A-4 See Table A-4 Table A-3 Operation Codes in Byte 2 (Axxx) LO 1 0 0 See Tbl. A-6* 1 SWAP EXTS HI 2 EXTU CLR R2 ADD R3 2 R0 R1 3 4 NEG R4 5 NOT R5 6 TST R6 7 TAS R7 8 9 ADD:Q #1 ADD:Q #2 SHAL SHAR R0 R1 A SHLL ADDS R2 B C D ADD:Q #-1 ADD:Q #-2 E F SHLR ROTL ROTR ROTXL ROTXR R3 R4 R5 R6 R7 3 SUB SUBS 4 OR BSET (Register indirect specification of bit number) 5 AND BCLR (Register indirect specification of bit number) 6 XOR BNOT (Register indirect specification of bit number) 7 CMP BTST (Register indirect specification of bit number) 8 MOV LDC XCH STC ADDX MULXU 9 A SUBX B C b0 b1 b2 b3 DIVXU b4 b5 BSET (Immediate specification of bit number) b6 b7 b8 b9 b10 D BCLR (Immediate specification of bit number) E BNOT (Immediate specification of bit number) F BTST (Immediate specification of bit number) b11 Note: The operation is inDSUB, byte 3,MOVTPE, given in table Note: ** Prefix code forcode DADD, andA-6. MOVFPE. The operation code is in byte 3, given in table A-6. b12 b13 b14 b15 Table A-4 Operation Codes in Byte 2 (05xx, 15xx, 0Dxx, 1Dxx, Bxxx, Cxxx, Dxxx, Exxx, Fxxx) LO HI 0 1 2 0 See Tbl. A-6* 1 2 3 CLR 4 5 CMP #xx:8 CMP #xx:16 MOV #xx:8 6 MOV #xx:16 7 ADD:Q #1 8 ADD:Q #2 9 NEG NOT TST TAS SHAL SHAR A SHLL B SHLR C D ADD:Q #-1 ADD:Q #-2 ROTL ROTR E F ROTXL ROTXR ADD ADDS 3 SUB SUBS 4 OR BSET (Register indirect specification of bit number) 5 AND BCLR (Register indirect specification of bit number) 6 XOR BNOT (Register indirect specification of bit number) 7 CMP BTST (Register indirect specification of bit number) 8 MOV (load) LDC 9 MOV (store) STC A B ADDX MULXU SUBX DIVXU C BSET (Immediate specification of bit number) D BCLR (Immediate specification of bit number) E BNOT (Immediate specification of bit number) F BTST (Immediate specification of bit number) Note: operation code is in DSUB, byte 3, given in table A-6. Note: ** The Prefix code for DADD, MOVTPE, and MOVFPE. The operation code is in byte 3, given in table A-6. Table A-5 Operation Codes in Byte 2 (04xx, 0Cxx) LO HI 0 0 1 2 3 4 5 6 7 8 9 A B 1 2 3 4 5 6 7 8 ADD ADDS SUB SUBS OR ORC AND ANDC XOR XORC CMP MOV LDC ADDX MULXU SUBX DIVXU 9 A B C D E F C D E F Table A-6 Operation Codes in Bytes 2 and 3 (11xx, 01xx, 06xx, 07xx, xx00xx) LO 0 HI 1 2 3 4 5 6 7 8 9 A B C D E F R6 R7 0 PRTD #xx:8 1 PRTS PRTD #xx:16 2 3 4 5 6 7 8 R0 R1 R2 MOVFPE R3 R4 R5 R6 R7 9 MOVTPE A DADD B DSUB C PJMP @Rn PJSR @Rn D JMP @Rn JSR @Rn E JMP @(d:8,Rn) JSR @(d:8,Rn) JMP @(d:16,Rn) JSR @(d:16,Rn) F R0 R1 SCB R2 R3 R4 R5 A.4 Instruction Execution Cycles Tables A-7 (1) through (6) list the number of cycles required by the CPU to execute each instruction in each addressing mode. The meaning of the symbols in the tables is explained below. The values of I, J, and K are used to calculate the number of execution cycles when off-chip memory is accessed for an instruction fetch or operand read/write. The formulas for these calculations are given next. A.4.1 Calculation of Instruction Execution States One state is one system clock cycle (ø). When ø = 10 MHz, one state = 100 ns. Instruction Fetch On-chip memory *1 Off-chip memory *2 Operand Read/Write On-chip memory, general register, or no operand On-chip memory module or off-chip memory *2 Number of States (Value given in table A-7) + (Value in table A-8) Byte On-chip memory, general register, or no operand On-chip supporting module or off-chip memory *2 (Value in table A-7) + (Value in table A-8) + I Word (Value in table A-7) + (Value in table A-8) + 2I (Value given in table A-7) + 2(J + K) Byte Word (Value in table A-7) + I + 2(J + K) (Value in table A-7) + 2(I + J + K) Notes: *1 When the instruction is fetched from on-chip memory (ROM or RAM), the number of execution states varies by 1 or 2 depending of whether the instruction is stored at an even or odd address. This difference must be noted when software is used for timing, and in other cases in which the exact number of states is important. *2 If wait states are inserted in access to external memory, add the necessary number of cycles. 384 A.4.2 Tables of Instruction Execution Cycles Tables A-7 (1) through (6) should be read as shown below: J + K = Instruction fetch cycles. Addressing mode @(d:16, Rn) @–Rn @Rn+ @aa:8 @aa:16 #xx:8 #xx:16 K J @(d:8, Rn) 1 @Rn Instruction Rn I: Total number of bytes written and read when operand is in memory. 1 1 2 3 1 1 2 3 2 3 3 ADD.B 1 1 2 5 5 6 5 6 5 6 ADD.W 2 1 2 5 5 6 5 6 5 6 ADD:Q.B 2 1 2 7 7 8 7 8 7 8 ADD:Q.W 4 1 2 7 7 8 7 8 7 8 2 4 DADD Shading in the I column means the operand cannot be in memory. 4 Shading indicates addressing modes that cannot be used with this instruction. 385 • Examples of Calculation of Number of States Required for Execution (Example 1) Instruction fetch from on-chip memory: ADD:G.W @R0, R1 Operand Read/Write On-chip memory or general register Start Addr. Even Odd Assembler Notation Address Code Mnemonic H'0100 H'D821 ADD:G.W @R0, R1 H'0101 H'D821 ADD:G.W @R0, R1 Table A-7 + Table A-8 5+1 5+0 Number of States 6 5 (Example 2) Instruction fetch from on-chip memory: JSR @R0 Branch Addr. Even Odd Assembler Notation Address Code Mnemonic H'FC00 H'11D8 JSR @R0 H'FC01 H'11D8 JSR @R0 Table A-7 + Table A-8 + 2I 9+0+2×2 9+1+2×2 Number of States 13 14 (Example 3) Instruction fetch from external memory Operand Read/Write On-chip memory or general register On-chip module or external memory Assembler Notation Address Code Mnemonic H'9002 H'D821 ADD:G.W @R0, R1 Table A-7 + 2(J + K) 5 + 2 × (1 + 1) Number of States 9 H'9002 5 + 2 × (2 + 1 + 1) 13 H'D821 ADD:G.W @R0, R1 386 Table A-7 Instruction Execution Cycles (1) @Rn+ @aa:8 @aa:16 #xx:8 #xx:16 1 @–Rn 1 @(d:16, Rn) ADD:G.B <EA s >, Rd K J @(d:8, Rn) 1 @Rn Instruction Rn Addressing mode 1 1 2 3 1 1 2 3 2 3 2 5 5 6 5 6 5 6 3 ADD:G.W <EA s >, Rd 2 1 2 5 5 6 5 6 5 6 ADD:Q.B #xx, <EA d > 2 1 2 7 7 8 7 8 7 8 ADD:Q.W #xx, <EA d > 4 1 2 7 7 8 7 8 7 8 ADDS.B <EA s >, R d 1 1 3 5 5 6 5 6 5 6 ADDS.W <EA s >, R d 2 1 3 5 5 6 5 6 5 6 ADDX.B <EA s >, Rd 1 1 2 5 5 6 5 6 5 6 ADDX.W <EA s >, R d 2 1 2 5 5 6 5 6 5 6 AND.B <EA s >, Rd 1 1 2 5 5 6 5 6 5 6 AND.W <EA s >, R d 2 1 2 5 5 6 5 6 5 6 ANDC #xx, CR 1 * 2 1 4 7 7 8 7 8 7 8 BCLR.W #xx, <EA d > * 4 1 4 7 7 8 7 8 7 8 BNOT.B #xx, <EA d > * 2 1 4 7 7 8 7 8 7 8 BNOT.W #xx, <EA d > * 4 1 4 7 7 8 7 8 7 8 BSET.B #xx, <EA d > * 2 1 4 7 7 8 7 8 7 8 BSET.W #xx, <EA d > * 4 1 4 7 7 8 7 8 7 8 BTST.B #xx, <EA d > * 1 1 3 5 5 6 5 6 5 6 BTST.W #xx, <EA d > * 2 1 3 5 5 6 5 6 5 6 CLR.B <EA d > 1 1 2 5 5 6 5 6 5 6 CLR.W <EA d > 2 1 2 5 5 6 5 6 5 6 CMP:G.B <EA s >, Rd 1 1 2 5 5 6 5 6 5 6 2 CMP:G.W <EA s >, Rd 2 1 5 5 6 5 6 5 6 CMP:G.B #XX:8, <EA> 1 2 6 6 7 6 7 6 7 CMP:G.B #XX:16, <EA> 2 3 7 7 8 7 8 7 8 387 3 4 3 4 3 4 5 BCLR.B #xx, <EA d > * Rs can also be specified as the source operand. 4 9 3 4 Table A-7 Instruction Execution Cycles (2) CMP:E#xx:8,Rd #xx:8, Rd CMP:E 0 CMP:I#xx:16,Rd #xx:16, Rd CMP:I 0 DADD Rs , R d DADD @(d:8,Rn) @(d:8, Rn) @(d:16,Rn) @(d:16, Rn) @-Rn @–Rn @Rn+ @Rn+ @aa:8 @aa:8 @aa:16 @aa:16 #xx:8 #xx:8 #xx:16 #xx:16 K I1 JJ @Rn @Rn Instruction Instruction Rn Rn Addressing mode 11 11 2 2 3 3 11 11 22 33 22 33 22 33 22 44 DIVXU.B <EA s >, Rd DIVXU.B 11 11 20 20 23 24 23 23 23 24 24 23 23 24 23 23 24 24 21 21 DIVXU.W <EAs >, Rd DIVXU.W 22 29 30 29 29 29 30 30 29 29 30 29 29 30 30 11 26 26 DSUB Rs , Rd DSUB 22 44 EXTS Rd EXTS 1 33 EXTU Rd EXTU 1 33 LDC.B <EA s >, CR LDC.B 11 1 33 66 66 7 66 77 66 77 LDC.W <EAs >, CR LDC.W 22 11 44 77 77 8 8 77 88 77 88 MOV:G.B MOV.B 11 1 22 55 55 6 55 66 55 66 MOV:G.W MOV.W 22 11 22 55 55 6 6 55 66 55 66 MOV.G.B #xx:8, <EAd > MOV.B #xx:8,<EA> 11 2 77 77 8 77 88 77 88 MOV.G.B #xx:16, <EA d > MOV.W #xx:16,<EA> 22 3 88 88 9 88 99 88 99 MOV:E#xx:8,Rd #xx:8, Rd MOV:E 00 MOV:I #xx:16,Rd #xx:16, R d MOV:I 44 66 33 44 22 0 33 MOV:L.B@aa:8,Rd @aa:8, Rd MOV:L.B 11 00 55 MOV:L.W@aa:8,Rd @aa:8, Rd MOV:L.W 22 0 55 MOV:S.BRs,@aa:8 R s ,@aa:8 MOV:S.B 11 0 55 MOV:S.WRs,@aa:8 Rs ,@aa:8 MOV:S.W 22 00 MOV:F.B@(d:8, @(d:8,R6), R6),Rd Rd MOV:F.B 11 0 55 MOV:F.W@(d:8, @(d:8,R6), R6),Rd Rd MOV:F.W 22 0 55 MOV:F.B MOV:F.BRs, Rs ,@(d:8, @(d:8,R6) R6) 11 0 55 MOV:F.W MOV:F.WRs, Rs ,@(d:8, @(d:8,R6) R6) 22 0 55 388 28 28 55 Table A-7 Instruction Execution Cycles (3) #xx:8 #xx:16 3 1 1 2 3 2 3 2 13 | 20 13 | 20 14 | 21 13 | 20 14 | 21 13 | 20 14 | 21 MOVTPE R s , <EA d > 0 2 13 | 20 13 | 20 14 | 21 13 14 | | 20 21 13 | 20 14 | 21 MULXU.B <EA s >, R d 1 1 16 19 19 20 19 20 19 20 1 @aa:8 2 0 @Rn+ 1 MOVFPE <EA s >, R d K J @–Rn 1 @Rn Instruction Rn @aa:16 @(d:16, Rn) @(d:8, Rn) Addressing mode MULXU.W <EA s >, R d 2 1 23 25 25 26 25 26 25 26 NEG.B <EA d > 2 1 2 7 7 8 7 8 7 8 NEG.W <EA d > 4 1 2 7 7 8 7 8 7 8 NOT.B <EA d> 2 1 2 7 7 8 7 8 7 8 NOT.W <EA d> 4 1 2 7 7 8 7 8 7 8 OR.B <EA s >, R d 1 1 2 5 5 6 5 6 5 6 OR.W <EA s >, R d 2 1 2 5 5 6 5 6 5 6 ORC #xx, CR 1 25 3 4 5 ROTL.B <EA d > 2 1 2 7 7 8 7 8 7 8 ROTL.W <EAd > 4 1 2 7 7 8 7 8 7 8 ROTR.B <EA d > 2 1 2 7 7 8 7 8 7 8 ROTR.W <EA d > 4 1 2 7 7 8 7 8 7 8 ROTXL.B <EA d > 2 1 2 7 7 8 7 8 7 8 ROTXL.W <EA d > 4 1 3 7 7 8 7 8 7 8 ROTXR.B <EA d > 2 1 2 7 7 8 7 8 7 8 ROTXR.W <EA d > 4 1 2 7 7 8 7 8 7 8 SHAL.B <EA d > 2 1 2 7 7 8 7 8 7 8 SHAL.W <EA d > 4 1 2 7 7 8 7 8 7 8 SHAR.B <EA d > 2 1 2 7 7 8 7 8 7 8 SHAR.W <EA d> 4 1 2 7 7 8 7 8 7 8 SHLL.B <EA d > 2 1 2 7 7 8 7 8 7 8 SHLL.W <EA d > 4 1 2 7 7 8 7 8 7 8 389 18 9 Table A-7 Instruction Execution Cycles (4) Rn @Rn @(d:8, Rn) @(d:16, Rn) @–Rn @Rn+ @aa:8 @aa:16 #xx:8 #xx:16 Addressing mode 1 1 2 3 1 1 2 3 2 3 SHLR.B <EA d > 2 1 2 7 7 8 7 8 7 8 SHLR.W <EAd > 4 1 2 7 7 8 7 8 7 8 STC.B CR, <EA d > 1 1 2 7 7 8 7 8 7 8 1 Instruction K J STC.W CR, <EA d > 2 1 2 7 7 8 7 8 7 8 SUB.B <EA s >, Rd 1 1 2 5 5 6 5 6 5 6 SUB.W <EA s >, Rd 2 1 2 5 5 6 5 6 5 6 SUBS.B <EA s >, Rd 1 1 3 5 5 6 5 6 5 6 SUBS.W <EA s >, Rd 2 1 3 5 5 6 5 6 5 6 SUBX.B <EA s >, Rd 1 1 2 5 5 6 5 6 5 6 SUBX.W <EA s >, Rd 2 1 2 5 5 6 5 6 5 6 7 7 8 7 8 7 8 SWAP R d TAS <EA d > 2 1 3 1 4 TST.B <EA d > 1 1 2 5 5 6 5 6 5 6 TST.W <EA d > 2 1 2 5 5 6 5 6 5 6 XCH Rs , R d 1 4 XOR.B <EA s >, Rd 1 1 2 5 5 6 5 6 5 6 XOR.W <EA s >, Rd 4 1 4 5 5 6 5 6 5 6 XORC #xx, CR 1 3 4 3 4 3 4 3 4 9 ↵ 5 * Zero divide, minimum mode DIVXU.B Zero divide, maximum mode DIVXU.W Zero divide, minimum mode DIVXU.W Zero divide, maximum mode DIVXU.B DIVXU.W ↵ * DIVXU.B 6 1 20 23 23 24 23 24 24 21 28 29 21 23 24 23 7 10 11 6 8 10 12 1 25 28 28 29 28 29 1 20 23 23 24 23 24 1 25 28 28 29 28 29 28 29 Overflow 1 1 8 11 11 12 11 12 11 12 Overflow 2 1 8 11 11 12 11 12 11 12 For register and immediate operands For memory operand 390 27 27 9 10 Table A-7 Instruction Execution Cycles (5) Instruction (Condition) Execution Cycles Bcc d:8 Condition false, branch not taken 3 2 Condition true, branch taken 7 5 Condition false, branch not taken 3 3 Condition true, branch taken 7 d:8 9 2 4 d:16 9 2 5 @aa:16 7 5 @Rn 6 5 @(d:8, Rn) 7 5 @(d:16, Rn) 8 @aa:16 9 2 5 @Rn 9 2 5 @(d:8, Rn) 9 2 5 @(d:16, Rn) 10 2 6 6 + 4n* 2n 2 #xx:8 6 2 2 #xx:16 7 2 3 Bcc d:16 BSR JMP JSR LDM LINK RTE SLEEP 6 1 #xx:8 9 2 4 #xx:16 9 2 5 Minimum mode 13 4 4 Maximum mode 15 6 4 8 2 4 RTS SCB J+K 6 2 NOP RTD I Condition false, branch not taken 3 3 Count = –1, branch not taken 4 3 Other than the above, branch taken 8 6 Cycles preceding transition to power- 2 0 down mode STM 6 + 3n* * n is the number of registers specified in the register list. 391 2n 2 Table A-7 Instruction Execution Cycles (6) Instruction (Condition) Execution Cycles I J+K TRAPA Minimum mode 17 6 4 Maximum mode 22 10 4 V = 0, trap not taken 3 V = 1, trap taken, minimum mode 18 6 4 V = 1, trap taken, maximum mode 23 10 4 5 2 1 TRAP/VS UNLK PJMP PJSR @aa:24 9 @Rn 8 @aa:24 15 4 6 @Rn 13 4 5 12 4 5 #xx:8 13 4 5 #xx:16 13 4 6 PRTS PRTD 1 6 5 Table A-8 (a) Adjusted Value (Branch Instruction) Instruction BSR, JMP, JSR, RTS, RTD, RTE TRAPA, PJMP, PJSR, PRTS, PRTD Bcc, SCB, TRAP/VS (When branch is taken) Address even odd even odd Adjusted Value 0 1 0 1 @(d:8, Rn) MOV.B #xx:8, <EA> even 1 1 1 1 1 1 1 odd 1 1 1 1 1 1 1 even 2 0 2 2 2 0 2 odd 0 2 0 0 0 2 0 #xx:16 0 1 0 1 1 1 0 1 0 0 odd 0 0 1 0 0 0 1 0 0 0 392 @Rn+ #xx:8 Instruction other than above @–Rn even Rn MOV.W #xx:16, <EA> @aa:16 Start address @aa:8 Instruction @Rn @(d:16, Rn) Table A-8 (b) Adjusted Value (Other Instructions by Addressing Modes) Appendix B Register Field B.1 Register Addresses and Bit Names Addr. Addr. (upper (lower Register byte) byte) Name Bit 7 H'80 P1DDR P17DDR H'81 P2DDR — H'82 P1DR P17 H'83 P1DR — H'84 P3DDR P37DDR H'85 P4DDR P47DDR H'86 P3DR P37 H'FE H'87 P4DR P47 H'88 P5DDR P57DDR H'89 P6DDR — H'8A P5DR P57 H'8B P6DR — H'8C P7DDR P77DDR H'8D — — H'8E P7DR P77 H'8F P8DR P87 H'90 TCR ICIE H'91 TCSR ICF H'92 FRC(H) H'93 FRC(L) H'94 OCRA(H) H'95 OCRA(L) H'96 OCRB(H) H'FE H'97 OCRB(L) H'98 ICR(H) H'99 ICR(L) H'9A — — H'9B — — H'9C — — H'9D — — H'9E — — H'9F — — Bit 6 P16DDR — P16 — P36DDR P46DDR P36 P46 P56DDR — P56 — P76DDR — P76 P86 OCIEB OCFB Bit 5 P15DDR — P15 — P35DDR P45DDR P35 P45 P55DDR — P55 — P75DDR — P75 P85 OCIEA OCFA Bit Names Bit 4 Bit 3 P14DDR P13DDR P24DDR P23DDR P14 P13 P24 P23 P34DDR P33DDR P44DDR P43DDR P34 P33 P44 P43 P54DDR P53DDR — P63DDR P54 P53 — P63 P74DDR P73DDR — — P74 P73 P84 P83 OVIE OEB OVF OLVLB Bit 2 P12DDR P22DDR P12 P22 P32DDR P42DDR P32 P42 P52DDR P62DDR P52 P62 P72DDR — P72 P82 OEA OLVLA Bit 1 P11DDR P21DDR P11 P21 P31DDR P41DDR P31 P41 P51DDR P61DDR P51 P61 P71DDR — P71 P81 CKS1 IEDG Bit 0 P10DDR P20DDR P10 P20 P30DDR P40DDR P30 P40 P50DDR P60DDR P50 P60 P70DDR — P70 P80 CKS0 CCLRA Module Port 1 Port 2 Port 1 Port 2 Port 3 Port 4 Port 3 Port 4 Port 5 Port 6 Port 5 Port 6 Port 7 — Port 7 Port 8 FRT 1 — — — — — — — — — — — — — — — — — — Note: FRT1: Free-Running Timer channel 1 — — — — — — — — — — — — — — — — — — — — — — — — (Continued on next page) 393 (Continued from preceding page) Addr. Addr. (upper (lower Register byte) byte) Name Bit 7 H'A0 TCR ICIE H'A1 TCSR ICF H'A2 FRC(H) H'A3 FRC(L) H'A4 OCRA(H) H'A5 OCRA(L) H'A6 OCRB(H) H'FE H'A7 OCRB(L) H'A8 ICR(H) H'A9 ICR(L) H'AA — — H'AB — — H'AC — — H'AD — — H'AE — — H'AF — — H'B0 TCR ICIE H'B1 TCSR ICF H'B2 FRC(H) H'B3 FRC(L) H'B4 OCRA(H) H'B5 OCRA(L) H'B6 OCRB(H) H'FE H'B7 OCRB(L) H'B8 ICR(H) H'B9 ICR(L) H'BA — — H'BB — — H'BC — — H'BD — — H'BE — — H'BF — — Bit 6 OCIEB OCFB Bit 5 OCIEA OCFA Bit 4 OVIE OVF Bit Names Bit 3 Bit 2 OEB OEA OLVLB OLVLA Bit 1 CKS1 IEDG Bit 0 Module CKS0 CCLRA FRT2 — — — — — — OCIEB OCFB — — — — — — OCIEA OCFA — — — — — — OVIE OVF — — — — — — OEB OLVLB — — — — — — OEA OLVLA — — — — — — CKS1 IEDG — — — — — — CKS0 CCLRA FRT 3 — — — — — — — — — — — — — — — — — — Notes: FRT2: Free-Running Timer channel 2 FRT3: Free-Running Timer channel 3 — — — — — — — — — — — — — — — — — — — — — — — — (Continued on next page) 394 (Continued from preceding page) Addr. Addr. (upper (lower Register byte) byte) Name Bit 7 H'C0 TCR OE H'C1 DTR H'C2 TCNT H'C3 — — H'C4 TCR OE H'C5 DTR H'C6 TCNT H'FE H'C7 — — H'C8 TCR OE H'C9 DTR H'CA TCNT H'CB — — H'CC — — H'CD — — H'CE — — H'CF — — H'D0 TCR CMIEB H'D1 TCSR CMFB H'D2 TCORA H'D3 TCORB H'D4 TCNT H'D5 — — H'D6 — — H'FE H'D7 — — H'D8 SMR C/A H'D9 BRR H'DA SCR TIE H'DB TDR H'DC SSR TDRE H'DD RDR H'DE — — H'DF — — Notes: PWM1: PWM2: PWM3: TMR: SCI1: Bit 6 OS Bit 5 — Bit 4 — Bit Names Bit 3 Bit 2 — CKS2 Bit 1 CKS1 Bit 0 CKS0 Module PWM1 — OS — — — — — — — CKS2 — CKS1 — CKS0 PWM2 — OS — — — — — — — CKS2 — CKS1 — CKS0 PWM3 — — — — — CMIEA CMFA — — — — — OVIE OVF — — — — — CCLR1 — — — — — — CCLR0 OS3 — — — — — CKS2 OS2 — — — — — CKS1 OS1 — — — — — CKS0 OS0 — TMR — — — CHR — — — PE — — — O/E — — — STOP — — — — — — — CKS1 — — — CKS0 RIE TE RE — — CKE1 CKE0 RDRF ORER FER PER — — — — — — — — — — — — — — — — — SCI1 (Continued on next page) Pulse-Width Modulation timer channel 1 Pulse-Width Modulation timer channel 2 Pulse-Width Modulation timer channel 3 8-Bit Timer Serial Communication Interface 1 395 (Continued from preceding page) Addr. Addr. (upper (lower Register byte) byte) Name Bit 7 H'E0 ADDRA(H) AD9 H'E1 ADDRA(L) AD1 H'E2 ADDRB(H) AD9 H'E3 ADDRB(L) AD1 H'E4 ADDRC(H) AD9 H'E5 ADDRC(L) AD1 H'E6 ADDRD(H) AD9 H'FE H'E7 ADDRD(L) AD1 H'E8 ADCSR ADF H'E9 — — H'EA — — H'EB — — H'EC TCSR* OVF H'ED TCNT* — H'EE — — H'EF — — H'F0 SMR C/A H'F1 BRR H'F2 SCR TIE H'F3 TDR H'F4 SSR TDRE H'F5 RDR H'F6 — — H'FE H'F7 — — H'F8 — — H'F9 — — H'FA — — H'FB — — H'FC SYSCR1 — H'FD SYSCR2 — H'FE P9DDR P97DDR H'FF P9DR P97 Bit 6 AD8 AD0 AD8 AD0 AD8 AD0 AD8 AD0 ADIE — — — WT/IT — — — CHR Bit 5 AD7 — AD7 — AD7 — AD7 — ADST — — — TME — — — PE Bit 4 AD6 — AD6 — AD6 — AD6 — SCAN — — — — — — — O/E RIE TE RE RDRF ORER — — — — — — IRQ1E IRQ5E P96DDR P96 — — — — — — IRQ0E IRQ4E P95DDR P95 Bit Names Bit 3 AD5 — AD5 — AD5 — AD5 — CKS — — — — — — — STOP Bit 2 AD4 — AD4 — AD4 — AD4 — CH2 — — — CKS2 — — — — Bit 1 AD3 — AD3 — AD3 — AD3 — CH1 — — — CKS1 — — — CKS2 Bit 0 AD2 — AD2 — AD2 — AD2 — CH0 — — — CKS0 — — — CKS0 — — OKE1 OKE2 FER — — — — — — — — — — NMIEG IRQ3E P94DDR P94 — — — — — — BRLE IRQ2E P93DDR P93 — — — — — — — P6PWME P92DDR P92 — — — — — — — P9PWME P91DDR P91 — — — — — — — P9SCI2E P90DDR P90 Module A/D WDT — SCI2 — Port 1 Port 6,9 Port 9 Notes: (Continued on next page) A/D: Analog-to-Digital converter WDT: Watchdog Timer SCI2: Serial Communication Interface 2 * Read addresses are shown. Write addresses of both TCSR and TCNT are H'FEED. See section 13.2.4, “Notes on Register Access” for details. 396 (Continued from preceding page) Addr. Addr. (upper (lower Register byte) byte) Name Bit 7 H'00 IPRA — H'01 IPRB — H'02 IPRC — H'03 IPRD — H'04 IPRE — H'05 IPRF — H'06 — — H'FF H'07 — — H'08 DTEA — H'09 DTEB — H'0A DTEC — H'0B DTED — H'0C DTEE — H'0D DTEF — H'0E — — H'0F — — H'10 WCR — H'11 RAMCR RAME H'12 MDCR — H'13 SBYCR SSBY H'14 WCR H'15 RSTCSR WRST H'16 — — H'FF H'17 — — H'18 — — H'19 — — H'1A — — H'1B — — H'1C — — H'1D — — H'1E — — H'1F — — Bit 6 — — — — OCIB1 OCIB3 TXI1 — — — — — — — Bit 5 Bit 4 IRQ0 IRQ2/IRQ3 FRT1 FRT3 SCI1 A/D — — — — — IRQ0 IRQ3 IRQ2 OCIA1 ICI1 OCIA3 ICI3 RXI1 — — ADI — — — — — — — — — — — — RSTOE — — — — — — — — — — — — — — — — — — — — — Bit Names Bit 3 — — — — — — — — — — — — — — — — WMS1 — — — Bit 2 — — — — — OCIB2 — TXI2 — — — WMS0 — MDS2 — Bit 1 Bit 0 IRQ1 IRQ4/IRQ5 FRT2 8 Bit Timer SCI2 — — — — — — — IRQ1 IRQ5 IRQ4 OCIA2 ICI2 CMIB CMIA RXI2 — — — — — — — WC1 WC0 — — MDS1 MDS0 — — — — — — — — — — — — — — — — — — — — — — — — Module INTC WSC RAM — WDT — — — — — — — — — — — Notes: INTC: Interrupt Controller WSC: Wait State Controller WDT: Watchdog Timer 397 — — — — — — — — — — — — — — — — — — — — — — — B.2 Register Descriptions Register name Acronym of the register Address to which the register is mapped SYSCR1—System Control Register 1 Bit numbers Initial bit values Bit Name of the on-chip supporting module H'FEFC Port 1 7 6 5 4 3 2 1 0 — IRQ1E IRQ0E NMIEG BRLE — — — Initial value 1 0 0 0 0 1 1 1 Read/Write — R/W R/W R/W R/W — — — Type of access permitted R Read only W Write only R/W Both read and write Names of the bits. Dashes (—) indicate reserved bits. Bus Release Enable 0 P12 and P13 are I/O ports. 1 P12 is the BACK output pin. P13 is the BREQ input pin. Full name of the bit Nonmaskable Interrupt Edge 0 An NMI request is generated on the falling edge of the NMI pin input. 1 An NMI request is generated on the rising edge of the NMI pin input. Functions of the bit settings Interrupt Request 0 Enable 0 P15 is an I/O port; IRQ0 input is disabled. 1 P15 is the IRQ0 input pin. Interrupt Request 1 Enable 0 P16 is an I/O port; IRQ1 input is disabled. 1 P16 is the IRQ1 input pin. 398 P1DDR—Port 1 Data Direction Register Bit 7 6 5 H'FE80 4 3 Port 1 2 1 0 P17DDR P16DDR P15DDR P14DDR P13DDR P12DDR P11DDR P10DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W Port 1 Input/Output Selection 0 Input port 1 Output port P2DDR—Port 2 Data Direction Register Bit H'FE81 4 3 Port 2 7 6 5 2 1 0 — — — Initial value 1 1 1 0 0 0 0 0 Read/Write — — — W W W W W P24DDR P23DDR P22DDR P21DDR P20DDR Port 2 Input/Output Selection 0 Input port 1 Output port P1DR—Port 1 Data Register Bit H'FE82 Port 1 7 6 5 4 3 2 1 0 P17 P16 P15 P14 P13 P12 P11 P10 Initial value 0 0 0 0 0 0 — — Read/Write R/W R/W R/W R/W R/W R/W R R 399 P2DR—Port 2 Data Register Bit H'FE83 Port 2 7 6 5 4 3 2 1 0 — — — P24 P23 P22 P21 P20 Initial value 1 1 1 0 0 0 0 0 Read/Write — — — R/W R/W R/W R/W R/W P3DDR—Port 3 Data Direction Register Bit 7 6 5 H'FE84 4 3 Port 3 2 1 0 P37DDR P36DDR P35DDR P34DDR P33DDR P32DDR P31DDR P30DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W Port 3 Input/Output Selection 0 Input port 1 Output port P4DDR—Port 4 Data Direction Register Bit 7 6 5 H'FE85 4 3 Port 4 2 1 0 P47DDR P46DDR P45DDR P44DDR P43DDR P42DDR P41DDR P40DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W Port 4 Input/Output Selection 0 Input port 1 Output port P3DR—Port 3 Data Register Bit H'FE86 Port 3 7 6 5 4 3 2 1 0 P37 P36 P35 P34 P33 P32 P31 P30 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W 400 P4DR—Port 4 Data Register Bit H'FE87 Port 4 7 6 5 4 3 2 1 0 P47 P46 P45 P44 P43 P42 P41 P40 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W P5DDR—Port 5 Data Direction Register Bit 7 6 5 H'FE88 4 3 Port 5 2 1 0 P57DDR P56DDR P55DDR P54DDR P53DDR P52DDR P51DDR P50DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W Port 5 Input/Output Selection 0 Input port 1 Output port P6DDR—Port 6 Data Direction Register Bit H'FE89 3 Port 6 7 6 5 4 2 1 0 — — — — Initial value 1 1 1 1 0 0 0 0 Read/Write — — — — W W W W P63DDR P62DDR P61DDR P60DDR Port 6 Input/Output Selection 0 Input port 1 Output port P5DR—Port 5 Data Register Bit H'FE8A Port 5 7 6 5 4 3 2 1 0 P57 P56 P55 P54 P53 P52 P51 P50 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W 401 P6DR—Port 6 Data Register Bit H'FE8B Port 6 7 6 5 4 3 2 1 0 — — — — P63 P62 P61 P60 Initial value 1 1 1 1 0 0 0 0 Read/Write — — — — R/W R/W R/W R/W P7DDR—Port 7 Data Direction Register Bit 7 6 5 H'FE8C 4 3 Port 7 2 1 0 P77DDR P76DDR P75DDR P74DDR P73DDR P72DDR P71DDR P70DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W Port 7 Input/Output Selection 0 Input port 1 Output port P7DR—Port 7 Data Register Bit H'FE8E Port 7 7 6 5 4 3 2 1 0 P77 P76 P75 P74 P73 P72 P71 P70 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W P8DR—Port 8 Data Register Bit Read/Write H'FE8F Port 8 7 6 5 4 3 2 1 0 P87 P86 P85 P84 P83 P82 P81 P80 R R R R R R R R 402 TCR—Timer Control Register Bit H'FE90 FRT1 7 6 5 4 3 2 1 0 ICIE OCIEB OCIEA OVIE OEB OEA CKS1 CKS0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Clock Select 00 Internal clock source: ø4 01 Internal clock source: ø8 10 Internal clock source: ø32 11 External clock source: counted on rising edge Output Enable A 0 Compare-A output is disabled. 1 Compare-A output is enabled. Output Enable B 0 Compare-B output is disabled. 1 Compare-B output is enabled. Timer Overflow Interrupt Enable 0 Overflow interrupt request is disabled. 1 Overflow interrupt request is enabled. Output Compare Interrupt Enable A 0 Compare-match A interrupt request is disabled. 1 Compare-match A interrupt request is enabled. Output Compare Interrupt Enable B 0 Compare-match B interrupt request is disabled. 1 Compare-match B interrupt request is enabled. Input Capture Interrupt Enable 0 Input capture interrupt is disabled. 1 Input capture interrupt is enabled. 403 TCSR—Timer Control/Status Register Bit H'FE91 FRT1 7 6 5 4 3 2 1 0 ICF OCFB OCFA OVF OLVLB OLVLA IEDG CCLRA Initial value 0 0 0 0 0 0 0 0 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* R/W R/W R/W R/W Counter Clear A 0 FRC count is not cleared. 1 FRC count is cleared by comparematch A. Input Edge Select 0 Count is captured on falling edge of input capture signal (FTI). 1 Count is captured on rising edge of input capture signal. 0 1 0 1 0 1 0 1 Output Level A Compare-match A causes 0 output. Compare-match A causes 1 output. Output Level B Compare-match B causes 0 output. Compare-match B causes 1 output. Timer Overflow Cleared from 1 to 0 when CPU reads OVF = 1, then writes 0 in OVF. Set to 1 when FRC changes from H'FFFF to H'0000. Output Compare Flag A Cleared from 1 to 0 when: 1. CPU reads OCFA = 1, then writes 0 in OCFA. 2. OCIA interrupt is served by DTC. Set to 1 when FRC = OCRA. Output Compare Flag B Cleared from 1 to 0 when: 1. CPU reads OCFB = 1, then writes 0 in OCFB. 2. OCIB interrupt is served by DTC. 1 Set to 1 when FRC = OCRB. Input Capture Flag 0 Cleared from 1 to 0 when: 1. CPU reads ICF = 1, then writes 0 in ICF. * Only writing of a 0 to 2. ICI interrupt is served by DTC. clear the flag is enabled. 1 Set to 1 when input capture signal is received and FRC count is copied to ICR. 0 404 FRC (H and L)—Free-Running Counter H'FE92, H'FE93 FRT 1 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Count value OCRA (H and L)—Output Compare Register A H'FE94, H'FE95 FRT 1 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Continually compared with FRC. OCFA is set to 1 when OCRA = FRC. OCRB (H and L)—Output Compare Register B H'FE96, H'FE97 FRT 1 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Continually compared with FRC. OCFB is set to 1 when OCRB = FRC. ICR (H and L)—Input Capture Register H'FE98, H'FE99 FRT 1 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R Contains FRC count captured when external input capture signal changes. 405 TCR—Timer Control Register Bit H'FEA0 FRT 2 7 6 5 4 3 2 1 0 ICIE OCIEB OCIEA OVIE OEB OEA CKS1 CKS0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. TCSR—Timer Control/Status Register Bit H'FEA1 FRT 2 7 6 5 4 3 2 1 0 ICF OCFB OCFA OVF OLVLB OLVLA IEDG CCLRA Initial value 0 0 0 0 0 0 0 0 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. * Only writing of a 0 to clear the flag is enabled. FRC (H and L)—Free-Running Counter H'FEA2, H'FEA3 FRT 2 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. 406 OCRA (H and L)—Output Compare Register A H'FEA4, H'FEA5 FRT 2 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. OCRB (H and L)—Output Compare Register B H'FEA6, H'FEA7 FRT 2 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. ICR (H and L)—Input Capture Register H'FEA8, H'FEA9 FRT 2 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R Note: Bit functions are the same as for FRT1. TCR—Timer Control Register Bit H'FEB0 FRT 3 7 6 5 4 3 2 1 0 ICIE OCIEB OCIEA OVIE OEB OEA CKS1 CKS0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. 407 TCSR—Timer Control/Status Register Bit H'FEB1 FRT 3 7 6 5 4 3 2 1 0 ICF OCFB OCFA OVF OLVLB OLVLA IEDG CCLRA Initial value 0 0 0 0 0 0 0 0 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. * Only writing of 0 to clear the flag is enabled. FRC (H and L)—Free-Running Counter H'FEB2, H'FEB3 FRT 3 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. OCRA (H and L)—Output Compare Register A H'FEB4, H'FEB5 FRT 3 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. 408 OCRB (H and L)—Output Compare Register B H'FEB6, H'FEB7 FRT 3 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for FRT1. ICR (H and L)—Input Capture Register H'FEB8, H'FEB9 FRT 3 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R Note: Bit functions are the same as for FRT1. 409 TCR—Timer Control Register Bit H'FEC0 PWM1 7 6 5 4 3 2 1 0 OE OS — — — CKS2 CKS1 CKS0 Initial value 0 0 1 1 1 0 0 0 Read/Write R/W R/W — — — R/W R/W R/W Clock Select (Values When ø = 10MHz) Internal ResoPWM PWM Clock Freq. lution Period Frequency ø/2 200 ns 50 µs 20 kHz ø/8 800 ns 200 µs 5 kHz ø/32 3.2 µs 800 µs 1.25 kHz ø/128 12.8 µs 3.2 ms 312.5 kHz ø/256 25.6 µs 6.4 ms 156.3 Hz ø/1024 102.4 µs 25.6 ms 39.1 Hz ø/2048 204.8 µs 51.2 ms 19.5 Hz ø/4096 409.6 µs 102.4 ms 9.8 Hz 000 001 010 011 100 101 110 111 Output Select 0 Positive logic 1 Negative logic Output Enable 0 PWM output disabled; TCNT cleared to H'00 and stops. 1 PWM output enabled; TCNT runs. DTR—Duty Register H'FEC1 PWM1 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Pulse duty factor 410 TCNT—Timer Counter H'FEC2 PWM1 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* Count value (runs from H'00 to H'F9, then repeats from H'00) * Write function is for test purposes only. Writing to this register during normal operation may have unpredictable effects TCR—Timer Control Register Bit H'FEC4 PWM2 7 6 5 4 3 2 1 0 OE OS — — — CKS2 CKS1 CKS0 Initial value 0 0 1 1 1 0 0 0 Read/Write R/W R/W — — — R/W R/W R/W Note: Bit functions are the same as for PWM1. DTR—Duty Register H'FEC5 PWM2 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for PWM1. 411 TCNT—Timer Counter H'FEC6 PWM2 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* Note: Bit functions are the same as for PWM1. * Write function is for test purposes only. Writing to this register during normal operation may have unpredictable effects TCR—Timer Control Register Bit H'FEC8 PWM3 7 6 5 4 3 2 1 0 OE OS — — — CKS2 CKS1 CKS0 Initial value 0 0 1 1 1 0 0 0 Read/Write R/W R/W — — — R/W R/W R/W Note: Bit functions are the same as for PWM1. DTR—Duty Register H'FEC9 PWM3 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for PWM1. 412 TCNT—Timer Counter H'FECA PWM3 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* Note: Bit functions are the same as for PWM1. * Write function is for test purposes only. Writing to this register during normal operation may have unpredictable effects. 413 TCR—Timer Control Register Bit H'FED0 TMR 7 6 5 4 3 2 1 0 CMIEB CMIEA OVIE CCLR1 CCLR0 CKS2 CKS1 CKS0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W 0 0 0 0 0 1 0 1 0 0 1 1 1 0 0 1 0 1 1 1 0 1 1 1 0 0 1 1 0 1 0 1 Clock Select No clock source; timer stops. Internal clock source: ø/8, counted on falling edge. Internal clock source: ø/64, counted on falling edge. Internal clock source: ø/1024, counted on falling edge. No clock source; timer stops. External clock source, counted on rising edge. External clock source, counted on falling edge. External clock source, counted on both rising and falling edges. Counter Clear Counter is not cleared. Cleared by compare-match A. Cleared by compare-match B. Cleared on rising edge of external reset input. Timer Overflow Interrupt Enable 0 Overflow interrupt request is disabled. 1 Overflow interrupt request is enabled. Compare-Match Interrupt Enable A 0 Compare-match A interrupt request is disabled. 1 Compare-match A interrupt request is enabled. Compare-Match Interrupt Enable B 0 Compare-match B interrupt request is disabled. 1 Compare-match B interrupt request is enabled. 414 TCSR—Timer Control/Status Register Bit H'FED1 TMR 7 6 5 4 3 2 1 0 CMFB CMFA OVF — OS3*2 OS2*2 OS1*2 OS0*2 Initial value 0 0 0 1 0 0 0 0 Read/Write R/(W)*1 R/(W)*1 R/(W)*1 — R/W R/W R/W R/W 0 0 1 1 0 1 0 1 Output Select No change on compare-match A. Output 0 on compare-match A. Output 1 on compare-match A. Invert (toggle) output on compare-match A. Output Select 0 0 No change on compare-match B. 0 1 Output 0 on compare-match B. 1 0 Output 1 on compare-match B. 1 1 Invert (toggle) output on compare-match B. Timer Overflow Flag 0 Cleared from 1 to 0 when CPU reads OVF = 1, then writes 0 in OVF. 1 Set to 1 when TCNT changes from H'FF to H'00. Compare-Match Flag A 0 Cleared from 1 to 0 when: 1. CPU reads CMFA = 1, then writes 0 in CMFA. 2. CMA interrupt is served by the DTC. 1 Set to 1 when TCNT = TCORA. Compare-Match Flag B 0 Cleared from 1 to 0 when: 1. CPU reads CMFB = 1, then writes 0 in CMFB. 2. CMB interrupt is served by the DTC. 1 Set to 1 when TCNT = TCORB. *1 Only writing of 0 to clear the flag is enabled. *2 When all four bits (OS3 to OS0) are cleared to 0, output is disabled. 415 TCORA—Time Constant Register A H'FED2 TMR Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The CMFA bit is set to 1 when TCORA = TCNT. TCORB—Time Constant Register B H'FED3 TMR Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W The CMFB bit is set to 1 when TCORB = TCNT. TCNT—Timer Counter H'FED4 TMR Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Count value 416 SMR—Serial Mode Register Bit H'FED8 SCI1 7 6 5 4 3 2 1 0 C/A CHR PE O/E STOP — CKS1 CKS0 Initial value 0 0 0 0 0 1 0 0 Read/Write R/W R/W R/W R/W R/W — R/W R/W 0 0 1 1 0 1 0 1 Clock Select ø clock ø/4 clock ø/16 clock ø/64 clock Stop Bit Length 0 One stop bit 1 Two stop bits Parity Mode 0 Even parity 1 Odd parity Parity Enable 0 Transmit: No parity bit added. Receive: Parity bit not checked. 1 Transmit: Parity bit added. Receive: Parity bit checked. Character Length 0 8-Bit data length 1 7-Bit data length Communication Mode 0 Asynchronous 1 Synchronous 417 BRR—Bit Rate Register H'FED9 SCI1 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Constant that determines the baud rate SCR—Serial Control Register Bit H'FEDA SCI1 7 6 5 4 3 2 1 0 TIE RIE TE RE — — CKE1 CKE0 Initial value 0 0 0 0 1 1 0 0 Read/Write R/W R/W R/W R/W — — R/W R/W Clock Enable 0 0 SCK pin is NOT USED. 1 SCK pin is used for output. Clock Enable 1 0 Internal clock 1 External clock, input at SCK pin Receive Enable 0 Receive disabled 1 Receive enabled Transmit Enable 0 Transmit disabled 1 Transmit enabled Receive Interrupt Enable 0 Receive interrupt request (RXI) is disabled. 1 Receive interrupt request (RXI) is enabled. Transmit Interrupt Enable 0 Transmit interrupt request (TXI) is disabled. 1 Transmit interrupt request (TXI) is enabled. 418 TDR—Transmit Data Register H'FEDB SCI1 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Transmit data 419 SSR—Serial Status Register Bit H'FEDC SCI1 7 6 5 4 3 2 1 0 TDRE RDRF ORER FER PER — — — Initial value 1 0 0 0 0 1 1 1 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* R/(W)* — — — Parity Error 0 Cleared from 1 to 0 when: 1. CPU reads PER = 1, then writes 0 in PER. 2. The chip is reset or enters a standby mode. 1 Set to 1 when a parity error occurs (parity of receive data does not match parity selected by bit). Framing Error 0 Cleared from 1 to 0 when: 1. CPU reads FER = 1, then writes 0 in FER. 2. The chip is reset or enters a standby mode. 1 Set to 1 when a framing error occurs (stop bit is 0). Overrun Error 0 Cleared from 1 to 0 when: 1. CPU reads ORER = 1, then writes 0 in ORER. 2. The chip is reset or enters a standby mode. 1 Set to 1 when an overrun error occurs (next data is completely received while RDRF bit is set to 1). Receive Data Register Full 0 Cleared from 1 to 0 when: 1. CPU reads RDRF = 1, then writes 0 in RDRF. 2. RDR is read by the DTC. 3. The chip is reset or enters a standby mode. 1 Set to 1 when one character is received normally and transferred from RSR to RDR. Transmit Data Register Empty 0 Cleared from 1 to 0 when: 1. CPU reads TDRE = 1, then writes 0 in TDRE. 2. The DTC writes data in TDR. 1 Set to 1 when: 1. The chip is reset or enters a standby mode. 2. Data is transferred from TDR to TSR. 3. CPU reads TDRE = 0, then clears 0 in TE. * Only writing of 0 to clear the flag is enabled. 420 RDR—Receive Data Register H'FEDD SCI1 Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R Receive data ADDRn (H)—A/D Data Register n (High) H'FEE0, H'FEE2, H'FEE4, H'FEE6 Bit (n = A, B, C, D) A/D 7 6 5 4 3 2 1 0 AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R Upper 8 bits of 10-bit A/D conversion result ADDRn (L)—A/D Data Register n (Low) H'FEE1, H'FEE3, H'FEE5, H'FEE7 Bit (n = A, B, C, D) A/D 7 6 5 4 3 2 1 0 AD1 AD0 — — — — — — Initial value 0 0 0 0 0 0 0 0 Read/Write R R R R R R R R Lower 2 bits of 10-bit A/D conversion result 421 ADCSR—A/D Control/Status Register Bit H'FEE8 A/D 7 6 5 4 3 2 1 0 ADF ADIE ADST SCAN CKS CH2 CH1 CH0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/(W)* R/W R/W R/W R/W R/W R/W R/W CH2 CH1 CH0 0 0 0 1 0 1 0 1 1 0 0 0 1 1 1 0 1 1 Channel Select Single Mode Scan Mode AN0 AN0 AN1 AN0, AN1 AN2 AN0 to AN2 AN3 AN0 to AN3 AN4 AN4 AN5 AN4, AN5 AN6 AN4 to AN6 AN7 AN4 to AN7 Clock Select 0 Conversion time = 274 states 1 Conversion time = 138 states Scan Mode 0 Single mode 1 Scan mode A/D Start 0 A/D conversion is halted. 1 1. Single mode: One A/D conversion is performed, then this bit is automatically cleared to 0. 2. Scan mode: A/D conversion starts and continues cyclically on all selected channels until 0 is written in this bit. A/D Interrupt Enable 0 The A/D interrupt request (ADI) is disabled. 1 The A/D interrupt request (ADI) is enabled. A/D End Flag 0 Cleared from 1 to 0 when: 1. The chip is reset or enters a standby mode. 2. CPU reads ADF = 1, then writes 0 in ADF. 3. DTC is served by ADI. 1 Set to 1 at the following times: 1. Single mode: at the completion of A/D conversion. 2. Scan mode: when all selected channels have been converted. * Only writing of 0 to clear the flag is enabled. 422 ADCR—A/D Control Register Bit H'FEE9 A/D 7 6 5 4 3 2 1 0 TRGE — — — — — — — Initial value 0 1 1 1 1 1 1 1 Read/Write R/W Trigger Enable 0 The A/D external trigger is disabled. 1 The A/D external trigger is enabled. A/D conversion starts on the falling edge of ADTRG. 423 H'FEEC*1, H'FEED*2 TCSR—Timer Status/Control Register Bit WDT 7 6 5 4 3 2 1 0 OVF WT/IT TME — — CKS2 CKS1 CKS0 Initial value 0 0 0 1 1 0 0 0 Read/Write R/(W)*3 R/W R/W — — R/W R/W R/W 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1 0 1 0 1 0 1 0 1 Clock Select ø/2 (51.2 µs)*4 ø/32 (819.2 µs) ø/64 (1.6 ms) ø/128 (3.3 ms) ø/256 (6.6 ms) ø/512 (13.1 ms) ø/2048 (52.4 ms) ø/4096 (104.9 ms) Timer Enable 0 Timer is disabled. • TCNT is initialized to H'00 and stopped. 1 Timer is enabled. • TCNT starts incrementing. • CPU interrupt request is enabled. Timer Mode Select 0 Interval timer mode (IRQ0 interrupt request) 1 Watchdog timer mode (NMI interrupt request) Overflow Flag 0 Cleared from 1 to 0 when CPU reads OVF = 1, then wtites 0 in OVF. 1 Set to 1 when TCNT changes from H'FF to H'00. *1 *2 *3 *4 Read address Write address Only writing of 0 to clear the flag is enabled. Times in parentheses are the times for TCNT to increment from H'00 to H'FF and change to H'00 again when ø = 10 MHz. 424 TCNT—Timer Counter H'FEED WDT Bit 7 6 5 4 3 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Count value SMR—Serial Mode Register Bit H'FEF0 SCI2 7 6 5 4 3 2 1 0 C/A CHR PE O/E STOP — CKS1 CKS0 Initial value 0 0 0 0 0 1 0 0 Read/Write R/W R/W R/W R/W R/W — R/W R/W Note: Bit functions are the same as for SCI1. BRR—Bit Rate Register H'FEF1 SCI2 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for SCI1. SCR—Serial Control Register Bit H'FEF2 SCI2 7 6 5 4 3 2 1 0 TIE RIE TE RE — — CKE1 CKE0 Initial value 0 0 0 0 1 1 0 0 Read/Write R/W R/W R/W R/W — — R/W R/W Note: Bit functions are the same as for SCI1. 425 TDR—Transmit Data Register H'FEF3 SCI2 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for SCI1. SSR—Serial Status Register Bit H'FEF4 7 6 5 4 3 TDRE RDRF ORER FER PER Initial value 0 0 0 0 Read/Write R/(W)* R/(W)* R/(W)* R/(W)* SCI2 2 1 0 0 1 1 1 R/(W)* — — — Note: Bit functions are the same as for SCI1. * Only writing of 0 to clear the flag is enabled. RDR—Receive Data Register H'FEF5 SCI2 Bit 7 6 5 4 3 2 1 0 Initial value 1 1 1 1 1 1 1 1 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for SCI1. 426 SYSCR1—System Control Register 1 Bit H'FEFC Port 1 7 6 5 4 3 2 1 0 — IRQ1E IRQ0E NMIEG BRLE — — — Initial value 1 0 0 0 0 1 1 1 Read/Write — R/W R/W R/W R/W — — — Bus Release Enable 0 P12 and P13 are I/O ports. 1 P12 is the BACK output pin and P13 is the BREQ input pin. Nonmaskable Interrupt Edge 0 An NMI request is generated on the falling edge of the NMI pin input. 1 An NMI request is generated on the rising edge of the NMI pin input. Interrupt Request 0 Enable 0 P15 is an I/O port; IRQ0 input is disabled. 1 P15 is the IRQ0 input pin. Interrupt Request 1 Enable 0 P16 is an I/O port; IRQ1 input is disabled. 1 P16 is the IRQ1 input pin. 427 SYSCR2—System Control Register 2 Bit H'FEFD 3 Port6, Port9 7 6 5 4 2 1 0 — IRQ5E IRQ5E IRQ5E Initial value 1 0 0 0 0 0 0 0 Read/Write — R/W R/W R/W R/W R/W R/W R/W IRQ5E P6PWME P9PWME P9SCI2E Port 9 SCI2 Enable 0 P92, P93, and P94 cannot be used for serial communication. 1 P92, P93, and P94 can be used for serial communication (see port 9 pin functions). Port 9 PWM Enable 0 P92, P93, and P94 cannot be used for PWM output. 1 P92, P93, and P94 can be used for PWM output (see port 9 pin functions). Port 6 PWM Enable 0 P61, P62, and P63 cannot be used for PWM output. 1 P61, P62, and P63 can be used for PWM output (see port 6 pin functions). 0 1 0 1 0 1 0 1 Interrupt Request 2 Enable P60 is not used for IRQ2 signal input. P60 is used for IRQ2 signal input. Interrupt Request 3 Enable P61 is not used for IRQ3 signal input. P61 is used for IRQ3 signal input. Interrupt Request 4 Enable P62 is not used for IRQ4 signal input. P62 is used for IRQ4 signal input. Interrupt Request 5 Enable P63 is not used for IRQ5 signal input. P63 is used for IRQ5 signal input. 428 P9DDR—Port 9 Data Direction Register Bit 7 6 5 H'FEFE 4 3 Port 9 2 1 0 P97DDR P96DDR P95DDR P94DDR P93DDR P92DDR P91DDR P90DDR Initial value 0 0 0 0 0 0 0 0 Read/Write W W W W W W W W Port 9 Input/Output Selection 0 Input port 1 Output port P9DR—Port 9 Data Register Bit H'FEFF Port 9 7 6 5 4 3 2 1 0 P97 P96 P95 P94 P93 P92 P91 P90 Initial value 0 0 0 0 0 0 0 0 Read/Write R/W R/W R/W R/W R/W R/W R/W R/W IPRA—Interrupt Priority Register A Bit 7 6 5 H'FF00 4 3 — INTC 2 1 0 — Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W IRQ0 interrupt priority level (0 to 7) IPRB—Interrupt Priority Register B Bit 7 6 5 IRQ1 interrupt priority level (0 to 7) H'FF01 4 — 3 INTC 2 1 0 — Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W IRQ2 and IRQ3 interrupt priority level (0 to 7) 429 IRQ4 and IRQ5 interrupt priority level (0 to 7) IPRC—Interrupt Priority Register C Bit 7 6 H'FF02 5 4 — 3 INTC 2 1 0 — Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W 16-Bit FRT2 interrupt priority level (0 to 7) 16-Bit FRT1 interrupt priority level (0 to 7) IPRD—Interrupt Priority Register D Bit 7 6 H'FF03 5 4 — 3 INTC 2 1 0 — Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W 16-Bit FRT3 interrupt priority level (0 to 7) IPRE—Interrupt Priority Register E Bit 7 6 8-Bit timer interrupt priority level (0 to 7) H'FF04 5 4 — 3 INTC 2 1 0 — Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W SCI1 interrupt priority level (0 to 7) 430 SCI2 interrupt priority level (0 to 7) IPRF—Interrupt Priority Register F Bit 7 6 H'FF05 5 4 INTC 3 — 2 1 0 — Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W A/D interrupt priority level (0 to 7) Unused DTEA—Data Transfer Enable Register A Bit 7 6 5 — — — Initial value 0 0 0 Read/Write R R/W R/W H'FF08 4 INTC 3 2 1 — — — 0 0 0 0 0 R/W R R/W R/W R/W IRQ0 0 Served by CPU 1 Served by DTC DTEB—Data Transfer Enable Register B Bit 7 6 5 — — Initial value 0 0 0 Read/Write R R/W R/W IRQ1 0 Served by CPU 1 Served by DTC H'FF09 4 INTC 3 2 — — 0 0 R/W R 1 0 0 0 0 R/W R/W R/W IRQ2 0 Served by CPU 1 Served by DTC IRQ3 0 Served by CPU 1 Served by DTC 431 0 IRQ4 0 Served by CPU 1 Served by DTC IRQ5 0 Served by CPU 1 Served by DTC DTEC—Data Transfer Enable Register C Bit 7 6 5 H'FF0A 4 — 3 INTC 2 1 0 — Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W (FRT2) (FRT1) ICI2 0 Served by CPU 1 Served by DTC OCIB2 0 Served by CPU 1 Served by DTC ICI1 0 Served by CPU 1 Served by DTC OCIA1 0 Served by CPU 1 Served by DTC OCIB1 0 Served by CPU 1 Served by DTC 432 OCIA2 0 Served by CPU 1 Served by DTC DTED—Data Transfer Enable Register D Bit 7 6 5 H'FF0B 4 — INTC 3 2 — — 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W (FRT3) (8-Bit timer) ICI3 0 Served by CPU 1 Served by DTC OCIA3 0 Served by CPU 1 Served by DTC OCIB3 0 Served by CPU 1 Served by DTC 433 CMIA 0 Served by CPU 1 Served by DTC CMIB 0 Served by CPU 1 Served by DTC DTEE—Data Transfer Enable Register E Bit 7 6 H'FF0C 5 — 4 3 — — INTC 2 1 0 Initial value 0 0 0 0 0 0 0 0 Read/Write R R/W R/W R/W R R/W R/W R/W (SCI1) (SCI2) RXI1 0 Served by CPU 1 Served by DTC RXI2 0 Served by CPU 1 Served by DTC TXI1 0 Served by CPU 1 Served by DTC TXI2 0 Served by CPU 1 Served by DTC DTEF—Data Transfer Enable Register F Bit 7 6 5 — — — Initial value 0 0 0 Read/Write R R/W R/W H'FF0D 4 INTC 3 2 1 0 — — — — 0 0 0 0 0 R/W R R/W R/W R/W (A/D converter) ADI 0 Served by CPU 1 Served by DTC 434 WCR—Wait-State Control Register Bit H'FF10 WSC 7 6 5 4 3 2 1 0 — — — — WMS1 WMS0 WC1 WC0 Initial value 1 1 1 1 0 0 1 1 Read/Write — — — — R/W R/W R/W R/W Wait Count 1 and 0 0 0 No wait states (TW) are inserted. 0 1 1 Wait states are inserted. 1 0 2 Wait states are inserted. 1 1 3 Wait state is inserted. Wait Mode Select 1 and 0 0 0 Programmable wait mode 0 1 No wait states are inserted, regardless of the wait count. 1 0 Pin wait mode 1 1 Pin auto-wait mode RAMCR—RAM Control Register Bit H'FF11 RAM 7 6 5 4 3 2 1 0 RAME — — — — — — — Initial value 1 1 1 1 1 1 1 1 Read/Write R/W — — — — — — — RAM Enable 0 On-chip RAM is disabled. 1 On-chip RAM is enabled. 435 MDCR—Mode Control Register Bit H'FF12 7 6 5 4 3 2 1 0 — — — — — MDS2 MDS1 MDS0 Initial value 1 1 0 0 0 —* —* —* Read/Write — — — — — R R R Mode Select Value input at mode pins * Initialized according to the inputs at pins MD2, MD1, and MD0. SBYCR—Software Standby Control Register Bit H'FF13 7 6 5 4 3 2 1 0 SSBY — — — — — — — Initial value 0 1 1 1 1 1 1 1 Read/Write R/W — — — — — — — Software Standby 0 SLEEP instruction causes transition to sleep mode. 1 SLEEP instruction causes transition to software standby mode. RSTCSR—Reset Status/Control Register Bit H'FF15 WDT 7 6 5 4 3 2 1 0 WRST RSTOE — — — — — — Initial value 0 0 1 1 1 1 1 1 Read/Write R/(W)* R/W — — — — — — Reset Output Enable 0 The reset signal is not output externally. 1 The reset signal is output externally. Watchdog Timer Reset 0 Cleared from 1 to 0 by software, or by a Low input at the RES pin. 1 Set to 1 when TCNT overflows and a reset signal is generated. * Software can write a 0 in bit 7 to clear the flag but cannot write a 1. 436 Appendix C I/O Port Schematic Diagrams C.1 Schematic Diagram of Port 1 Reset R Q D P10 DDR C WP1D Internal data bus (PDB8) Figure C-1 (a) to (g) gives a schematic view of the port 1 input/output circuits. WP1D: Write to P1DDR RP1: Read Port 1 ø P10 RP1 Figure C-1 (a) Schematic Diagram of Port 1, Pin P10 Table C-1 (a) Port 1 Port Read (Pin P10) Port Read Data Pin value ø Reset R Q D P11 DDR C WP1D Internal data bus (PDB9) Setting DDR = 0 DDR = 1 WP1D: Write to P1DDR RP1: Read Port 1 E P11 RP1 Figure C-1 (b) Schematic Diagram of Port 1, Pin P11 437 Table C-1 (b) Port 1 Port Read (Pin P11) Setting DDR = 0 DDR = 1 Port Read Data Pin value E WP1D: Write to P1DDR WP1: Write to Port 1 RP1: Read Port 1 Reset R D P12 DDR C WP1D Reset R Q P12 D P12 DR C Internal data bus (PDB10) Q WP1 Mode 1, 2, 3, or 4 System control register 1, bit 3 BRLE Q BACK RP1 Figure C-1 (c) Schematic Diagram of Port 1, Pin P12 Table C-1 (c) Port 1 Port Read (Pin P12) Mode 1, 2, 3, 4 7 Setting BRLE = 1 BRLE = 0 DDR = 0 DDR = 1 DDR = 0 DDR = 1 Port Read Data DR value Pin value DR value Pin value DR value 438 WP1D: Write to P1DDR WP1: Write to Port 1 RP1: Read Port 1 Reset R D P13 DDR C WP1D Reset R P13 Q D P13 DR C WP1 Mode 1, 2, 3, or 4 Internal data bus (PDB11) Q System control register 1, bit 3 BRLE Q RP1 BREQ to CPU Figure C-1 (d) Schematic Diagram of Port 1, Pin P13 Table C-1 (d) Port 1 Port Read (Pin P13) Mode 1, 2, 3, 4 7 Setting BRLE = 1 BRLE = 0 DDR = 0 DDR = 1 DDR = 0 DDR = 1 Port Read Data Pin value Pin value DR value Pin value DR value 439 WP1D: Write to P1DDR WP1: Write to Port 1 RP1: Read Port 1 Reset R D P14 DDR C WP1D Reset R P14 Q D P14 DR C WP1 Mode 1, 2, 3, or 4 Internal data bus (PDB12) Q Wait-state control register, bit 3 WMS1 Q RP1 WAIT to CPU Figure C-1 (e) Schematic Diagram of Port 1, Pin P14 Table C-1 (e) Port 1 Port Read (Pin P14) Mode 1, 2, 3, 4 7 Setting WMS 1 = 1 WMS 1 = 0 DDR = 0 DDR = 1 DDR = 0 DDR = 1 Fig. C-1 (d) Port Read Data Pin value Pin value DR value Pin value DR value 440 Reset WP1D: Write to P1DDR WP1: Write to Port 1 RP1: Read Port 1 R D P15 DDR C WP1D Reset R P15 Q D P15 DR C WP1 Internal data bus (PDB13) Q System control register 1, bit 5 IRQ 0 E Q RP1 IRQ0 to CPU Figure C-1 (f) Schematic Diagram of Port 1, Pin P15 Table C-1 (f) Port 1 Port Read (Pin P15) Setting IRQ0E = 1 IRQ0E = 0 Port Read Data Pin value DDR = 0 DDR = 1 Pin value DR value 441 Reset WP1D: Write to P1DDR WP1: Write to Port 1 RP1: Read Port 1 R D P16 DDR C WP1D Reset R P16 Q D P16 DR C WP1 Internal data bus (PDB14) Q System control register 1, bit 6 IRQ 0 E Q A/D control register, bit 7 TRGE RP1 Q IRQ1 to CPU Falling edge detector ADTRG to A/D converter Figure C-1 (g) Schematic Diagram of Port 1, Pin P16 Table C-1 (g) Port 1 Port Read (Pin P16) Setting TRGE or IRQ1E = 1 TRGE and IRQ1E = 0 DDR = 0 DDR = 1 Port Read Data Pin value Pin value DR value 442 WP1D: Write to P1DDR WP1: Write to Port 1 RP1: Read Port 1 Reset D P17 DDR C WP1D Reset R Q P17 D P17 DR C Internal data bus (PDB15) R Q WP1 8-Bit timer module Output enable 8-Bit timer output RP1 Figure C-1 (h) Schematic Diagram of Port 1, Pin P17 Fig. C-1 (g) Table C-1 (h) Port 1 Port Read (Pin P17) Setting 8-bit timer output enable 8-bit timer output disable DDR = 0 DDR = 1 Port Read Data 8-bit timer output value Pin value DR value 443 C.2 Schematic Diagram of Port 2 Figure C-2 gives a schematic view of the port 2 input/output circuits. Bus release Reset S Q R D P2 n DDR C WP2D Reset Mode 7 R Q P2n D P2 n DR C WP2 Mode 1, 2, 3, or 4 RP2 Bus control signals Figure C-2 Schematic Diagram of Port 2 Fig. C-2 Table C-2 Port 2 Port Read Mode 1, 2, 3, 4 7 DDR = 0 DDR = 1 Port Read Data DR value Pin value DR value 444 WP2D: WP2: RP2: n: Internal data bus (PDB8 to PDB11) Mode 1, 2, 3, or 4 Software standby Write to P2DDR Write to Port 2 Read Port 2 0, 1, 2, 3, or 4 C.3 Schematic Diagram of Port 3 Figure C-3 gives a schematic view of the port 3 input/output circuits. Data write WP3D: WP3: RP3: n: Mode 1, 2, 3, or 4 Reset R Q D Mode 7 WP3 Mode 1, 2, 3, or 4 Reset R P3n Q Mode 7 D P3 n DR C WP3D Mode 1, 2, 3, or 4 Internal data bus (PDB8 to PDB15) P3 n DDR C RP3 External address read Figure C-3 Schematic Diagram of Port 3 Table C-3 Port 3 Port Read Mode 1, 2, 3, 4 7 DDR = 0 DDR = 1 Port Read Data Always reads 1 Pin value DR value 445 Write to P3DDR Write to Port 3 Read Port 3 0 to 7 C.4 Schematic Diagram of Port 4 Figure C-4 gives a schematic view of the port 4 input/output circuits. Bus release R D P4 n DDR C WP4D Reset Mode 7 R Q P4n D P4 n DR C WP4 Mode 1, 2, 3, or 4 RP4 Figure C-4 Schematic Diagram of Port 4 Fig. C-4 Table C-4 Port 4 Port Read Mode 1, 2, 3, 4 7 DDR = 0 DDR = 1 Port Read Data DR value Pin value DR value 446 Internal data bus (PDB8 to PDB15) Reset S Q WP4D: WP4: RP4: n: Internal address bus (IAB0 to IAB7) Mode 1, 2, 3, or 4 Software standby Write to P4DDR Write to Port 4 Read Port 4 0 to 7 C.5 Schematic Diagram of Port 5 Figure C-5 gives a schematic view of the port 5 input/output circuits. Mode 1, 2, 3, or 4 Mode 1 or 3 Bus release S Q R D P5 n DDR C WP5D Reset Mode 7 R Q P5n D P5 n DR C WP5 Mode 1, 2, 3, or 4 RP5 Figure C-5 Schematic Diagram of Port 5 Fig. C-5 Table C-5 Port 5 Port Read Mode 1, 3 2, 4, 7 Port Read Data DR value DDR = 0 Pin value DDR = 1 DR value 447 Internal data bus (PDB8 to PDB15) Reset MOS pull-up WP5D: WP5: RP5: n: Internal address bus (IAB8 to IAB15) Software standby Write to P5DDR Write to Port 5 Read Port 5 0 to 7 C.6 Schematic Diagram of Port 6 Figure C-6 gives a schematic view of the port 6 input/output circuits. Mode 3 or 4 Reset S Q R D P6 0 DDR C WP6D Reset Mode 1, 2, or 7 R P60 Mode 4 Mode 3 Mode 3 or 4 Q D P6 0 DR C WP6 Internal address bus (IAB16) MOS pull-up WP6D: Write to P6DDR WP6: Write to Port 6 RP6: Read Port 6 Mode 3 Internal data bus (PDB8) Bus release Software standby System control register 2, Bit 3 IRQ2 E Q RP6 Falling edge detector IRQ2 to CPU Figure C-6 (a) Schematic Diagram of Port 6, Pin P60 Table C-6 (a) Port 6 Port Read (Pin P60) Mode 3 1, 2, 4, 7 IRQ2E = 0 IRQ2E = 1 DDR = 0 DDR = 1 Port Read Data DR value Pin value DR value Pin value 448 Mode 3 or 4 Reset S Q R D P6 n DDR C WP6D Reset Mode 3, 4 R Q P6n D P6 n DR C WP6 Mode 4 Internal address bus (IAB17 to IAB19) MOS pull-up Mode 3 Internal data bus (PDB9 to PDB11) Bus release Software standby WP6D: WP6: RP6: n: Write to P6DDR Write to Port 6 Read Port 6 1, 2, or 3 PWM timer module PWM1, PWM2, or PWM3 output enable PWM1, PWM2, or PWM3 output System control register 2 P6PWME Bit 2 RP6 Q IRQ3 E to Bit 6, 5, or 4 IRQ5 E Q Mode 3 Falling edge detector IRQ3 , IRQ 4 , IRQ 5 to CPU Figure C-6 (b) Schematic Diagram of Port 6, Pin P61 to P63 Table C-6 (b) Port 6 Port Read (Pin P61 to P63) Mode and Setting 3 4 DDR = 0 DDR = 1 1, 2, 7 IRQnE = 1 IRQnE = 0 Port Read Data DR value Pin value DR value Pin value P6PWME = 1 PWM output enable PWM output value Other than the DDR = 0 Pin value above settings DDR = 1 DR value 449 C.7 Schematic Diagram of Port 7 Figure C-7 (a) to (e) gives a schematic view of the port 7 input/output circuits. WP7D: Write to P7DDR WP7: Write to Port 7 RP7: Read Port 7 Reset R1 D P70 DDR C WP7D Reset R Q P70 D P70 DR C WP7 Internal data bus (PDB8) Q 8-Bit timer module RP7 Input clock Figure C-7 (a) Schematic Diagram of Port 7, Pin P70 Fig. C-7 (a) Table C-7 (a) Port 7 Port Read (Pin P70) Setting DDR = 0 DDR = 1 Port Read Data Pin value DR value 450 Reset D P7n DDR C WP7D Reset R Q P7n D P7n DR C WP7 Internal data bus (PDB9 to 10) R1 Q WP7D: WP7: RP7: n: Write to P7DDR Write to Port 7 Read Port 7 1 or 2 Free-running timer module Output enable Output Compare signal RP7 Counter clock output Figure C-7 (b) Schematic Diagram of Port 7, Pins P71 and P72 Table C-7 (b) Port 7 Port Read (Pins P71, P72) Setting DDR = 0 DDR = 1 Port Read Data Pin value DR value 451 WP7D: Write to P7DDR WP7: Write to Port 7 RP7: Read Port 7 Reset R1 D P73 DDR C WP7D Reset R Q P73 D P73 DR C WP7 Internal data bus (PDB11) Q RP7 8-Bit timer module Counter reset input Free-running timer module Input capture signal Figure C-7 (c) Schematic Diagram of Port 7, Pin P73 Fig. C-7 (c) Table C-7 (c) Port 7 Port Read (Pin P73) Setting DDR = 0 DDR = 1 Port Read Data Pin value DR value 452 R Q D P7n DDR C WP7D Reset R Q P7n D P7n DR C WP7 Internal data bus (PDB12 to PDB14) Reset WP7D: WP7: RP7: n: Write to P7DDR Write to Port 7 Read Port 7 4, 5 or 6 Free-running timer module RP7 Input capture signal Figure C-7 (d) Schematic Diagram of Port 7, Pins P74, P75 and P76 Table C-7 (d) Port 7 Port Read (Pins P74 to P76) Setting Output enable Output disable DDR = 0 DDR = 1 Port Read Data Output compare output value Pin value DR value 453 WP7D: Write to P7DDR WP7: Write to Port 7 RP7: Read Port 7 Reset R1 D P77 DDR C WP7D Reset R Q P77 D P77 DR C WP7 Internal data bus (PDB15) Q Free-running timer module Output enable Output compare output RP7 Figure C-7 (e) Schematic Diagram of Port 7, Pin P77 Fig. C-7 (e) Table C-7 (e) Port 7 Port Read (Pin P77) Setting Output enable Output disable DDR = 0 DDR = 1 Port Read Data Output compare output value Pin value DR value 454 C.8 Schematic Diagram of Port 8 Internal data bus (PDB8 to PDB15) Figure C-8 gives a schematic view of the port 8 input circuits. RP8 P8n RP8: Read Port 8 n: 0 to 7 A/D converter module Input multiplexer Figure C-8 Schematic Diagram of Port 8 Fig. C-8 455 C.9 Schematic Diagram of Port 9 Figure C-9 (a) to (g) gives a schematic view of the port 9 input/output circuits. R Q D P9 n DDR C WP9D Reset R Q P9n D P9 n DR C WP9 Internal data bus (PDB8, PDB9) Reset WP9D: WP9: RP9: n: Write to P9DDR Write to Port 9 Read Port 9 0 or 1 Free-running timer module Output enable Output compare output RP9 Figure C-9 (a) SchematicFig. Diagram of Port 9, Pins P90 and P91 C-9 (a) Table C-9 (a) Port 9 Port Read (Pins P90, P91) Setting Output enable Output disable DDR = 0 DDR = 1 Port Read Data Output compare output value Pin value DR value 456 Reset WP9D: Write to P9DDR WP9: Write to Port 9 RP9: Read Port 9 R D P9 2 DDR C WP9D Reset R Q P92 D P9 2 DR C WP9 Internal data bus (PDB10) Q PWM timer module PWM output enable PWM1 output Bit 1 System control register 2 P9PWME Q Bit 0 System control register 2 P9SCI2E Q RP9 SCI2 output enable Serial transmit data SCI2 module Figure C-9 (b) Schematic Diagram of Port 9, Pin P92 Table C-9 (b) Port 9 Port Read (Pin P92) Setting Port 9 SCI2 enable Port 9 SCI2 disable Port 9 SCI2 disable Port 9 SCI2 enable Port 9 PWM disable Port 9 PWM enalbe Port 9 PWM disable Port 9 PWM enable SCI2 output enable SCI2 output disable DDR = 0 DDR = 1 PWM output enable PWM output disable DDR = 0 DDR = 1 PWM and SCI2 DDR = 0 output either enabled DDR = 1 or disabled DDR = 0 DDR = 1 457 Port Read Data (Pin P92) Serial transmit data value Pin value DR value PWM1 output value Pin value DR value Pin value DR value Pin value DR value Reset WP9D: Write to P9DDR WP9: Write to Port 9 RP9: Read Port 9 R D P9 3 DDR C WP9D Reset R Q P93 D P9 3 DR C WP9 Internal data bus (PDB11) Q PWM timer module PWM output enable PWM2 output Bit 1 System control register 2 P9PWME Q Bit 0 System control register 2 P9SCI2E Q RP9 SCI2 input enable Serial receive data SCI2 module Figure C-9 (c) Schematic Diagram of Port 9, Pin P93 Table C-9 (c) Port 9 Port Read (Pin P93) Setting Port 9 SCI2 enable Port 9 SCI2 disable Port 9 SCI2 disable Port 9 SCI2 enable Port 9 PWM disable Port 9 PWM enalbe Port 9 PWM disable Port 9 PWM enable SCI2 input enable SCI2 input disable PWM output enable PWM output disable PWM and SCI2 input either enabled or disabled DDR = 0 DDR = 1 DDR = 0 DDR = 1 Port Read Data (Pin P93) Serial receive data value Pin value DR value PWM2 output value Pin value DR value Pin value DR value DDR = 0 DDR = 1 Pin value DR value DDR = 0 DDR = 1 458 Reset WP9D: Write to P9DDR WP9: Write to Port 9 RP9: Read Port 9 R D P9 4 DDR C WP9D Reset R Q P94 D P9 4 DR C WP9 Internal data bus (PDB12) Q PWM timer module PWM output enable PWM3 output Bit 1 System control register 2 P9PWME Q Bit 0 System control register 2 P9SCI2E Q RP9 Clock output enable Clock output Clock input enable Clock input SCI2 module Figure C-9 (d) Schematic Diagram of Port 9, Pin P94 Table C-9 (d) Port 9 Port Read (Pin P94) Setting Port 9 SCI2 enable Port 9 PWM disable Clock input enable Clock output enable Clock input and output disable Port 9 SCI2 enable Port 9 SCI2 disable Port 9 PWM enalbe Clock input, clock output, and PWM output enabled or disabled Port 9 SCI2 disable Port 9 PWM disable PWM output enable PWM output disable Clock input, clock output, and PWM output either enabled or disabled 459 DDR = 0 DDR = 1 DDR = 0 DDR = 1 Port Read Data (Pin P94) Input clock value Output clock value Pin value DR value Pin value DR value DDR = 0 DDR = 1 PWM3 output value Pin value DR value DDR = 0 DDR = 1 Pin value DR value Reset WP9D: Write to P9DDR WP9: Write to Port 9 RP9: Read Port 9 R D P9 5 DDR C WP9D Reset R Q P95 D P9 5 DR C WP9 Internal data bus (PDB13) Q SCI1 module Output enable Serial transfer data RP9 Figure C-9 (e) Schematic Diagram of Port 9, Pin P95 Table C-9 (e) Port 9 Port Read (Pin P95) Setting Output enable Output disable DDR = 0 DDR = 1 Port Read Data Serial transfer data Pin value DR value 460 Reset WP9D: Write to P9DDR WP9: Write to Port 9 RP9: Read Port 9 R D P96 DDR C WP9D P96 Reset R Q D P96 DR C Internal data bus (PDB14) Q WP9 SCI1 module RP9 Input enable Serial receive data Figure C-9 (f) Schematic Diagram of Port 9, Pin P96 Table C-9 (f) Port 9 Port Read (Pin P96) Setting Output enable Output disable DDR = 0 DDR = 1 Port Read Data Serial transfer data Pin value DR value 461 Reset WP9D: Write to P9DDR WP9: Write to Port 9 RP9: Read Port 9 R Q D P97 DDR C Reset R Q P97 D P97 DR C WP9 Internal data bus (PDB15) WP9D SCI1 module Clock input enable Clock output enable Clock output RP9 Clock input Figure C-9 (g) Schematic Diagram of Port 9, Pin P97 Table C-9 (g) Port 9 Port Read (Pin P97) Setting Clock input enable Clock output enable Clock input/output enable DDR = 0 DDR = 1 Port Read Data Input clock value Output clock value Pin value DR value 462 Appendix D Memory Maps Table D-1 H8/534 Memory Map Expanded Minimum Mode Mode 1 Mode 2 H'0000 Expanded Maximum Mode Mode 3 Mode 4 H'0000 Vector tables H'00000 Vector tables H'00FF H'0100 External memory H'00000 Vector tables H'00FF H'0100 H'F67F H'F680 External memory H'F67F H'F680 H'FE7F H'FE80 H'FFFF Page 0 On-chip ROM 32 kbytes H'0F67F H'0F680 H'FE7F H'FE80 Page 0 H'F680 On-chip RAM 2 kbytes H'0FE7F H'0FE80 On-chip RAM 2 kbytes H'0FE7F H'0FE80 Register field 384 bytes H'FE7F H'FE80 Register field 384 bytes H'0FFFF H'10000 Register field 384 bytes H'0FFFF H'10000 H'FFFF Page 1 Page 1 H'1FFFF H'1FFFF External memory External memory H'F0000 H'F0000 Page 15 H'FFFFF Page 0 H'0F67F H'0F680 On-chip RAM 2 kbytes Register field 384 bytes H'FFFF On-chip ROM 32 kbytes H'7FFF External memory Page 0 On-chip RAM 2 kbytes Register field 384 bytes H'00FF H'0100 H'07FFF H'08000 External memory On-chip RAM 2 kbytes Vector tables H'001FF H'00200 H'7FFF H'8000 Page 0 H'0000 Vector tables H'001FF H'00200 On-chip ROM 32 kbytes Single-Chip Mode Mode 7 Page 15 H'FFFFF Table D-2 H8/536 Memory Map Expanded Minimum Mode Mode 1 Mode 2 (Preliminary) H'0000 H'0000 H'00000 Vector tables Vector tables H'00FF H'0100 Expanded Maximum Mode Mode 3 Mode 4 H'EE7F Page 0 H'EE80 H'0000 Vector tables H'001FF H'00200 On-chip ROM 60 kbytes External memory H'00000 Vector tables H'00FF H'0100 Single-Chip Mode Mode 7 Vector tables H'001FF H'00200 External memory Page 0 H'00FF H'0100 On-chip ROM 62 kbytes Page 0 On-chip ROM 62 kbytes Page 0 Page 0 (Reserved)* H'F67F H'F680 On-chip RAM 2 kbytes On-chip RAM 2 kbytes H'FE7F H'FE80 H'0F67F H'0F680 On-chip RAM 2 kbytes Register field 384 bytes H'FFFF H'F67F H'F680 On-chip RAM 2 kbytes H'0FE7F H'0FE80 H'FE7F H'FE80 Register field 384 bytes H'FFFF H'0F67F H'0F680 H'F67F H'F680 H'0FE7F H'0FE80 Register field 384 bytes H'FE7F H'FE80 Register field 384 bytes H'0FFFF H'10000 Register field 384 bytes H'0FFFF H'10000 * : Reserved for future use as external address space H'FFFF Page 1 Page 1 H'1FFFF H'1FFFF External memory External memory H'F0000 H'F0000 Page 15 H'FFFFF On-chip RAM 2 kbytes Page 15 H'FFFFF Appendix E Pin States E.1 Port State of Each Pin State Table E-1 Port State Hardware Port Pin Name Mode Reset P17 to P12 1 Standby Software Bus Program Execution Mode Standby Mode Sleep Mode Release Mode State (Normal Operation) Input/output port or TMO, IRQ1, IRQ0 2 control signal Input/ keep*1 keep*3 keep*4 output 7 keep*2 keep —— Input/output port P11/E 1 (DDR = 1) (DDR = 1) (DDR = 1) (DDR = 1) P10/ø 2 Clock ø=H Clock output Clock output Clock output 3 output WAIT, BREQ, BACK P24 to P20 3 T T 4 E=L (DDR = 0) (DDR = 0) (DDR = 0) 4 T (DDR = 0) T T Input port 7 T —— 1 WR, RD, DS, 2 R/W, AS 3 WR, RD, DS, H T H T R/W, AS T keep keep —— Input/output port T T T D7 to D0 keep keep —— Input/output port T L T A7 to A0 4 7 P37 to P30 1 D7 to D0 2 3 T T 4 7 P47 to P40 1 A7 to A0 2 L 3 T 4 7 T keep keep —— Input/output port P57 to P50 1 L T L T A15 to A8 A15 to A8 2 T T*6 *5 T*6 Address bus or input port 3 L T L T A15 to A8 4 T T*6 *5 T*6 Address bus or input port keep keep —— 7 T Input/output port (Continued on next page) 465 Table E-1 Port State (cont) Hardware Port Pin Name Mode Reset P63 to P60 1 A19 to A16 2 T 3 L 4 T Standby Software Bus Mode Standby Mode Sleep Mode Release Mode State (Normal Operation) keep keep keep T L T A19 to A16 T*6 *5 T*6 Address bus or input port keep keep —— Input/output port T 7 P77 to P70 Program Execution Input/output port 1 2 3 T T keep*2 keep keep Input/output port T T T T T Input port T T keep*2 keep keep Input/output port 4 7 P87 to P80 1 2 3 4 7 P97 to P90 1 2 3 4 7 H: L: T: keep: High logic level Low logic level High-Impedance state Input ports are in the high-impedance state. Output ports hold their previous output values. If DDR = 0 and DR = 1 in ports 5 and 6, the MOS pull-ups remain on. *1 The on-chip supporting modules are reset, so P17 becomes an input or output port controlled by DDR and DR. If P12 is programmed for BACK output, it goes to the high-impedance state. *2 The on-chip supporting modules are reset, so these pins become input or output ports controlled by DDR and DR. *3 BREQ can be received. BACK is High. *4 BACK is Low. *5 Address outputs are Low. Input ports are in the high-impedance state, or the MOS pull-ups are on. *6 Pins used as input ports with the MOS pull-up on (DDR = 0, DR = 1) do not go to the highimpedance state. The MOS pull-up remains on. 466 Table E-2 MOS Pull-Up State Port P57 to P50 A15 to A8 P63 to P60 A19 to A16 Mode 1 2 3 4 7 1 2 3 4 7 Reset OFF Hardware Standby Mode OFF Other Operating States* OFF ON/OFF OFF ON/OFF OFF OFF ON/OFF OFF ON/OFF Notes OFF: The MOS pull-up is always OFF. ON/OFF: The MOS pull-up is on when DDR = 0 and DR = 1, and is off at other times. * Including software standby mode. 467 E.2 Pin States in Reset State 1. Mode 1 Figure E-1 shows how the pin states change when the RES pin goes Low during external memory access in mode 1. As soon as RES goes Low, all ports are initialized to the input (high-impedance) state. The AS, DS, RD, and WR signals all go High. The data bus (D7 to D0) is placed in the high-impedance state. The address bus and the R/W signal are initialized 1.5 ø clock periods after the Low state of the RES pin is sampled. All address bus signals are made Low. The R/W signal is made High. The clock output pins P10/ø and P11/E are initialized 0.5 ø clock periods after the Low state of the RES pin is sampled. Both pins are initialized to the output state. 468 External memory access T1 T2 T3 P10 / ø* RES Internal reset signal H’0000 A15 to A0 R/W AS, RD and DS (read) WR and DS (write) High impedance D7 to D0 (write) High impedance I/O ports * The dotted line indicates that P1 /ø is an input port if the corresponding DDR bit is 0, but a clock output pin if the DDR bit is 1. Figure E-1 Reset during Memory Access (Mode 1) 2. Mode 2 Figure E-4 shows how the pin states change when the RES pin goes Low during external memory access in mode 2. As soon as RES goes Low, all ports are initialized to the input (high-impedance) state. The AS, DS, RD, and WR signals all go High. The data bus (D7 to D0) is placed in the high-impedance state. Pins P57/A15 to P50/A8 of the address bus are initialized as input ports. 469 Pins A7 to A0 of the address bus and the R/W signal are initialized 1.5 ø clock periods after the Low state of the RES pin is sampled. Pins A7 to A0 are made Low. The R/W signal is made High. The clock output pins P10/ø and P11/E are initialized 0.5 ø clock periods after the Low state of the RES pin is sampled. Both pins are initialized to the output state. External memory access T1 T2 T3 P10 / ø* RES Internal reset signal H’00 A7 to A0 High impedance P57 /A15 to P5 0 /A 8 R/W AS, RD and DS (read) WR and DS (write) High impedance D7 to D0 (write) High impedance I/O ports * The dotted line indicates that P10 /ø is an input port if the corresponding DDR bit is 0, but a clock output pin if the DDR bit is 1. Figure E-2 Reset during Memory Access (Mode 2) 470 3. Mode 3 Figure E-4 shows how the pin states change when the RES pin goes Low during external memory access in mode 3. As soon as RES goes Low, all ports are initialized to the input (high-impedance) state. The AS, DS, RD, and WR signals all go High. The data bus (D7 to D0) is placed in the high-impedance state. The address bus and the R/W signal are initialized 1.5 ø clock periods after the Low state of the RES pin is sampled. All address bus signals are made Low. The R/W signal is made High. The clock output pins P10/ø and P11/E are initialized 0.5 ø clock periods after the Low state of the RES pin is sampled. Both pins are initialized to the output state. 471 External memory access T1 T2 P10 / ø* RES Internal reset signal A19 to A0 H’00000 R/W AS, RD and DS (read) WR and DS (write) High impedance D7 to D0 (write) High impedance I/O ports * The dotted line indicates that P10 /ø is an input port if the corresponding DDR bit is 0, but a clock output pin if the DDR bit is 1. Figure E-3 Reset during Memory Access (Mode 3) 4. Mode 4 Figure E-4 shows how the pin states change when the RES pin goes Low during external memory access in mode 4. As soon as RES goes Low, all ports are initialized to the input (high-impedance) state. The AS, DS, RD, and WR signals all go High. The data bus (D7 to D0) is placed in the high-impedance state. Pins P57/A15 to P50/A8 of the address bus and pins P63/A19 to P60/A16 of the page address bus are initialized as input ports. 472 Pins A7 to A0 of the address bus and the R/W signal are initialized 1.5 ø clock periods after the Low state of the RES pin is sampled. Pins A7 to A0 are made Low. The R/W signal is made High. The clock output pins P10/ø and P11/E are initialized 0.5 ø clock periods after the Low state of the RES pin is sampled. Both pins are initialized to the output state. T1 T2 T3 T1 P10 / ø* RES Internal reset signal H’00 A7 to A0 High impedance P63 /A19 to P6 0 /A16 and P57 /A15 to P5 0 /A8 R/W AS, RD and DS (read) WR and DS (write) High impedance D7 to D0 (write) High impedance I/O ports * The dotted line indicates that P10 /ø is an input port if the corresponding DDR bit is 0, but a clock output pin if the DDR bit is 1. Figure E-4 Reset during Memory Access (Mode 4) 473 5. Mode 7 Figure E-5 shows how the pin states change when the RES pin goes Low in mode 7. As soon as RES goes Low, all ports are initialized to the input (high-impedance) state. The clock output pins P10/ø and P11/E are initialized 0.5 ø clock periods after the Low state of the RES pin is sampled. Both pins are initialized to the output state. P10 / ø* P10 / E* RES Internal reset signal High impedance I/O ports * The dotted line indicates that P10 /ø and P10 /E are input ports if the corresponding DDR bit is 0, but clock output pins if the DDR bit is 1. Figure E-5 Reset during Memory Access (Mode 7) 474 Appendix F Timing of Transition to and Recovery from Hardware Standby Mode Timing of Transition to Hardware Standby Mode (1) To retain RAM contents when the RAME bit in RAMCR is set to 1, drive the RES signal line low 10 system clock cycles before the STBY signal, at a time when RAM is not being accessed. STBY t 1 ≥ 10 tcyc t 2 ≥ 0 ns RES (2) When the RAME bit in RAMCR is cleared to 0, or when it is not necessary to retain RAM contents, RES need not be driven low as in (1). Fig. p4 Timing of Exit from Hardware Standby Mode Drive the RES signal line low approximately 100 ns before the rise of the STBY signal. STBY t ≤ 100 ns t OSC RES 475 Fig. p437 Lower Appendix G Package Dimensions Figure G-1 shows the dimensions of the CP-84 package. Figure G-2 shows the dimensions of the CG-84 package. Figure G-3 shows the dimensions of the FP-80A package. 30.23 ± 0.12 29.28 74 54 53 84 1 11 0.42 ± 0.10 2.55 ± 0.15 0.75 4.40 ± 0.20 33 32 12 28.20 ± 0.50 1.27 28.20 ± 0.50 0.10 Figure G-1 Package Dimensions (CP-84) 29.21 ± 0.38 4.03 Max φd 12 32 33 11 0.635 30.23 ± 0.12 75 1 84 75 53 54 74 2.16 1.27 1.27 Figure G-2 Package Dimensions (CG-84) 476 17.2 ± 0.3 14.0 60 41 40 0.65 17.2 ±0.3 61 80 21 1 +0.08 –0.05 1.60 0.17 2.70 0.12 M +0.20 –0.16 0.30 ±0.10 3.05 Max 20 0.10 0–5° 0.10 0.80 ± 0.30 Figure G-3 Package Dimensions (FP-80A) 14.0 ± 0.2 12.0 60 41 40 80 21 0.50 14.0 ± 0.2 61 1 20 1.00 0.10 0.50 ± 0.10 0.17 ± 0.05 1.20 Max 0.10 M 0.00 Min 0.20 Max 0.20 ± 0.05 Figure G-4 Package Dimensions (TFP-80C) 477 0 – 5°