HD64F7045F28V - Renesas Electronics

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Old Company Name in Catalogs and Other Documents

On April 1st, 2010, NEC Electronics Corporation merged with Renesas Technology

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April 1st, 2010

Renesas Electronics Corporation

Issued by: Renesas Electronics Corporation (http://www.renesas.com)

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SH7040, SH7041, SH7042,

SH7043, SH7044, SH7045 Group

Hardware Manual

User’s Manual

Rev.6.00 2003.5

Renesas 32-Bit RISC Microcomputer

SuperH RISC engine Family/SH7040

Series

(CPU Core SH-2)

Renesas 32-Bit RISC Microcomputer

SuperH RISC engine Family/

SH7040 Series (CPU Core SH-2)

SH7040, SH7041, SH7042,

SH7043, SH7044, SH7045

Group

Hardware Manual

REJ09B0044-0600O

Cautions

Keep safety first in your circuit designs!

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Remember to give due consideration to safety when making your circuit designs, with appropriate measures such as (i) placement

of substitutive, auxiliary circuits, (ii) use of nonflammable material or (iii) prevention against any malfunction or mishap.

Notes regarding these materials

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Preface

The SH7040 Series (SH7040, SH7041, SH7042, SH7043, SH7044, SH7045) single-chip RISC

(Reduced Instruction Set Computer) microprocessors integrate a Renesas Technology-original

RISC CPU core with peripheral functions required for system configuration.

The CPU has a RISC-type instruction set. Most instructions can be executed in one clock cycle,

which greatly improves instruction execution speed. In addition, the 32-bit internal-bus

architecture enhances data processing power. With this CPU, it has become possible to assemble

low cost, high performance/high-functioning systems, even for applications that were previously

impossible with microprocessors, such as real-time control, which demands high speeds. In

particular, the SH7040 series has a 1-kbyte on-chip cache, which allows an improvement in CPU

performance during external memory access.

In addition, the SH7040 series includes on-chip peripheral functions necessary for system

configuration, such as large-capacity ROM and RAM, timers, a serial communication interface

(SCI), an A/D converter, an interrupt controller, and I/O ports. Memory or peripheral LSIs can be

connected efficiently with an external memory access support function. This greatly reduces

system cost.

There are versions of on-chip ROM: mask ROM, PROM, and flash memory. The flash memory

can be programmed with a programmer that supports SH7040 series programming, and can also

be programmed and erased by software.

This hardware manual describes the SH7040 series hardware. Refer to the programming manual

for a detailed description of the instruction set.

Related Manual

SH7040 series instructions

SH-1/SH-2/SH-DSP Programming Manual

Please consult your Renesas Technology sales representative for details for development

environment system.

List of Items Revised or Added for This Version

Section Page Description

1.1.1 SH7040 Series

Features

Notes on the

SH7040 Series

Specifications

Note: Package with Copper used as the lead material.

Type Abbreviation Package Frequency Voltage Type Name ROM

Mask

Version On-chip

ROM External

Bus Width Operating

Temp Electrical

Characteristics

A/D

Accuracy

(5Vversion)

Notes on the SH7040 Series Specifications

ZTAT SH7042 128 kB 16 bits ±15LSB

(High-Speed)

QFP2020-112 –20°C to 75°C 28 MHz

16 MHz 5 V

3.3 V HD6477042F28

HD6477042VF16 See “128 kB

PROM” See “Electrical

Characteristics”

FLASH SH7044F 256 kB 16 bits ±4LSB

(Mid-Speed)QFP2020-112 –20°C to 75°C 28 MHz 5 V HD64F7044F28 See “256 kB Flash

Memory” See “Electrical

Characteristics”

SH7042A A mask

A mask

MASK SH7040A 64 kB 16 bits ±4LSB

(Mid-Speed)QFP2020-112

TQFP1414-120

QFP2020-112Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6437040AF28

HD6437040AVF16

HD6437040AVX16

HD6437040ACF28

HD6437040AVCF16

See “64 kB Mask

ROM” See “Electrical

Characteristics”

A mask

ROM

less SH7040A 16 bits ±4LSB

(Mid-Speed)QFP2020-112

TQFP1414-120

QFP2020-112Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6417040AF28

HD6417040AVF16

HD6417040AVX16

HD6417040ACF28

HD6417040AVCF16

See “Electrical

Characteristics”

A mask

128 kB 16 bits ±4LSB

(Mid-Speed)QFP2020-112

TQFP1414-120

QFP2020-112Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6477042AF28

HD6477042AVF16

HD6477042AVX16

HD6477042ACF28

HD6477042AVCF16

See “128 kB

PROM” See “Electrical

Characteristics”

SH7043 128 kB 32 bits ±15LSB

(High-Speed)

QFP2020-144 –20°C to 75°C 28 MHz

16 MHz 5 V

3.3 V HD6477043F28

HD6477043VF16 See “128 kB

PROM” See “Electrical

Characteristics”

SH7043A A mask 128 kB 32 bits ±4LSB

(Mid-Speed)QFP2020-144

QFP2020-144Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6477043AF28

HD6477043AVF16

HD6477043ACF28

HD6477043AVCF16

See “128 kB

PROM” See “Electrical

Characteristics”

SH7045F A mask 256 kB 32 bits ±4LSB

(Mid-Speed)QFP2020-144 –20°C to 75°C 28 MHz 5 V HD64F7045F28 See “256 kB Flash

Memory” See “Electrical

Characteristics”

SH7041A A mask 64 kB 32 bits ±4LSB

(Mid-Speed)QFP2020-144

QFP2020-144Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6437041AF28

HD6437041AVF16

HD6437041ACF28

HD6437041AVCF16

See “64 kB Mask

ROM” See “Electrical

Characteristics”

SH7042A A mask 128 kB 16 bits ±4LSB

(Mid-Speed)QFP2020-112

TQFP1414-120

QFP2020-112Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6437042AF28

HD6437042AVF16

HD6437042AVX16

HD6437042ACF28

HD6437042AVCF16

See “128 kB Mask

ROM” See “Electrical

Characteristics”

SH7043A A mask 128 kB 32 bits ±4LSB

(Mid-Speed)QFP2020-144

QFP2020-144Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6437043AF28

HD6437043AVF16

HD6437043ACF28

HD6437043AVCF16

See “128 kB Mask

ROM” See “Electrical

Characteristics”

SH7044 A mask 256 kB 16 bits ±4LSB

(Mid-Speed)QFP2020-112 –20°C to 75°C 28 MHz 5 V HD6437044F28 See “256 kB Mask

ROM” See “Electrical

Characteristics”

SH7045 A mask 256 kB 32bits ±4LSB

(Mid-Speed)QFP2020-144 –20°C to 75°C 28 MHz 5 V HD6437045F28 See “256 kB Mask

ROM” See “Electrical

Characteristics”

SH7041A A mask 32 bits ±4LSB

(Mid-Speed)QFP2020-144

QFP2020-144Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6417041AF28

HD6417041AVF16

HD6417041ACF28

HD6417041AVCF16

See “Electrical

Characteristics”

SH7042 128 kB 16 bits ±15LSB

(High-Speed)

QFP2020-112 –20°C to 75°C 28 MHz

16 MHz 5 V

3.3 V HD6437042F28

HD6437042VF16 See “128 kB Mask

ROM” See “Electrical

Characteristics”

SH7043 128 kB 32 bits ±15LSB

(High-Speed)

QFP2020-144 –20°C to 75°C 28 MHz

16 MHz 5 V

3.3 V HD6437043F28

HD6437043VF16 See “128 kB Mask

ROM” See “Electrical

Characteristics”

1.4 The F-ZTAT

Version Onboard

Programming

Figure 1.6 Condition

Transfer for Flash

Memory

42 Note amended

Notes: For transferring between user mode and user program mode,

proceed while CPU is not programming or erasing the flash 

memory.

* RAM emulation permitted

2.4 Instruction Set

by Classification

Table 2.16 Branch

Instructions

70 Table amended

BF/S label 10001111dddddddd Delayed branch, if T = 0, disp × 2 +

PC → PC; if T = 1, nop 2/1*—

4.2.3 Notes on

Board Design —Deleted

4.5 Usage Notes 83 to

85 Newly added

11.1.4 Register

Configuration

Table 11.2 DMAC

Registers

218 Note *5 deleted

Section Page Description

11.2.3 DMA

Transfer Count

Registers 0–3

(DMATCR0–

DMATCR3)

220 Description amended

The data for the upper 8 bits of a DMATCR is 0 when read.

11.2.4 DMA

Channel Control

Registers 0–3

(CHCR0–CHCR3)

221 Description amended

• Bits 31–21—Reserved bits: Data are 0 when read. The write

value always be 0.

224 Description amended

• Bit 7—Reserved bits: Data is 0 when read. The write value

always be 0.

11.2.5 DMAC

Operation Register

(DMAOR)

226 Description amended

• Bits 15–10—Reserved bits: Data are 0 when read. The write

value always be 0.

227 Description amended

• Bits 7–3—Reserved bits: Data are 0 when read. The write

value always be 0.

11.3.3 Channel

Priority

Figure 11.3 Round

Robin Mode

233 Figure amended

Channel 0 is given the lowest

priority.

12.4.5 Cascade

Connection Mode

Figure 12.23

Cascade Connection

Operation Example

(Phase Counting

Mode)

337 Figure amended

TCLKC

TCLKD

12.4.9

Complementary

PWM Mode

Figure 12.55

Example of Output

Phase Switching by

External Input (1)

373 Figure amended

When BDC = 1, N = 0, P = 0, FB = 0, output active level = high

Section Page Description

12.9.2 Block

Diagram

Figure 12.125 POE

Block Diagram

444 Note added

TIOC3B*

TIOC3D*

TIOC4A*

TIOC4C*

TIOC4B*

TIOC4D*

Note: * Includes multiplexed pins.

12.11.5 Usage

Notes 453 Section added

14.2.8 Bit Rate

Table 14.3 Bit Rates

and BRR Settings in

Asynchronous Mode

(cont)

491 Table amended

Bit Rate 27.0336

(Bits/s) n N Error (%)

110 3 119 0.00

150 3 87 0.00

300 2 175 0.00

600 1 87 0.00

1200 1 175 0.00

2400 1 87 0.00

4800 0 175 0.00

9600 0 87 0.00

14400 0 58 –0.56

19200 0 43 0.00

28800 0 28 1.15

31250 0 26 0.12

38400 0 21 0.00

Table 14.4 Bit Rates

and BRR Settings in

Clocked

Synchronous Mode

(cont)

495 Table amended

3.5M —— —— 01

5M 0 0*—— ——

7M —— 00

14.3.4 Clock

Synchronous

Operation

Figure 14.22

Example of SCI

Receive Operation

529 Figure amended

Bit 7 Bit 0

RxI request

Section Page Description

15.4.9 A/D

Conversion Time

Table 15.8

Operating Frequency

and CKS Bit Settings

562 33 MHz deleted

15.6 Notes on Use

Figure 15.14

Example of a

Protection Circuit for

the Analog Input Pins

564 Figure amended

Notes: Numbers are only to be noted as reference value

*2 Rin: Input impedance

AVss

AVcc

AVref

AN0 to AN7

This LSI

10µF0.01µF

100Ω

Rin*2

0.1µF*1

16.7.2 Handling of

Analog Input Pins

Figure 16.8 Example

of Analog Input Pin

Protection Circuit

585 Note amended

Notes: Numbers are only to be noted as reference value

19.2 Port A

Table 19.2 Port A,

FP-144 Version

649 Table amended

PA16 (I/O)/AH (output) PA16 (I/O)/AH (output) PA16 (I/O)

PA15 (I/O)/CK (output) PA15 (I/O)/CK (output) PA15 (I/O)/CK (output)

21.2.2 Socket

Adapter Pin

Correspondence and

Memory Map

Figure 21.2 SH7042

Pin and HN27C101

Pin Correspondence

(112-Pin Version)

671 Figure amended

100 Ω

0.1 µF

Section Page Description

21.2.2 Socket

Adapter Pin

Correspondence and

Memory Map

Figure 21.3 SH7042

Pin and HN27C101

Pin Correspondence

(120-Pin Version)

672 Figure amended

2 nF

0.1 µF

100 Ω

Figure 21.4 SH7043

Pin and HN27C101

Pin Correspondence

(144-Pin Version)

673 Figure amended

100 Ω

0.1 µF

22.2.2 Mode

Transition Diagram

Figure 22.2 Flash

Memory Mode

Transitions

683 Note amended

Execute transition between the user mode and user program mode

while the CPU is not programming or erasing the flash memory

Section Page Description

22.7.2 Program-

Verify Mode

Figure 22.13

Program/Program

Verify Flow

706 Figure amended

Set SWE bit in FLMCR1

n = 1

m = 0

Write 32-byte data in reprogram data area

in RAM to flash memory consecutively

Start of programming

NG NG

*5*5

Store 32-byte program data in

reprogram data area *4

Read verify data

Clear SWE bit in FLMCR1

m = 1

End of programming

Program data = verify data?

End of 32-byte

data verification?

flag = 0?

Verify

Increment address

Programming failure

Clear SWE bit in FLMCR1

n ≥ 1000

n ← n + 1

Start

End of programming

Enable WDT

Disable WDT

Reprogram data computation

Transfer reprogram data to reprogram

data area

Wait 10 µs

Clear PV1(2) bit in FLMCR1(2)

Wait 4 µs

Dummy write of H'FF to verify address

Wait 2 µs

Set PV1(2) bit in FLMCR1(2)

Wait 4 µs

Clear PSU1(2) bit in FLMCR1(2)

Wait 10 µs

Clear P1(2) bit in FLMCR1(2)

Wait 10 µs

Set P1(2) bit in FLMCR1(2)

Wait 200 µs

Set PSU1(2) bit in FLMCR1(2)

Wait 50 µs

Note *5 added.

*5 Make sure to set the wait times and repetitions as specified.

Programming may not complete correctly if values other than

the specified ones are used.

Section Page Description

22.7.4 Erase-Verify

Mode

Figure 22.14

Erase/Erase-Verify

Flowchart

713 Figure amended

End of erasing

Start

Set SWE bit in FLMCR1

Set ESU1(2) bit in FLMCR1(2)

Set E1(2) bit in FLMCR1(2)

Wait 10 µs

Wait 200 µs

n = 1

Set EBR1(2)

Enable WDT

*5*5

Wait 5 ms

Wait 10 µs

Wait 20 µs

Set block start address to verify address

Wait 2 µs

Wait 5 µs

Start erase

Clear E1(2) bit in FLMCR1(2)

Clear ESU1(2) bit in FLMCR1(2)

Set EV1(2) bit in FLMCR1(2)

H'FF dummy write to verify address

Read verify data

Clear EV1(2) bit in FLMCR1(2)

Wait 5 µs

Clear EV1(2) bit in FLMCR1(2)

Clear SWE bit in FLMCR1

Disable WDT

Halt erase

Verify data = all "1"?

Last address of block?

End of

erasing of all erase

blocks?

Erase failure

Clear SWE bit in FLMCR1

n ≥ 60?

NG NG

OK OK

n ← n + 1

Increment

address

Notes: *1 Preprogramming (setting erase block data to all “0”) is not necessary.

*2 Verify data is read in 32-bit (longword) units.

*3 Set only one bit in EBR1(2). More than one bit cannot be set.

*4 Erasing is performed in block units. To erase a number of blocks, each block must be erased in turn.

*5 Make sure to set the wait times and repetitions as specified. Erasing may not complete correctly if values other

than the specified ones are used.

24.4.2 Canceling the

Standby Mode 747 Cancellation by a Manual Reset deleted

25. Electrical

Characteristics (5V,

33.3 MHz Version)

—Deleted

Section Page Description

25.2 DC

Characteristics

Table 25.2 DC

Characteristics

751 Note amended

*2 5 mA in the A mask version, except for F-ZTAT products.

25.3.2 Control

Signal Timing

Table 25.5 Control

Signal Timing

754 Note amended

Note: *The RES, MRES, NMI, BREQ, and IRQ7–IRQ0 signals are

asynchronous inputs, but when thesetup times shown here

are provided, the signals are considered to have produced

changes at clock rise (for RES, MRES, BREQ) or clock fall

(for NMI and IRQ7–IRQ0). If the setup times are not

provided, recognition is delayed until the next clock rise or

fall.

25.3.3 Bus Timing

Figure 25.12 DRAM

Cycle (Normal Mode,

1 Wait, TPC=0,

RCD=0)

763 Figure amended

Tcw1 Tc2

tCASD1

tCAC

tRAC

tAA tRDS

Column address

Figure 25.13 DRAM

Cycle (Normal Mode,

2 Waits, TPC=1,

RCD=1)

764 Figure amended

Tcw1 Tcw2

tCASD1

tCAC

tAA

Column address

Section Page Description

25.3.3 Bus Timing

Figure 25.14 DRAM

Cycle (Normal Mode,

3 Waits, TPC=1,

RCD=1)

764 Figure amended

Tcw1 Tcw2

tCASD1

tCAC tAA

Column

25.3.5 Multifunction

Timer Pulse Unit

Timing

Figure 25.23 MTU

I/O Timing

770 Figure amended

tTOCD

Figure 25.24 MTU

Clock Input Timing 770 Figure amended

tTCKS

25.3.11 Measuring

Conditions for AC

Characteristics

Figure 25.33 Output

Load Circuit

778 Title amended

Output Load Circuit

Section Page Description

25.4 A/D Converter

Characteristics

Table 25.16 A/D

Converter Timing (A

mask)

779 Table amended

Non-linearity error

Offset error*

Full scale error*

Quantize error*

26.2 DC

Characteristics

Table 26.2 DC

Characteristics

782 Table amended

Schmitt

trigger input

voltage

PA2, PA5, PA6–

PA9,

PE0–PE15

VT+ – VT–VCC×

0.07 —— VVT+ ≥ VCC× 0.9V (min)

VT– ≤ VCC× 0.2V (max)

783 Table amended

Analog

supply AICC —48 mA f = 16.7MHz

current AIref —0.5 1*3mA QFP144 version only

*3 2 mA in the A mask version of MASK products.

26.3.2 Control

Signal Timing

Table 26.5 Control

Signal Timing

786 Note amended

Notes: *1 SH7042/43 ZTAT (excluding A mask) are 3.2V.

*2 The RES, MRES, NMI, BREQ, and IRQ7–IRQ0 signals

are asynchronous inputs, but when the setup times

shown here are provided, the signals are considered to

have produced changes at clock rise (for RES, MRES,

BREQ) or clock fall (for NMI and IRQ7–IRQ0). If the

setup times are not provided, recognition is delayed until

the next clock rise or fall.

26.3.3 Bus Timing

Figure 26.12 DRAM

Cycle (Normal Mode,

1 Wait, TPC = 0,

RCD = 0)

795 Figure amended

Tcw1 Tc2

CASD1

CAC

RAC

RDS

Column address

Section Page Description

26.3.3 Bus Timing

Figure 26.13 DRAM

Cycle (Normal Mode,

2 Waits, TPC = 1,

RCD = 1)

796 Figure amended

Tcw1 Tcw2

tCASD1

tCAC

tAA

tRAC

tCASD1

Column address

Figure 26.14 DRAM

Cycle (Normal Mode,

3 Waits, TPC = 1,

RCD = 1)

796 Figure amended

Tcw1 Tcw2

tCASD1

tCAC tAA

tCASD1

Column address

tRAC

26.3.5 Multifunction

Timer Pulse Unit

Timing

Figure 26.23 MTU

I/O Timing

802 Figure amended

TOCD

Output

compare output

26.3.11

Measurement

Conditions for AC

Characteristics

Figure 26.33 Output

Load Circuit

810 Title amended

Output Load Circuit

Section Page Description

Appendix B Block

Diagrams

Figure B.19

PB4/IRQ2/POE2/

CASH,PB3/IRQ1/

POE1/CASL

Block Diagram

(F-ZTAT Version)

844 Note added

A17

Note: * Only when n = 4.

On-chip flash memory*

Appendix C Pin

States

Table C.1 Pin

Modes During Reset,

Power-Down, and

Bus Right Release

Modes (144 Pin)

865 Table amended

Pin modes

Pin Function Reset Power-Down Bus Right Standby in Bus

Class Pin Name Power-OnManual Standby Sleep Release Right Release

Clock CK O O H*1OO O

System RES IIIII I

control MRES Z*4IZII Z

WDTOVF O*3O*3OOO O

BREQ Z*4IZII I

BACK Z*4OZOL L

Interrupt NMI I I I I I I

IRQ0–IRQ7 Z*4IZII Z

IRQOUT (PD30) Z*4OH

*1HO H

IRQOUT (PE15) Z*4OZHO Z

Address

bus A0–A21 O*2OZOZ Z

Data bus D0–D31 Z*4I/O Z I/O Z Z

Bus WAIT Z*4IZIZ Z

control RD/WR, RAS Z*4OOOZ Z

CASH, CASL,

CASLH, CASLL Z*4OOOZ Z

RD HOZOZ Z

CS0, CS1 HOZOZ Z

CS2, CS3 Z*4OZOZ Z

WRHH, WRHL,

WRH, WRL HOZOZ Z

AH Z*4OZOZ Z

DMAC DACK0, DACK1

(PD26, PD27) Z*4OO

*1OO O

DACK0, DACK1

(PE14, PE15) Z*4OZOO Z

DRAK0, DRAK1 Z*4OO

*1OO O

DREQ0, DREQ1 Z*4IZII Z

Section Page Description

Appendix C Pin

States

Table C.1 Pin

Modes During Reset,

Power-Down, and

Bus Right Release

Modes (144 Pin)

(cont)

866 Table amended

Pin modes

Pin Function Reset Power-Down Bus Right Standby in Bus

Class Pin Name Power-OnManual Standby Sleep Release Right Release

MTU TIOC0A–TIOC0D,

TIOC1A–TIOC1D,

TIOC2A–TIOC2D,

TIOC3A, TIOC3C

Z*4I/O K*1I/O I/O K*1

TIOC3B,TIOC3D,

TIOC4A–TIOC4D Z*4I/O Z I/O I/O Z

TCLKA–TCLKD Z*4IZII Z

Port

control POE0–POE3 Z*4IZII Z

SCI SCK0–SCK1 Z*4I/O Z I/O I/O Z

TXD0–TCD1 Z*4OO

*1OO O

RXD0–RXD1 Z*4IZII Z

A/D ADTRG Z*4IZII Z

converter AN0–AN7 Z I Z I I Z

I/O Port PA0–PA23 Z*4I/O K*1K I/O K*1

PB0–PB9

PC0–PC15

PD0–PD31

PE0–PE8,PE10

PE9,PE11–PE15 Z*4I/O Z K I/O Z

PF0–PF17 Z I Z I I Z

Notes: 1. There are instances where bus right release and transition to software standby mode

occur simultaneously due to the timing between BREQ and internal operations. In such

cases, standby mode results, but the standby state may be different.

The initial pin states depend on the mode. See section 18, Pin Function Controller

(PFC), for details.

2. I: Input, O: Output, H: High-level output, L: Low-level output, Z: High impedance,

K: Input pin with high impedance, output pin mode maintained.

*1 If the standby control register port high-impedance bits are set to 1, output pins become

high impedance.

*2 A21–A18 will become input ports after power-on reset.

*3 Input in the SH7044/SH7045 F-ZTAT version.

*4 General use I/O ports PAn, PBn, PCn, PDn, and PEn, as well as pins multiplexed with

them, are unstable during the RES setup time (tRESS) immediately after the RES pin

goes to low level.

Section Page Description

Appendix C Pin

States

Table C.2 Pin

Modes During Reset,

Power-Down, and

Bus Right Release

Modes (112 Pin,

120 Pin)

867 Table amended

Pin modes

Pin Function Reset Power-Down Bus Right Standby in Bus

Class Pin Name Power-OnManual Standby Sleep Release Right Release

Clock CK O O H*1OO O

System RES IIIII I

control MRES Z*4IZII Z

WDTOVF O*3O*3OOO O

BREQ Z*4IZII I

BACK Z*4OZOL L

Interrupt NMI I I I I I I

IRQ0–IRQ7 Z*4IZII Z

IRQOUT Z*4OZHO Z

Address

bus A0–A21 O*2OZOZ Z

Data bus D0–D31 Z*4I/O Z I/O Z Z

Bus WAIT Z*4IZIZ Z

control RDWR, RAS Z*4OOOZ Z

CASH, CASL Z*4OOOZ Z

RD HOZOZ Z

CS0, CS1 HOZOZ Z

CS2, CS3 Z*4OZOZ Z

WRH, WRL HOZOZ Z

AH Z*4OZOZ Z

DMAC DACK0–DACK1 Z*4OZOO Z

DRAK0–DRAK1 Z*4OZOO Z

DREQ0–DREQ1 Z*4IZII Z

MTU TIOC0A–TIOC0D,

TIOC1A–TIOC1D,

TIOC2A–TIOC2D,

TIOC3A, TIOC3C

Z*4I/O K*1I/O I/O K*1

TIOC3B,TIOC3D,

TIOC4A–TIOC4D Z*4I/O Z I/O I/O Z

TCLKA–TCLKD Z*4IZII Z

Section Page Description

Appendix C Pin

States

Table C.2 Pin

Modes During Reset,

Power-Down, and

Bus Right Release

Modes (112 Pin,

120 Pin) (cont)

868 Table amended

Pin modes

Pin Function Reset Power-Down Bus Right Standby in Bus

Class Pin Name Power-OnManual Standby Sleep Release Right Release

Port

control POE0–POE3 Z*4IZII Z

SCI SCK0–SCK1 Z*4I/O Z I/O I/O Z

TXD0–TCD1 Z*4OO

*1OO O

RXD0–RXD1 Z*4IZII Z

A/D

converter ADTRG Z*4IZII Z

control AN0–AN7 Z I Z I I Z

I/O Port PA0–PA15 Z*4I/O K*1K I/O K*1

PB0–PB9

PC0–PC15

PD0–PD15

PE0–PE8–PE10

PE9,PE11–PE15 Z*4I/O Z K I/O Z

PF0–PF7 Z I Z I I Z

Notes: 1. There are instances where bus right release and transition to software standby mode

occur simultaneously due to the timing between BREQ and internal operations. In such

cases, standby mode results, but the standby state may be different.

The initial pin states depend on the mode. See section 18, Pin Function Controller

(PFC), for details.

2. I: Input, O: Output, H: High-level output, L: Low-level output, Z: High impedance,

K: Input pin with high impedance, output pin mode maintained.

*1 If the standby control register port high-impedance bits are set to 1, output pins become

high impedance.

*2A21–A18 will become input ports after power-on reset.

*3 Input in the SH7044/SH7045 F-ZTAT version.

*4 General use I/O ports PAn, PBn, PCn, PDn, and PEn, as well as pins multiplexed with

them, are unstable during the RES setup time (tRESS) immediately after the RES pin

goes to low level.

Section Page Description

Appendix E Product

Code Lineup

Table E.1 SH7040,

SH7041, SH7042,

SH7043, SH7044,

and SH7045 Product

Lineup

876,

877 Table amended

Product

Type

SH7040A Mask ROM

verion A MASK HD6437040AF28

HD6437040AVF16

HD6437040AVX16

HD6437040ACF28

HD6437040AVCF16



HD6437040A (***)F28

HD6437040A(***)VF16

HD6437040A(***)VX16

HD6437040A(***)CF28

HD6437040A(***)VCF16

QFP2020-112

TQFP1414-120

QFP2020-112Cu*1

QFP2020-112Cu*1

HD6437040A***F

HD6437040A***X

HD6437040A***CF

HD6437040A***CF

ROM less

verion A MASK HD6417040AF28

HD6417040AVF16

HD6417040AVX16

HD6417040ACF28

HD6417040AVCF16

HD6417040AF28

HD6417040AVF16

HD6417040AVX16

HD6417040ACF28

HD6417040AVCF16

QFP2020-112

TQFP1414-120

QFP2020-112Cu*1

QFP2020-112Cu*1

HD6417040AF28

HD6417040AVF16

HD6417040AVX16

HD6417040ACF28

HD6417040AVCF16

Mask

Version Product Code Mark Code Package Order Model No.*2

SH7041A Mask ROM

verion A MASK HD6437041AF28

HD6437041AVF16

HD6437041ACF28

HD6437041AVCF16

HD6437041A(***)F28

HD6437041A(***)VF16

HD6437041A(***)CF28

HD6437041A(***)VCF16

QFP2020-144

QFP2020-144Cu*1

QFP2020-144Cu*1

HD6437041A***F

HD6437041A***CF

HD6437041A***CF

SH7042 Mask ROM

verion – HD6437042F28

HD6437042VF16 HD6437042 (***)F28

HD6437042 (***)VF16 QFP2020-112

QFP2020-112 HD6437042***F

HD6437042***F

SH7042A Mask ROM

verion A MASK HD6437042AF28

HD6437042AVF16

HD6437042AVX16

HD6437042ACF28

HD6437042AVCF16

HD6437042A(***)F28

HD6437042A(***)VF16

HD6437042A(***)VX16

HD6437042A(***)CF28

HD6437042A(***)VCF16

QFP2020-112

TQFP1414-120

QFP2020-112Cu*1

QFP2020-112Cu*1

HD6437042A***F

HD6437042A***X

HD6437042A***CF

HD6437042A***CF

ROM less

verion A MASK HD6417041AF28

HD6417041AVF16

HD6417041ACF28

HD6417041AVCF16

HD6417041AF28

HD6417041AVF16

HD6417041ACF28

HD6417041AVCF16

QFP2020-144

QFP2020-144Cu*1

QFP2020-144Cu*1

HD6417041AF28

HD6417041AVF16

HD6417041ACF28

HD6417041AVCF16

Z-TAT

version – HD6477042F28

HD6477042VF16 HD6477042F28

HD6477042VF16 QFP2020-112

QFP2020-112 HD6477042F28

HD6477042VF16

Product

Type

SH7042A Z-TAT

version A MASK HD6477042AF28

HD6477042AVF16

HD6477042AVX16

HD6477042ACF28

HD6477042AVCF16

HD6477042AF28

HD6477042AVF16

HD6477042AVX16

HD6477042ACF28

HD6477042AVCF16

QFP2020-112

TQFP1414-120

QFP2020-112Cu*1

QFP2020-112Cu*1

HD6477042AF28

HD6477042AVF16

HD6477042AVX16

HD6477042ACF28

HD6477042AVCF16

Mask

Version Product Code Mark Code Package Order Model No.*2

SH7043 Mask ROM

version – HD6437043F28

HD6437043VF16 HD6437043(***)F28

HD6437043(***)VF16 QFP2020-144

QFP2020-144 HD6437043***F

HD6437043***F

SH7043A Mask ROM

version A MASK HD6437043AF28

HD6437043AVF16

HD6437043ACF28

HD6437043AVCF16

HD6437043A(***)F28

HD6437043A(***)VF16

HD6437043A(***)CF28

HD6437043A(***)VCF16

QFP2020-144

QFP2020-144Cu*1

QFP2020-144Cu*1

HD6437043A***F

HD6437043A***CF

HD6437043A***CF

SH7044 Mask ROM

version A MASK HD6437044F28 HD6437044(***)F28 QFP2020-112 HD6437044***F

F-ZTAT

version HD64F7044F28 HD64F7044F28 QFP2020-112 HD64F7044F28

Z-TAT

version – HD6477043F28

HD6477043VF16 HD6477043F28

HD6477043VF16 QFP2020-144

QFP2020-144 HD6477043F28

HD6477043VF16

Z-TAT

version A MASK HD6477043AF28

HD6477043AVF16

HD6477043ACF28

HD6477043AVCF16

HD6477043AF28

HD6477043AVF16

HD6477043ACF28

HD6477043AVCF16

QFP2020-144

QFP2020-144Cu*1

QFP2020-144Cu*1

HD6477043AF28

HD6477043AVF16

HD6477043ACF28

HD6477043AVCF16

SH7045 Mask ROM

version A MASK HD6437045F28 HD6437045(***)F28 QFP2020-144 HD6437045***F

F-ZTAT

version HD64F7045F28 HD64F7045F28 QFP2020-144 HD64F7045F28

(***) is the ROM code.

NoteS: 1. Package with Copper used as the lead material.

2. *** in the Order Model No. is the ROM code, consisting of a letter and a two-digit 

number (ex. E00). The letter indicates the voltage and frequency, as shown below.

 • E, F, G, H: 5.0 V, 28 MHz

 • P, Q, R: 3.3 V, 16 MHz

Contents

Section 1 SH7040 Series Overview............................................................................. 1

1.1 SH7040 Series Overview................................................................................................... 1

1.1.1 SH7040 Series Features........................................................................................ 1

1.2 Block Diagram................................................................................................................... 11

1.3 Pin Arrangement and Pin Functions.................................................................................. 13

1.3.1 Pin Arrangment..................................................................................................... 13

1.3.2 Pin Arrangement by Mode ................................................................................... 16

1.3.3 Pin Functions........................................................................................................ 37

1.4 The F-ZTAT Version Onboard Programming................................................................... 42

Section 2 CPU..................................................................................................................... 45

2.1 Register Configuration....................................................................................................... 45

2.1.1 General Registers (Rn) ......................................................................................... 45

2.1.2 Control Registers .................................................................................................. 46

2.1.3 System Registers................................................................................................... 47

2.1.4 Initial Values of Registers .................................................................................... 47

2.2 Data Formats...................................................................................................................... 48

2.2.1 Data Format in Registers ...................................................................................... 48

2.2.2 Data Format in Memory....................................................................................... 48

2.2.3 Immediate Data Format........................................................................................ 48

2.3 Instruction Features ........................................................................................................... 49

2.3.1 RISC-Type Instruction Set ................................................................................... 49

2.3.2 Addressing Modes ................................................................................................ 52

2.3.3 Instruction Format ................................................................................................ 56

2.4 Instruction Set by Classification........................................................................................ 59

2.5 Processing States ............................................................................................................... 72

2.5.1 State Transitions................................................................................................... 72

2.5.2 Power-Down State................................................................................................ 74

Section 3 Operating Modes............................................................................................. 77

3.1 Operating Modes, Types, and Selection............................................................................ 77

3.2 Explanation of Operating Modes....................................................................................... 78

3.3 Pin Configuration............................................................................................................... 79

Section 4 Clock Pulse Generator (CPG)..................................................................... 81

4.1 Overview............................................................................................................................ 81

4.1.1 Block Diagram...................................................................................................... 81

4.2 Oscillator............................................................................................................................ 81

4.2.1 Connecting a Crystal Oscillator............................................................................ 81

4.2.2 External Clock Input Method............................................................................... 82

4.3 Prescaler............................................................................................................................. 83

4.4 Oscillator Halt Function..................................................................................................... 83

4.5 Usage Notes....................................................................................................................... 83

4.5.1 Oscillator Usage Notes......................................................................................... 83

4.5.2 Notes on Board Design......................................................................................... 84

4.5.3 Spread Spectrum Clock Generator Usage Notes.................................................. 85

Section 5 Exception Processing..................................................................................... 87

5.1 Overview............................................................................................................................ 87

5.1.1 Types of Exception Processing and Priority......................................................... 87

5.1.2 Exception Processing Operations......................................................................... 88

5.1.3 Exception Processing Vector Table...................................................................... 89

5.2 Resets................................................................................................................................. 90

5.2.1 Power-On Reset.................................................................................................... 91

5.2.2 Manual Reset ........................................................................................................ 91

5.3 Address Errors ................................................................................................................... 92

5.3.1 Address Error Exception Processing .................................................................... 93

5.4 Interrupts............................................................................................................................ 93

5.4.1 Interrupt Priority Level......................................................................................... 94

5.4.2 Interrupt Exception Processing............................................................................. 94

5.5 Exceptions Triggered by Instructions................................................................................ 94

5.5.1 Trap Instructions................................................................................................... 95

5.5.2 Illegal Slot Instructions......................................................................................... 95

5.5.3 General Illegal Instructions................................................................................... 96

5.6 When Exception Sources Are Not Accepted..................................................................... 96

5.6.1 Immediately after a Delayed Branch Instruction.................................................. 96

5.6.2 Immediately after an Interrupt-Disabled Instruction............................................ 96

5.7 Stack Status after Exception Processing Ends................................................................... 97

5.8 Notes on Use...................................................................................................................... 98

5.8.1 Value of Stack Pointer (SP).................................................................................. 98

5.8.2 Value of Vector Base Register (VBR) ................................................................. 98

5.8.3 Address Errors Caused by Stacking of Address Error Exception Processing...... 98

Section 6 Interrupt Controller (INTC)......................................................................... 99

6.1 Overview............................................................................................................................ 99

6.1.1 Features................................................................................................................. 99

6.1.2 Block Diagram...................................................................................................... 99

6.1.3 Pin Configuration ................................................................................................. 101

6.1.4 Register Configuration ......................................................................................... 101

6.2 Interrupt Sources................................................................................................................ 102

6.2.1 NMI Interrupts...................................................................................................... 102

6.2.2 User Break Interrupt............................................................................................. 102

iii

6.2.3 IRQ Interrupts....................................................................................................... 102

6.2.4 On-Chip Peripheral Module Interrupts................................................................. 103

6.2.5 Interrupt Exception Vectors and Priority Rankings ............................................. 103

6.3 Description of Registers..................................................................................................... 108

6.3.1 Interrupt Priority Registers A–H (IPRA–IPRH)................................................... 108

6.3.2 Interrupt Control Register (ICR) .......................................................................... 109

6.3.3 IRQ Status Register (ISR) .................................................................................... 110

6.4 Interrupt Operation............................................................................................................. 112

6.4.1 Interrupt Sequence................................................................................................ 112

6.4.2 Stack after Interrupt Exception Processing........................................................... 114

6.5 Interrupt Response Time.................................................................................................... 114

6.6 Data Transfer with Interrupt Request Signals ................................................................... 116

6.6.1 Handling DTC Activating and CPU Interrupt Sources,

but Not DMAC Activating Sources ..................................................................... 117

6.6.2 Handling DMAC Activating Sources but Not CPU Interrupt

or DTC Activating Sources .................................................................................. 118

6.6.3 Handling DTC Activating Sources but Not CPU Interrupt

or DMAC Activating Sources .............................................................................. 118

6.6.4 Treating CPU Interrupt Sources but Not DTC

or DMAC Activating Sources .............................................................................. 118

Section 7 User Break Controller (UBC)..................................................................... 119

7.1 Overview............................................................................................................................ 119

7.1.1 Features................................................................................................................. 119

7.1.2 Block Diagram...................................................................................................... 119

7.1.3 Register Configuration ......................................................................................... 120

7.2 Register Descriptions......................................................................................................... 121

7.2.1 User Break Address Register (UBAR)................................................................. 121

7.2.2 User Break Address Mask Register (UBAMR) ................................................... 122

7.2.3 User Break Bus Cycle Register (UBBR).............................................................. 123

7.3 Operation ........................................................................................................................... 126

7.3.1 Flow of the User Break Operation ....................................................................... 126

7.3.2 Break on On-Chip Memory Instruction Fetch Cycle ........................................... 128

7.3.3 Program Counter (PC) Values Saved................................................................... 128

7.4 Use Examples..................................................................................................................... 128

7.4.1 Break on CPU Instruction Fetch Cycle ................................................................ 128

7.4.2 Break on CPU Data Access Cycle........................................................................ 129

7.4.3 Break on DMA/DTC Cycle.................................................................................. 130

7.5 Cautions on Use................................................................................................................. 130

7.5.1 On-Chip Memory Instruction Fetch..................................................................... 130

7.5.2 Instruction Fetch at Branches............................................................................... 130

7.5.3 Contention between User Break and Exception Handling................................... 131

7.5.4 Break at Non-Delay Branch Instruction Jump Destination.................................. 131

Section 8 Data Transfer Controller (DTC)................................................................. 133

8.1 Overview............................................................................................................................ 133

8.1.1 Features................................................................................................................. 133

8.1.2 Block Diagram...................................................................................................... 134

8.1.3 Register Configuration ......................................................................................... 135

8.2 Register Description .......................................................................................................... 135

8.2.1 DTC Mode Register (DTMR) .............................................................................. 135

8.2.2 DTC Source Address Register (DTSAR)............................................................. 138

8.2.3 DTC Destination Address Register (DTDAR)..................................................... 138

8.2.4 DTC Initial Address Register (DTIAR) ............................................................... 139

8.2.5 DTC Transfer Count Register A (DTCRA) ......................................................... 139

8.2.6 DTC Transfer Count Register B (DTCRB).......................................................... 140

8.2.7 DTC Enable Registers (DTER) ............................................................................ 140

8.2.8 DTC Control/Status Register (DTCSR)............................................................... 141

8.2.9 DTC Information Base Register (DTBR)............................................................. 143

8.3 Operation ........................................................................................................................... 143

8.3.1 Overview of Operation......................................................................................... 143

8.3.2 Activating Sources................................................................................................ 145

8.3.3 DTC Vector Table ................................................................................................ 145

8.3.4 Register Information Placement........................................................................... 148

8.3.5 Normal Mode........................................................................................................ 149

8.3.6 Repeat Mode......................................................................................................... 149

8.3.7 Block Transfer Mode............................................................................................ 150

8.3.8 Operation Timing ................................................................................................. 151

8.3.9 DTC Execution State Counts................................................................................ 151

8.3.10 DTC Usage Procedure.......................................................................................... 153

8.3.11 DTC Use Example................................................................................................ 153

8.4 Cautions on Use................................................................................................................. 154

Section 9 Cache Memory (CAC).................................................................................. 155

9.1 Overview............................................................................................................................ 155

9.1.1 Features................................................................................................................. 155

9.1.2 Block Diagram...................................................................................................... 156

9.1.3 Register Configuration ......................................................................................... 156

9.2 Register Explanation.......................................................................................................... 157

9.2.1 Cache Control Register (CCR)............................................................................. 157

9.3 Address Array and Data Array .......................................................................................... 158

9.3.1 Cache Address Array Read/Write Space.............................................................. 159

9.3.2 Cache Data Array Read/Write Space ................................................................... 159

9.4 Cautions on Use................................................................................................................. 160

9.4.1 Cache Initialization............................................................................................... 160

9.4.2 Forced Access to Address Array and Data Array................................................. 160

9.4.3 Cache Miss Penalty and Cache Fill Timing ......................................................... 160

9.4.4 Cache Hit after Cache Miss.................................................................................. 162

Section 10 Bus State Controller (BSC) ......................................................................... 163

10.1 Overview............................................................................................................................ 163

10.1.1 Features................................................................................................................. 163

10.1.2 Block Diagram...................................................................................................... 164

10.1.3 Pin Configuration ................................................................................................. 165

10.1.4 Register Configuration ......................................................................................... 166

10.1.5 Address Map......................................................................................................... 167

10.2 Description of Registers..................................................................................................... 169

10.2.1 Bus Control Register 1 (BCR1)............................................................................ 169

10.2.2 Bus Control Register 2 (BCR2)............................................................................ 172

10.2.3 Wait Control Register 1 (WCR1)......................................................................... 175

10.2.4 Wait Control Register 2 (WCR2)......................................................................... 177

10.2.5 DRAM Area Control Register (DCR).................................................................. 178

10.2.6 Refresh Timer Control/Status Register (RTCSR) ................................................ 181

10.2.7 Refresh Timer Counter (RTCNT) ........................................................................ 183

10.2.8 Refresh Time Constant Register (RTCOR).......................................................... 184

10.3 Accessing Ordinary Space................................................................................................. 185

10.3.1 Basic Timing......................................................................................................... 185

10.3.2 Wait State Control ................................................................................................ 186

10.3.3 CS Assert Period Extension.................................................................................. 188

10.4 DRAM Access................................................................................................................... 189

10.4.1 DRAM Direct Connection.................................................................................... 189

10.4.2 Basic Timing......................................................................................................... 190

10.4.3 Wait State Control ................................................................................................ 191

10.4.4 Burst Operation..................................................................................................... 195

10.4.5 Refresh Timing..................................................................................................... 197

10.5 Address/Data Multiplex I/O Space Access........................................................................ 199

10.5.1 Basic Timing......................................................................................................... 199

10.5.2 Wait State Control ................................................................................................ 200

10.5.3 CS Assertion Extension........................................................................................ 201

10.6 Waits between Access Cycles ........................................................................................... 201

10.6.1 Prevention of Data Bus Conflicts......................................................................... 201

10.6.2 Simplification of Bus Cycle Start Detection ........................................................ 203

10.7 Bus Arbitration................................................................................................................... 203

10.8 Memory Connection Examples ......................................................................................... 205

10.9 On-Chip Peripheral I/O Register Access........................................................................... 210

10.10 CPU Operation when Program is in External Memory..................................................... 211

Section 11 Direct Memory Access Controller (DMAC).......................................... 213

11.1 Overview............................................................................................................................ 213

11.1.1 Features................................................................................................................. 213

11.1.2 Block Diagram...................................................................................................... 215

11.1.3 Pin Configuration ................................................................................................. 216

11.1.4 Register Configuration ......................................................................................... 217

11.2 Register Descriptions......................................................................................................... 218

11.2.1 DMA Source Address Registers 0–3 (SAR0–SAR3)........................................... 218

11.2.2 DMA Destination Address Registers 0–3 (DAR0–DAR3).................................. 219

11.2.3 DMA Transfer Count Registers 0–3 (DMATCR0–DMATCR3)......................... 220

11.2.4 DMA Channel Control Registers 0–3 (CHCR0–CHCR3)................................... 221

11.2.5 DMAC Operation Register (DMAOR) ................................................................ 226

11.3 Operation ........................................................................................................................... 228

11.3.1 DMA Transfer Flow............................................................................................. 228

11.3.2 DMA Transfer Requests....................................................................................... 230

11.3.3 Channel Priority.................................................................................................... 232

11.3.4 DMA Transfer Types ........................................................................................... 235

11.3.5 Address Modes..................................................................................................... 235

11.3.6 Dual Address Mode.............................................................................................. 237

11.3.7 Bus Modes ............................................................................................................ 244

11.3.8 Relationship between Request Modes and Bus Modes by DMA Transfer

Category ............................................................................................................... 245

11.3.9 Bus Mode and Channel Priority Order................................................................. 246

11.3.10 Number of Bus Cycle States and DREQ Pin Sample Timing.............................. 246

11.3.11 Source Address Reload Function ......................................................................... 263

11.3.12 DMA Transfer Ending Conditions....................................................................... 264

11.3.13 DMAC Access from CPU .................................................................................... 265

11.4 Examples of Use ................................................................................................................ 265

11.4.1 Example of DMA Transfer between On-Chip SCI and External Memory .......... 265

11.4.2 Example of DMA Transfer between External RAM and External Device

with DACK........................................................................................................... 266

11.4.3 Example of DMA Transfer between A/D Converter and On-Chip Memory

(Address Reload On) (Excluding A Mask) .......................................................... 266

11.4.4 Example of DMA Transfer between A/D Converter and Internal Memory

(Address Reload On) (A Mask)............................................................................ 268

11.4.5 Example of DMA Transfer between External Memory and SCI1 Send Side

(Indirect Address On)........................................................................................... 270

11.5 Cautions on Use................................................................................................................. 272

Section 12 Multifunction Timer Pulse Unit (MTU).................................................. 273

12.1 Overview............................................................................................................................ 273

12.1.1 Features................................................................................................................. 273

12.1.2 Block Diagram...................................................................................................... 276

12.1.3 Pin Configuration ................................................................................................. 278

12.1.4 Register Configuration ......................................................................................... 280

12.2 MTU Register Descriptions............................................................................................... 283

vii

12.2.1 Timer Control Register (TCR) ............................................................................. 283

12.2.2 Timer Mode Register (TMDR)............................................................................. 288

12.2.3 Timer I/O Control Register (TIOR) ..................................................................... 290

12.2.4 Timer Interrupt Enable Register (TIER)............................................................... 306

12.2.5 Timer Status Register (TSR) ................................................................................ 309

12.2.6 Timer Counters (TCNT)....................................................................................... 312

12.2.7 Timer General Register (TGR)............................................................................. 313

12.2.8 Timer Start Register (TSTR) ................................................................................ 313

12.2.9 Timer Synchro Register (TSYR).......................................................................... 314

12.2.10 Timer Output Master Enable Register (TOER).................................................... 315

12.2.11 Timer Output Control Register (TOCR)............................................................... 317

12.2.12 Timer Gate Control Register (TGCR).................................................................. 318

12.2.13 Timer Subcounter (TCNTS)................................................................................. 320

12.2.14 Timer Dead Time Data Register (TDDR) ............................................................ 321

12.2.15 Timer Period Data Register (TCDR).................................................................... 321

12.2.16 Timer Period Buffer Register (TCBR)................................................................. 322

12.3 Bus Master Interface.......................................................................................................... 322

12.3.1 16-Bit Registers .................................................................................................... 322

12.3.2 8-Bit Registers ...................................................................................................... 323

12.4 Operation ........................................................................................................................... 324

12.4.1 Overview............................................................................................................... 324

12.4.2 Basic Functions..................................................................................................... 325

12.4.3 Synchronous Operation ........................................................................................ 330

12.4.4 Buffer Operation................................................................................................... 333

12.4.5 Cascade Connection Mode................................................................................... 336

12.4.6 PWM Mode .......................................................................................................... 337

12.4.7 Phase Counting Mode........................................................................................... 341

12.4.8 Reset-Synchronized PWM Mode......................................................................... 348

12.4.9 Complementary PWM Mode ............................................................................... 352

12.5 Interrupts............................................................................................................................ 377

12.5.1 Interrupt Sources and Priority Ranking................................................................ 377

12.5.2 DTC/DMAC Activation....................................................................................... 379

12.5.3 A/D Converter Activation..................................................................................... 379

12.6 Operation Timing............................................................................................................... 380

12.6.1 Input/Output Timing............................................................................................. 380

12.6.2 Interrupt Signal Timing ........................................................................................ 385

12.7 Notes and Precautions........................................................................................................ 389

12.7.1 Input Clock Limitations........................................................................................ 389

12.7.2 Note on Cycle Setting........................................................................................... 389

12.7.3 Contention between TCNT Write and Clear ........................................................ 390

12.7.4 Contention between TCNT Write and Increment................................................. 391

12.7.5 Contention between Buffer Register Write and Compare Match......................... 392

12.7.6 Contention between TGR Read and Input Capture.............................................. 394

viii

12.7.7 Contention between TGR Write and Input Capture............................................. 395

12.7.8 Contention between Buffer Register Write and Input Capture ............................ 396

12.7.9 Contention between TGR Write and Compare Match ......................................... 397

12.7.10 TCNT2 Write and Overflow/Underflow Contention in Cascade Connection ..... 397

12.7.11 Counter Value during Complementary PWM Mode Stop ................................... 399

12.7.12 Buffer Operation Setting in Complementary PWM Mode................................... 399

12.7.13 Reset Sync PWM Mode Buffer Operation and Compare Match Flag................. 400

12.7.14 Overflow Flags in Reset Sync PWM Mode ......................................................... 402

12.7.15 Notes on Compare Match Flags in Complementary PWM Mode ....................... 405

12.7.16 Contention between Overflow/Underflow and Counter Clearing........................ 407

12.7.17 Contention between TCNT Write and Overflow/Underflow............................... 408

12.7.18 Cautions on Transition from Normal Operation or PWM Mode 1

to Reset-Synchronous PWM Mode...................................................................... 409

12.7.19 Output Level in Complementary PWM Mode and Reset-Synchronous PWM

Mode..................................................................................................................... 409

12.7.20 Cautions on Using the Chopping Function in Complementary PWM Mode

or Reset Synchronous PWM Mode (A Mask Excluded)...................................... 409

12.7.21 Cautions on Carrying Out Buffer Operation of Channel 0 in PWM Mode

(A Mask Excluded)............................................................................................... 409

12.7.22 Cautions on Restarting with Sync Clear of Another Channel

in Complementary PWM Mode (A Mask Excluded)........................................... 410

12.8 MTU Output Pin Initialization........................................................................................... 411

12.8.1 Operating Modes .................................................................................................. 411

12.8.2 Reset Start Operation............................................................................................ 411

12.8.3 Operation in Case of Re-Setting Due to Error During Operation, Etc................. 412

12.8.4 Overview of Initialization Procedures and Mode Transitions in Case of Error

during Operation, Etc............................................................................................ 412

12.9 Port Output Enable (POE) ................................................................................................. 443

12.9.1 Features................................................................................................................. 443

12.9.2 Block Diagram...................................................................................................... 444

12.9.3 Pin Configuration ................................................................................................. 445

12.9.4 Register Configuration.......................................................................................... 445

12.10 POE Register Descriptions ................................................................................................ 446

12.10.1 Input Level Control/Status Register (ICSR)......................................................... 446

12.10.2 Output Level Control/Status Register (OCSR)..................................................... 449

12.11 Operation ........................................................................................................................... 451

12.11.1 Input Level Detection Operation .......................................................................... 451

12.11.2 Output-Level Compare Operation........................................................................ 452

12.11.3 Release from High-Impedance State .................................................................... 452

12.11.4 POE timing........................................................................................................... 453

12.11.5 Usage Notes.......................................................................................................... 453

Section 13 Watchdog Timer (WDT) .............................................................................. 455

13.1 Overview............................................................................................................................ 455

13.1.1 Features................................................................................................................. 455

13.1.2 Block Diagram...................................................................................................... 456

13.1.3 Pin Configuration ................................................................................................. 456

13.1.4 Register Configuration ......................................................................................... 457

13.2 Register Descriptions......................................................................................................... 457

13.2.1 Timer Counter (TCNT)......................................................................................... 457

13.2.2 Timer Control/Status Register (TCSR) ................................................................ 458

13.2.3 Reset Control/Status Register (RSTCSR) ............................................................ 460

13.2.4 Register Access..................................................................................................... 461

13.3 Operation ........................................................................................................................... 462

13.3.1 Watchdog Timer Mode......................................................................................... 462

13.3.2 Interval Timer Mode............................................................................................. 464

13.3.3 Clearing the Standby Mode .................................................................................. 464

13.3.4 Timing of Setting the Overflow Flag (OVF)........................................................ 465

13.3.5 Timing of Setting the Watchdog Timer Overflow Flag (WOVF)........................ 465

13.4 Notes on Use...................................................................................................................... 466

13.4.1 TCNT Write and Increment Contention............................................................... 466

13.4.2 Changing CKS2–CKS0 Bit Values ...................................................................... 466

13.4.3 Changing between Watchdog Timer/Interval Timer Modes................................ 466

13.4.4 System Reset With WDTOVF ............................................................................. 467

13.4.5 Internal Reset with the Watchdog Timer.............................................................. 467

Section 14 Serial Communication Interface (SCI)..................................................... 469

14.1 Overview............................................................................................................................ 469

14.1.1 Features................................................................................................................. 469

14.1.2 Block Diagram...................................................................................................... 470

14.1.3 Pin Configuration ................................................................................................. 471

14.1.4 Register Configuration ......................................................................................... 471

14.2 Register Descriptions......................................................................................................... 472

14.2.1 Receive Shift Register (RSR)............................................................................... 472

14.2.2 Receive Data Register (RDR)............................................................................... 472

14.2.3 Transmit Shift Register (TSR).............................................................................. 472

14.2.4 Transmit Data Register (TDR) ............................................................................ 473

14.2.5 Serial Mode Register (SMR) ................................................................................ 473

14.2.6 Serial Control Register (SCR) .............................................................................. 476

14.2.7 Serial Status Register (SSR)................................................................................. 479

14.2.8 Bit Rate Register (BRR)....................................................................................... 483

14.3 Operation ........................................................................................................................... 501

14.3.1 Overview............................................................................................................... 501

14.3.2 Operation in Asynchronous Mode........................................................................ 503

14.3.3 Multiprocessor Communication........................................................................... 513

14.3.4 Clock Synchronous Operation.............................................................................. 521

14.4 SCI Interrupt Sources and the DMAC/DTC...................................................................... 532

14.5 Notes on Use...................................................................................................................... 533

14.5.1 TDR Write and TDRE Flags ................................................................................ 533

14.5.2 Simultaneous Multiple Receive Errors................................................................. 533

14.5.3 Break Detection and Processing........................................................................... 534

14.5.4 Sending a Break Signal......................................................................................... 534

14.5.5 Receive Error Flags and Transmitter Operation (Clock Synchronous Mode

Only)..................................................................................................................... 534

14.5.6 Receive Data Sampling Timing and Receive Margin in the Asynchronous

Mode..................................................................................................................... 534

14.5.7 Constraints on DMAC/DTC Use.......................................................................... 536

14.5.8 Cautions for Clock Synchronous External Clock Mode....................................... 536

14.5.9 Caution for Clock Synchronous Internal Clock Mode......................................... 536

Section 15 High Speed A/D Converter (Excluding A Mask)................................. 537

15.1 Overview............................................................................................................................ 537

15.1.1 Features................................................................................................................. 537

15.1.2 Block Diagram...................................................................................................... 538

15.1.3 Pin Configuration ................................................................................................. 538

15.1.4 Register Configuration ......................................................................................... 539

15.2 Register Descriptions......................................................................................................... 540

15.2.1 A/D Data Registers A–H (ADDRA–ADDRH).................................................... 540

15.2.2 A/D Control/Status Register (ADCSR)................................................................ 541

15.2.3 A/D Control Register (ADCR)............................................................................. 544

15.3 Bus Master Interface.......................................................................................................... 545

15.4 Operation ........................................................................................................................... 548

15.4.1 Select-Single Mode............................................................................................... 548

15.4.2 Select-Scan Mode................................................................................................. 549

15.4.3 Group-Single Mode .............................................................................................. 550

15.4.4 Group-Scan Mode................................................................................................. 551

15.4.5 Buffer Operation................................................................................................... 552

15.4.6 Simultaneous Sampling Operation....................................................................... 555

15.4.7 Conversion Start Modes ....................................................................................... 557

15.4.8 Conversion Start by External Input ...................................................................... 560

15.4.9 A/D Conversion Time........................................................................................... 561

15.5 Interrupts............................................................................................................................ 562

15.6 Notes on Use...................................................................................................................... 563

Section 16 Mid-Speed A/D Converter (A Mask)....................................................... 567

16.1 Overview............................................................................................................................ 567

16.1.1 Features................................................................................................................. 567

16.1.2 Block Diagram...................................................................................................... 568

16.1.3 Pin Configuration ................................................................................................. 569

16.1.4 Register Configuration ......................................................................................... 570

16.2 Register Descriptions......................................................................................................... 571

16.2.1 A/D Data Register A–D (ADDRA0–ADDRD0, ADDRA1–ADDRD1) ............ 571

16.2.2 A/D Control/Status Register (ADCSR0, ADCSR1)............................................. 572

16.2.3 A/D Control Register (ADCR0, ADCR1)............................................................ 574

16.3 Interface with CPU ............................................................................................................ 575

16.4 Operation ........................................................................................................................... 576

16.4.1 Single Mode (SCAN=0)....................................................................................... 576

16.4.2 Scan Mode (SCAN=1) ......................................................................................... 578

16.4.3 Input Sampling and A/D Conversion Time.......................................................... 580

16.4.4 External Trigger Input Timing ............................................................................. 581

16.5 Interrupt and DMA, DTC Transfer Requests.................................................................... 582

16.6 A/D Conversion Precision Definitions .............................................................................. 583

16.7 Usage Notes....................................................................................................................... 584

16.7.1 Analog Voltage Settings....................................................................................... 584

16.7.2 Handling of Analog Input Pins............................................................................. 584

Section 17 Compare Match Timer (CMT)................................................................... 587

17.1 Overview............................................................................................................................ 587

17.1.1 Features................................................................................................................. 587

17.1.2 Block Diagram...................................................................................................... 587

17.1.3 Register Configuration ......................................................................................... 589

17.2 Register Descriptions......................................................................................................... 590

17.2.1 Compare Match Timer Start Register (CMSTR) ................................................. 590

17.2.2 Compare Match Timer Control/Status Register (CMCSR).................................. 591

17.2.3 Compare Match Timer Counter (CMCNT).......................................................... 592

17.2.4 Compare Match Timer Constant Register (CMCOR).......................................... 593

17.3 Operation ........................................................................................................................... 593

17.3.1 Period Count Operation........................................................................................ 593

17.3.2 CMCNT Count Timing......................................................................................... 594

17.4 Interrupts............................................................................................................................ 594

17.4.1 Interrupt Sources and DTC Activation................................................................. 594

17.4.2 Compare Match Flag Set Timing ......................................................................... 594

17.4.3 Compare Match Flag Clear Timing...................................................................... 595

17.5 Notes on Use...................................................................................................................... 596

17.5.1 Contention between CMCNT Write and Compare Match................................... 596

17.5.2 Contention between CMCNT Word Write and Incrementation........................... 597

17.5.3 Contention between CMCNT Byte Write and Incrementation ............................ 598

Section 18 Pin Function Controller................................................................................. 599

18.1 Overview............................................................................................................................ 599

18.2 Register Configuration....................................................................................................... 607

18.3 Register Descriptions......................................................................................................... 608

xii

18.3.1 Port A I/O Register H (PAIORH)......................................................................... 608

18.3.2 Port A I/O Register L (PAIORL) ......................................................................... 609

18.3.3 Port A Control Register H (PACRH)................................................................... 609

18.3.4 Port A Control Registers L1, L2 (PACRL1 and PACRL2) ................................. 612

18.3.5 Port B I/O Register (PBIOR)................................................................................ 617

18.3.6 Port B Control Registers (PBCR1 and PBCR2)................................................... 618

18.3.7 Port C I/O Register (PCIOR)................................................................................ 622

18.3.8 Port C Control Register (PCCR)........................................................................... 623

18.3.9 Port D I/O Register H (PDIORH)......................................................................... 626

18.3.10 Port D I/O Register L (PDIORL) ......................................................................... 627

18.3.11 Port D Control Registers H1, H2 (PDCRH1 and PDCRH2)................................ 627

18.3.12 Port D Control Register L (PDCRL) .................................................................... 634

18.3.13 Port E I/O Register (PEIOR) ................................................................................ 638

18.3.14 Port E Control Registers 1, 2 (PECR1 and PECR2)............................................. 638

18.3.15 IRQOUT Function Control Register (IFCR)........................................................ 643

18.4 Cautions on Use................................................................................................................. 645

Section 19 I/O Ports (I/O).................................................................................................. 647

19.1 Overview............................................................................................................................ 647

19.2 Port A................................................................................................................................. 647

19.2.1 Register Configuration ......................................................................................... 650

19.2.2 Port A Data Register H (PADRH)........................................................................ 650

19.2.3 Port A Data Register L (PADRL)......................................................................... 651

19.3 Port B................................................................................................................................. 652

19.3.1 Register Configuration ......................................................................................... 652

19.3.2 Port B Data Register (PBDR)............................................................................... 653

19.4 Port C................................................................................................................................. 654

19.4.1 Register Configuration ......................................................................................... 654

19.4.2 Port C Data Register (PCDR)............................................................................... 655

19.5 Port D................................................................................................................................. 656

19.5.1 Register Configuration ......................................................................................... 658

19.5.2 Port D Data Register H (PDDRH)........................................................................ 659

19.5.3 Port D Data Register L (PDDRL)......................................................................... 660

19.6 Port E ................................................................................................................................. 661

19.6.1 Register Configuration ......................................................................................... 661

19.6.2 Port E Data Register (PEDR) ............................................................................... 662

19.7 Port F ................................................................................................................................. 663

19.7.1 Register Configuration ......................................................................................... 663

19.7.2 Port F Data Register (PFDR)................................................................................ 663

Section 20 64/128/256kB Mask ROM........................................................................... 665

20.1 Overview............................................................................................................................ 665

xiii

Section 21 128kB PROM................................................................................................... 669

21.1 Overview............................................................................................................................ 669

21.2 PROM Mode...................................................................................................................... 670

21.2.1 PROM Mode Settings........................................................................................... 670

21.2.2 Socket Adapter Pin Correspondence and Memory Map ...................................... 670

21.3 PROM Programming......................................................................................................... 674

21.3.1 Programming Mode Selection.............................................................................. 674

21.3.2 Write/Verify and Electrical Characteristics.......................................................... 675

21.3.3 Cautions on Writing ............................................................................................. 679

21.3.4 Post-Write Reliability........................................................................................... 680

Section 22 256kB Flash Memory (F-ZTAT)............................................................... 681

22.1 Features.............................................................................................................................. 681

22.2 Overview............................................................................................................................ 682

22.2.1 Block Diagram...................................................................................................... 682

22.2.2 Mode Transition Diagram..................................................................................... 683

22.2.3 Onboard Program Mode....................................................................................... 684

22.2.4 Flash Memory Emulation in RAM....................................................................... 686

22.2.5 Differences between Boot Mode and User Program Mode.................................. 687

22.2.6 Block Configuration............................................................................................. 688

22.3 Pin Configuration............................................................................................................... 689

22.4 Register Configuration....................................................................................................... 689

22.5 Description of Registers..................................................................................................... 690

22.5.1 Flash Memory Control Register 1 (FLMCR1)..................................................... 690

22.5.2 Flash Memory Control Register 2 (FLMCR2)..................................................... 692

22.5.3 Erase Block Register 1 (EBR1)............................................................................ 695

22.5.4 Erase Block Register 2 (EBR2)............................................................................ 695

22.5.5 RAM Emulation Register (RAMER)................................................................... 696

22.6 On-Board Programming Mode .......................................................................................... 698

22.6.1 Boot Mode ............................................................................................................ 699

22.6.2 User Program Mode ............................................................................................. 703

22.7 Programming/Erasing Flash Memory................................................................................ 704

22.7.1 Program Mode (n = 1 for Addresses H'0000–H'1FFFF,

n = 2 for Addresses H'20000–H'3FFFF)............................................................... 704

22.7.2 Program-Verify Mode (n = 1 for Addresses H'0000–H'1FFFF,

n = 2 for Addresses H'20000–H'3FFFF)............................................................... 705

22.7.3 Erase Mode (n = 1 for Addresses H'0000–H'1FFFF,

n = 2 for Addresses H'20000–H'3FFFF)............................................................... 711

22.7.4 Erase-Verify Mode (n = 1 for Addresses H'00000–H'1FFFF,

n = 2 for Addresses H'20000–H'3FFFF)............................................................... 712

22.8 Protection........................................................................................................................... 718

22.8.1 Hardware Protection............................................................................................. 718

22.8.2 Software Protection .............................................................................................. 719

xiv

22.8.3 Error Protection .................................................................................................... 720

22.9 Flash Memory Emulation in RAM .................................................................................... 722

22.10 Note on Flash Memory Programming/Erasing.................................................................. 724

22.11 Flash Memory Programmer Mode..................................................................................... 724

22.11.1 Socket Adapter Pin Correspondence Diagrams ................................................... 725

22.11.2 Programmer Mode Operation............................................................................... 728

22.11.3 Memory Read Mode............................................................................................. 729

22.11.4 Auto-Program Mode............................................................................................. 733

22.11.5 Auto-Erase Mode.................................................................................................. 735

22.11.6 Status Read Mode................................................................................................. 736

22.11.7 Status Polling........................................................................................................ 737

22.11.8 Programmer Mode Transition Time..................................................................... 738

22.11.9 Cautions Concerning Memory Programming....................................................... 739

Section 23 RAM................................................................................................................... 741

23.1 Overview............................................................................................................................ 741

23.2 Operation ........................................................................................................................... 741

Section 24 Power-Down State.......................................................................................... 743

24.1 Overview............................................................................................................................ 743

24.1.1 Power-Down States .............................................................................................. 743

24.1.2 Related Register.................................................................................................... 744

24.2 Standby Control Register (SBYCR).................................................................................. 744

24.3 Sleep Mode ........................................................................................................................ 745

24.3.1 Transition to Sleep Mode ..................................................................................... 745

24.3.2 Canceling Sleep Mode.......................................................................................... 745

24.4 Standby Mode.................................................................................................................... 745

24.4.1 Transition to Standby Mode................................................................................. 745

24.4.2 Canceling the Standby Mode................................................................................ 747

24.4.3 Standby Mode Application Example.................................................................... 748

Section 25 Electrical Characteristics (5V, 28.7 MHz Version) ............................. 749

25.1 Absolute Maximum Ratings .............................................................................................. 749

25.2 DC Characteristics............................................................................................................. 750

25.3 AC Characteristics............................................................................................................. 752

25.3.1 Clock Timing........................................................................................................ 752

25.3.2 Control Signal Timing.......................................................................................... 754

25.3.3 Bus Timing........................................................................................................... 757

25.3.4 Direct Memory Access Controller Timing........................................................... 768

25.3.5 Multifunction Timer Pulse Unit Timing............................................................... 770

25.3.6 I/O Port Timing..................................................................................................... 771

25.3.7 Watchdog Timer Timing ...................................................................................... 772

25.3.8 Serial Communication Interface Timing .............................................................. 773

25.3.9 High-speed A/D Converter Timing (excluding A mask) ..................................... 774

25.3.10 Mid-speed Converter Timing (A mask) ............................................................... 776

25.3.11 Measuring Conditions for AC Characteristics ..................................................... 778

25.4 A/D Converter Characteristics........................................................................................... 779

Section 26 Electrical Characteristics (3.3V, 16.7 MHz Version).......................... 781

26.1 Absolute Maximum Ratings .............................................................................................. 781

26.2 DC Characteristics............................................................................................................. 782

26.3 AC Characteristics............................................................................................................. 784

26.3.1 Clock Timing........................................................................................................ 784

26.3.2 Control Signal Timing.......................................................................................... 786

26.3.3 Bus Timing........................................................................................................... 789

26.3.4 Direct Memory Access Controller Timing........................................................... 800

26.3.5 Multifunction Timer Pulse Unit Timing............................................................... 802

26.3.6 I/O Port Timing..................................................................................................... 803

26.3.7 Watchdog Timer Timing ...................................................................................... 804

26.3.8 Serial Communication Interface Timing .............................................................. 805

26.3.9 High-speed A/D Converter Timing (excluding A mask) ..................................... 806

26.3.10 Mid-speed Converter Timing (A mask) ............................................................... 808

26.3.11 Measurement Conditions for AC Characteristic................................................... 810

26.4 A/D Converter Characteristics........................................................................................... 811

Appendix A On-Chip Supporting Module Registers................................................ 813

A.1 Addresses........................................................................................................................... 813

Appendix B Block Diagrams........................................................................................... 826

Appendix C Pin States....................................................................................................... 865

Appendix D Notes when Converting the F–ZTAT Application Software

to the Mask-ROM Versions..................................................................... 875

Appendix E Product Code Lineup................................................................................. 876

Appendix F Package Dimensions.................................................................................. 878

xvi

Section 1 SH7040 Series Overview

1.1 SH7040 Series Overview

The SH7040 Series (SH7040/41/42/43/44/45) CMOS single-chip microprocessors integrate a

Renesas-original architecture, high-speed CPU with peripheral functions required for system

configuration.

The CPU has a RISC-type instruction set. Most instructions can be executed in one clock cycle,

which greatly improves instruction execution speed. In addition, the 32-bit internal-bus

architecture enhances data processing power. With this CPU, it has become possible to assemble

low cost, high performance/high-functioning systems, even for applications that were previously

impossible with microprocessors, such as real-time control, which demands high speeds. In

particular, the SH7040 series has a 1-kbyte on-chip cache, which allows an improvement in CPU

performance during external memory access.

In addition, the SH7040 Series includes on-chip peripheral functions necessary for system

configuration, such as large-capacity ROM and RAM, timers, a serial communication interface

(SCI), an A/D converter, an interrupt controller, and I/O ports. Memory or peripheral LSIs can be

connected efficiently with an external memory access support function. This greatly reduces

system cost.

In addition to the masked-ROM versions of the SH7040 series, the SH7042 and SH7043 have a

ZTAT™*1 version with user-programmable on-chip PROM and the SH7044 and SH7045 have an

F-ZTATTM*2 version with on-chip flash memory. These versions enable users to respond quickly

and flexibly to changing application specifications, growing production volumes, and other

conditions.

Notes: *1 ZTAT (Zero Turn-Around Time) is a registered trademark of Renesas Technology

Corp.

*2 F-ZTAT (Flexible ZTAT) is a trademark of Renesas Technology Corp.

1.1.1 SH7040 Series Features

CPU:

• Original Renesas architecture

• 32-bit internal data bus

• General-register machine

 Sixteen 32-bit general registers

 Three 32-bit control registers

 Four 32-bit system registers

• RISC-type instruction set

 Instruction length: 16-bit fixed length for improved code efficiency

 Load-store architecture (basic operations are executed between registers)

 Delayed branch instructions reduce pipeline disruption during branch

 Instruction set based on C language

• Instruction execution time: one instruction/cycle (35 ns/instruction at 28.7-MHz operation)

• Address space: Architecture supports 4 Gbytes

• On-chip multiplier: multiplication operations (32 bits × 32 bits → 64 bits) and

multiplication/accumulation operations (32 bits × 32 bits + 64 bits → 64 bits) executed in two

to four cycles

• Five-stage pipeline

Cache Memory:

• 1-kbyte instruction cache

• Caching of instruction codes and PC relative read data

• 4-byte line length (1 longword: 2 instruction lengths)

• 256 entry cache tags

• Direct map method

• On-chip ROM/RAM, and on-chip I/O areas not objects of cache

• Used in common with on-chip RAM; 2 kbytes of on-chip RAM used as address array/data

array when cache is enabled

Interrupt Controller (INTC):

• Nine external interrupt pins (NMI, IRQ0–IRQ7)

• Forty-three internal interrupt sources (forty-four for A mask)

• Sixteen programmable priority levels

User Break Controller (UBC):

• Generates an interrupt when the CPU or DMAC generates a bus cycle with specified

conditions

• Simplifies configuration of an on-chip debugger

Bus State Controller (BSC):

• Supports external extended memory access

 16-bit (QFP-112, TQFP-120), or 32-bit (QFP-144) external data bus

• Memory address space divided into five areas (four areas of SRAM space, one area of DRAM

space) with the following settable features:

 Bus size (8, 16, or 32 bits)

 Number of wait cycles

 Outputs chip-select signals for each area

 During DRAM space access:

• Outputs RAS and CAS signals for DRAM

• Can generate a RAS precharge time assurance Tp cycle

• DRAM burst access function

 Supports high-speed access mode for DRAM

• DRAM refresh function

 Programmable refresh interval

 Supports CAS-before-RAS refresh and self-refresh modes

• Wait cycles can be inserted using an external WAIT signal

• Address data multiplex I/O devices can be accessed

Direct Memory Access Controller (DMAC) (4 Channels):

• Supports cycle-steal transfers

• Supports dual address transfer mode

• Can be switched between direct and indirect transfer modes (channel 3 only)

 Direct transfer mode: transfers the data at the transfer source address to the transfer

destination address

 Indirect transfer mode: regards the data at the transfer source address as an address and

transfers the data at that address to the transfer destination address

Data Transfer Controller (DTC):

• Data transfer independent of the CPU possible through peripheral I/O interrupt requests

• Transfer mode can be set for each interrupt factor (transfer mode set in memory)

• Multiple data transfers possible for one activating factor

• Abundant transfer modes

 Normal mode/repeat mode/block transfer mode selectable

• Transfer unit can be set to byte/word/longword

• Interrupts activating the DTC requested of the CPU

 Interrupts can be generated to the CPU after completion of one data transfer

 Interrupts can be generated to the CPU after completing all designated data transfers

• Transfer can be activated by software

Multifunction Timer/Pulse Unit (MTU):

• Maximum 16 types of waveform output or maximum 16 types of pulse I/O processing possible

based on 16-bit timer, 5 channels

• 16 dual-use output compare/input capture registers

• 16 independent comparators

• 8 types of counter input clock

• Input capture function

• Pulse output mode

 One shot, toggle, PWM, phase-compensated PWM, reset-synchronized PWM

• Multiple counter synchronization function

• Phase-compensated PWM output mode

 Non-overlapping waveform output for 6-phase inverter control

 Automatic setting for dead time

 PWM duty cycle can be set from 0 to 100%

 Output off function

• Reset-synchronized PWM mode

 3-phase output of any duty cycle positive phase/reverse phase PWM waveforms

• Phase calculation mode

 2-phase encoder calculation processing

Compare Match Timer (CMT) (Two Channels):

• 16-bit free-running counter

• One compare register

• Generates an interrupt request upon compare match

Watchdog Timer (WDT) (One Channel):

• Watchdog timer or interval timer

• Count overflow can generate an internal reset, external signal, or interrupt

Serial Communication Interface (SCI) (Two Channels):

(Per Channel):

• Asynchronous or clock-synchronous mode is selectable

• Can transmit and receive simultaneously (full duplex)

• On-chip dedicated baud rate generator

• Multiprocessor communication function

I/O Ports:

• QFP 112 (SH7040, SH7042, SH7044), TQFP-120 (SH7040, SH7042)

 Input/output: 74

 Input: 8

 Total: 82

• QFP 144 (SH7041, SH7043, SH7045)

 Input/output: 98

 Input: 8

 Total: 106

A/D Converter:

• 10 bits × 8 channels

• Conversion upon external trigger possible

• Sample and hold function: two on-chip units (two channels can be sampled simultaneously)

• Depending on the product, there is a high speed, mid-accuracy A/D on-chip type and a mid-

speed, high accuracy A/D on-chip type. For details, see the product lineup.

Large Capacity On-Chip Memory:

• ROM (128 kbytes PROM, 256 kbytes/128 kbytes/64 kbytes mask ROM, 256 kbytes flash

ROM)

 SH7044, SH7045: 256 kbytes (flash ROM, mask ROM)

 SH7042, SH7043: 128 kbytes (ZTAT, mask ROM)

 SH7040, SH7041: 64 kbytes (mask ROM)

• RAM: 4 kbytes (2 kbytes when cache is used)

Operating Modes:

• Operating modes

 Expanded mode with ROM disabled

 Expanded mode with ROM enabled

 Single-chip mode

• Processing states

 Program execution state

 Exception processing state

 Bus-released state

• Power-down modes

 Sleep mode

 Software standby mode

Clock Pulse Generator (CPG):

• On-chip clock pulse generator

 On-chip clock-doubling PLL circuit

Type Abbreviation Mask

Version On-chip

ROM External

Bus Width

A/D

Accuracy

(5V Version) Package Operating

Temp Frequency Voltage Type Name

Notes on the SH7040 Series Specifications (For details, see each section in this manual)

A/D Electrical

INTC DTC DMAC MTU Converter ROM Characteristics

ZTAT SH7042 128 kB 16 bits ±15LSB

(High-Speed)QFP2020-112 –20°C to 75°C 28 MHz

16 MHz 5 V

3.3 V HD6477042F28

HD6477042VF16 See “High-

Speed A/D

Converter”

See “128 kB

PROM” See “Electrical

Characteristics”

SH7042A A mask 128 kB 16 bits ±4LSB

(Mid-Speed) QFP2020-112

TQFP1414-120

QFP2020-112Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6477042AF28

HD6477042AVF16

HD6477042AVX16

HD6477042ACF28

HD6477042AVCF16

Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “128 kB

PROM” See “Electrical

Characteristics”

SH7043 128 kB 32 bits ±15LSB

(High-Speed)QFP2020-144 –20°C to 75°C 28 MHz

16 MHz 5 V

3.3 V HD6477043F28

HD6477043VF16 See “High-

Speed A/D

Converter”

See “128 kB

PROM” See “Electrical

Characteristics”

SH7043A A mask 128 kB 32 bits ±4LSB

(Mid-Speed) QFP2020-144

QFP2020-144Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6477043AF28

HD6477043AVF16

HD6477043ACF28

HD6477043AVCF16

Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “128 kB

PROM” See “Electrical

Characteristics”

FLASH SH7044F A mask 256 kB 16 bits ±4LSB

(Mid-Speed) QFP2020-112 –20°C to 75°C 28 MHz 5 V HD64F7044F28 Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “256 kB Flash

Memory” See “Electrical

Characteristics”

SH7045F A mask 256 kB 32 bits ±4LSB

(Mid-Speed) QFP2020-144 –20°C to 75°C 28 MHz 5 V HD64F7045F28 Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “256 kB Flash

Memory” See “Electrical

Characteristics”

MASK SH7040A A mask 64 kB 16 bits ±4LSB

(Mid-Speed) QFP2020-112

TQFP1414-120

QFP2020-112Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6437040AF28

HD6437040AVF16

HD6437040AVX16

HD6437040ACF28

HD6437040AVCF16

Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “64 kB Mask

ROM” See “Electrical

Characteristics”

SH7041A A mask 64 kB 32 bits ±4LSB

(Mid-Speed) QFP2020-144

QFP2020-144Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6437041AF28

HD6437041AVF16

HD6437041ACF28

HD6437041AVCF16

Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “64 kB Mask

ROM” See “Electrical

Characteristics”

SH7042 128 kB 16 bits ±15LSB

(High-Speed)QFP2020-112 –20°C to 75°C 28 MHz

16 MHz 5 V

3.3 V HD6437042F28

HD6437042VF16 See “High-

Speed A/D

Converter”

See “128 kB Mask

ROM” See “Electrical

Characteristics”

SH7042A A mask 128 kB 16 bits ±4LSB

(Mid-Speed) QFP2020-112

TQFP1414-120

QFP2020-112Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6437042AF28

HD6437042AVF16

HD6437042AVX16

HD6437042ACF28

HD6437042AVCF16

Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “128 kB Mask

ROM” See “Electrical

Characteristics”

SH7043 128 kB 32 bits ±15LSB

(High-Speed)QFP2020-144 –20°C to 75°C 28 MHz

16 MHz 5 V

3.3 V HD6437043F28

HD6437043VF16 See “High-

Speed A/D

Converter”

See “128 kB Mask

ROM” See “Electrical

Characteristics”

SH7043A A mask 128 kB 32 bits ±4LSB

(Mid-Speed) QFP2020-144

QFP2020-144Cu*

–20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6437043AF28

HD6437043AVF16

HD6437043ACF28

HD6437043AVCF16

Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “128 kB Mask

ROM” See “Electrical

Characteristics”

Type Abbreviation Mask

Version On-chip

ROM External

Bus Width

A/D

Accuracy

(5V Version) Package Operating

Temp Frequency Voltage Type Name

Notes on the SH7040 Series Specifications (For details, see each section in this manual)

A/D Electrical

INTC DTC DMAC MTU Converter ROM Characteristics

MASK SH7044 A mask 256 kB 16 bits ±4LSB

(Mid-Speed) QFP2020-112 –20°C to 75°C 28 MHz 5 V HD6437044F28 Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “256 kB Mask

ROM” See “Electrical

Characteristics”

SH7045 A mask 256kB 32bits ±4LSB

(Mid-Speed) QFP2020-144 -20°C to 75°C 28 MHz 5 V HD6437045F28 Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “256 kB Mask

ROM” See “Electrical

Characteristics”

ROM

less SH7040A A mask 16 bits ±4LSB

(Mid-Speed) QFP2020-112

TQFP1414-120

QFP2020-112Cu*

-20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6417040AF28

HD6417040AVF16

HD6417040AVX16

HD6417040ACF28

HD6417040AVCF16

Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “Electrical

Characteristics”

SH7041A A mask 32 bits ±4LSB

(Mid-Speed) QFP2020-144

QFP2020-144Cu*

-20°C to 75°C 28 MHz

16 MHz

28 MHz

16 MHz

5 V

3.3 V

5 V

3.3 V

HD6417041AF28

HD6417041AVF16

HD6417041ACF28

HD6417041AVCF16

Change the interrupt

vectors related A/D

converter

Change the DTER

access methods

and DTC vectors

Change the setting

methods on transfer

requests

Change the Usage

Notes See “Mid-

Speed A/D

Converter”

See “Electrical

Characteristics”

Note: * Package with Copper used as the lead material.

1.2 Block Diagram

Figure 1.1 is a block diagram of the SH7040 Series QFP-112 pin and TQFP-120 pin. Figure 1.2 is

a block diagram of the SH7040 Series QFP-144 pin.

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;

;;;;

;;;;;

;;;;

;;

;;;;

;;;

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;

;;;;;

;;;

;

;;

PC15/A15



PC14/A14



PC13/A13



PC12/A12



PC11/A11



PC10/A10



PC9/A9

PC8/A8

PC7/A7

PC6/A6

PC5/A5

PC4/A4

PC3/A3

PC2/A2

PC1/A1

PC0/A0

PD15/D15



PD14/D14



PD13/D13



PD12/D12



PD11/D11



PD10/D10



PD9/D9

PD8/D8

PD7/D7

PD6/D6

PD5/D5

PD4/D4

PD3/D3

PD2/D2

PD1/D1

PD0/D0

MD3

MD2

MD1

MD0

NMI

EXTAL

XTAL

VCC /FWP*1

VCC

PLLVCC

PLLCAP

PLLVSS

VCC

VSS

AVCC

AVSS

RES/VPP*2

WDTOVF

PB9/IRQ7/A21/ADTRG

PB8/IRQ6/A20/WAIT

PB7/IRQ5/A19/BREQ

PB6/IRQ4/A18/BACK

PB5/IRQ3/POE3/RDWR



PB4/IRQ2/POE2/CASH

PB3/IRQ1/POE1/CASL

PB2/IRQ0/POE0/RAS

PB1/A17

PB0/A16

PA15/CK

PA14/RD

PA13/WRH

PA12/WRL

PA11/CS1

PA10/CS0

PA9/TCLKD/IRQ3

PA8/TCLKC/IRQ2

PA7/TCLKB/CS3

PA6/TCLKA/CS2

PA5/SCK1/DREQ1/IRQ

PA4/TXD1

PA3/RXD1

PA2/SCK0/DREQ0/IRQ

PA1/TXD0

PA0/RXD0

PE15/TIOC4D/DACK1/IRQOUT

PE14/TIOC4C/DACK0/AH

PE13/TIOC4B/MRES

PE12/TIOC4A

PE11/TIOC3D

PE10/TIOC3C

PE9/TIOC3B

PE8/TIOC3A

PE7/TIOC2B

PE6/TIOC2A

PE5/TIOC1B

PE4/TIOC1A

PE3/TIOC0D/DRAK1

PE2/TIOC0C/DREQ1

PE1/TIOC0B/DRAK0

PE0/TIOC0A/DREQ0

;;;;

;;;;;

: Peripheral address bus

: Peripheral data bus

: Internal address bus

: Internal upper data bus

: Internal lower data bus

PLL



PF7/AN7

PF6/AN6

PF5/AN5

PF4/AN4

PF3/AN3

PF2/AN2

PF1/AN1

PF0/AN0

Flash ROM/PROM/

mask ROM 

256kbytes/

128 kbytes/64 kbytes

RAM/cache

4 kbytes/1 kbyte

CPU

Data transfer

controller

Direct memory

access controller

Interrupt

controller User

break Bus state controller

Serial communi-

cation interface

(×2 channels)

Multifunction timer/

pulse unit

Compare match

timer (×2 channels) A/D

converter Watch-

dog

timer

VSS

;;

;;;;;;;

;;;

;;

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;

;;;;



Notes:*1VCC in the mask and ZTAT versions; FWP in the F-ZTAT version

 (however, FWE in writer mode)

*2Vpp: ZTAT v ersion only



Figure 1.1 Block Diagram of the SH7040, SH7042, SH7044 (QFP-112 Pin), SH7040, SH7042

(TQFP-120 pin)

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;

;;;;

;;;;;

;;;;

;;

;;;;;

;;;

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;

;;;;;;

;;;

;;

PC15/A15

PC14/A14

PC13/A13

PC12/A12

PC11/A11

PC10/A10

PC9/A9

PC8/A8

PC7/A7

PC6/A6

PC5/A5

PC4/A4

PC3/A3

PC2/A2

PC1/A1

PC0/A0

PD15/D15

PD14/D14

PD13/D13

PD12/D12

PD11/D11

PD10/D10

PD9/D9

PD8/D8

PD7/D7

PD6/D6

PD5/D5

PD4/D4

PD3/D3

PD2/D2

PD1/D1

PD0/D0

PD31/D31/ADTRG

PD30/D30/IRQOUT

PD29/D29/CS3

PD28/D28/CS2

PD27/D27/DACK1



PD26/D26/DACK0



PD25/D25/DREQ1

PD24/D24/DREQ0

PD23/D23/IRQ7

PD22/D22/IRQ6

PD21/D21/IRQ5

PD20/D20/IRQ4

PD19/D19/IRQ3

PD18/D18/IRQ2

PD17/D17/IRQ1

PD16/D16/IRQ0

MD3

MD2

MD1

MD0

NMI

EXTAL

XTAL

PLLVCC

PLLCAP

PLLVSS

RES/VPP*2

WDTOVF

PB9/IRQ7/A21/ADTRG

PB8/IRQ6/A20/WAIT

PB7/IRQ5/A19/BREQ

PB6/IRQ4/A18/BACK

PB5/IRQ3/POE3/RDWR



PB4/IRQ2/POE2/CASH

PB3/IRQ1/POE1/CASL

PB2/IRQ0/POE0/RAS

PB1/A17

PB0/A16

PA23/WRHH

PA22/WRHL

PA21/CASHH

PA20/CASHL

PA19/BACK/DRAK1

PA18/BREQ/DRAK0

PA17/WAIT

PA16/AH

PA15/CK

PA14/RD

PA13/WRH

PA12/WRL

PA11/CS1

PA10/CS0

PA9/TCLKD/IRQ3

PA8/TCLKC/IRQ2

PA7/TCLKB/CS3

PA6/TCLKA/CS2

PA5/SCK1/DREQ1/IRQ1

PA4/TXD1

PA3/RXD1

PA2/SCK0/DREQ0/IRQ0

PA1/TXD0

PA0/RXD0

PE15/TIOC4D/DACK1/IRQOUT

PE14/TIOC4C/DACK0/AH

PE13/TIOC4B/MRES

PE12/TIOC4A

PE11/TIOC3D

PE10/TIOC3C

PE9/TIOC3B

PE8/TIOC3A

PE7/TIOC2B

PE6/TIOC2A

PE5/TIOC1B

PE4/TIOC1A

PE3/TIOC0D/DRAK1

PE2/TIOC0C/DREQ1

PE1/TIOC0B/DRAK0

PE0/TIOC0A/DREQ0

PLL



PF7/AN7

PF6/AN6

PF5/AN5

PF4/AN4

PF3/AN3

PF2/AN2

PF1/AN1

PF0/AN0

Flash ROM/PROM/

mask ROM 

256 kbytes/

128 kbytes/64 kbytes

RAM/cache

4 kbytes/1 kbyte

CPU

Data transfer

controller

Direct memory

access controller

Interrupt

controller User

break Bus state controller

Serial communi-

cation interface

(×2 channels)

Multifunction timer/

pulse unit

Compare match

timer (×2 channels) A/D

converter Watch-

dog

timer

VCC /FWP*1

VCC

VSS

AVSS

AVref

AVCC

;;;

;;;;;;;

;;;;

;;;;;;;

;;;

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;

;;;;

;;;;;

: Peripheral address bus

: Peripheral data bus

: Internal address bus

: Internal upper data bus

: Internal lower data bus

Notes:*1VCC in the mask and ZTAT versions; FWP in the F-ZTAT version (however, FWE in writer mode)

*2Vpp: ZTAT v ersion only



Figure 1.2 Block Diagram of the SH7041, SH7043, SH7045 (QFP-144 Pin)

1.3 Pin Arrangement and Pin Functions

1.3.1 Pin Arrangment

Figure 1.3 shows the pin arrangement for the QFP-112 (top view).

PE0/TIOC0A/DREQ0

PE1/TIOC0B/DRAK0

PE2/TIOC0C/DREQ1

PE3/TIOC0D/DRAK1

PE4/TIOC1A

VSS

PF0/AN0

PF1/AN1

PF2/AN2

PF3/AN3

PF4/AN4

PF5/AN5

AVSS

PF6/AN6

PF7/AN7

AVCC

VSS

PE5/TIOC1B

VCC

PE6/TIOC2A

PE7/TIOC2B

PE8/TIOC3A

PE9/TIOC3B

PE10/TIOC3C

VSS

PE11/TIOC3D

PE12/TIOC4A

PB13/TIOC4B/MRES

100

101

102

103

104

105

106

107

108

109

110

111

112

RES/VPP*2

PA15/CK

PLLVSS

PLLCAP

PLLVCC

MD0

MD1

VCC (FWP*1)

NMI

MD2

EXTAL

MD3

XTAL

VSS

PD0/D0

PD1/D1

PD2/D2

PD3/D3

PD4/D4

VCC

PD5/D5

PD6/D6

PD7/D7

VSS

PD8/D8

PD9/D9

PD10/D10

PD11/D11

PD12/D12

VSS

PD13/D13

PD14/D14

PD15/D15

PA0/RXD0

PA1/TXD0

PA2/SCK0/DREQ0/IRQ0

PA3/RXD1

PA4/TXD1

PA5/SCK1/DREQ1/IRQ1

PA7/TCLKB/CS3

PA8/TCLKC/IRQ2

PA10/CS0

PA11/CS1

VSS

PA12/WRL

VCC

PA13/WRH

WDTOVF

PA14/RD

VSS

PB9/IRQ7/A21/ADTRG

PB8/IRQ6/A20/WAIT

PB7/IRQ5/A19/BREQ

PB6/IRQ4/A18/BACK

PA6/TCLKA/CS2

PA9/TCLKD/IRQ3

PE14/TIOC4C/DACK0/AH

PE15/TIOC4D/DACK1/IRQOUT

VSS

PC0/A0

PC1/A1

PC2/A2

PC3/A3

PC4/A4

PC5/A5

PC6/A6

PC7/A7

PC11/A11

PC12/A12

PC13/A13

PC14/A14

PC15/A15

PB0/A16

VCC

PB1/A17

PB2/IRQ0/POE0/RAS

PB3/IRQ1/POE1/CASL

PB4/IRQ2/POE2/CASH

VSS

PB5/IRQ3/POE3/RDWR

PC8/A8

PC9/A9

PC10/A10

VSS

QFP-112

Notes:*1VCC in the mask and ZTAT versions; FWP in the F-ZTAT version (however, FWE in writer mode)

*2Vpp: ZTAT v ersion only



Figure 1.3 SH7040, SH7042, SH7044 Pin Arrangement (QFP-112 Top View)

Figure 1.4 shows the pin arrangement for the TFP-120 (top view).

TQFP-120

PE15/TIOC4D/DACK1/IRQOUT

Vss

PC0/A0

PC1/A1

PC2/A2

PC3/A3

PC4/A4

PC5/A5

PE14/TIOC4C/DACK0/AH

PC6/A6

PC7/A7

PC8/A8

PC9/A9

PC10/A10

PC11/A11

PC12/A12

PC13/A13

PC14/A14

PC15/A15

PB0/A16

Vcc

PB1/A17

Vss

PB2/IRQ0/POE0/RAS

PB3/IRQ1/POE1/CASL

PB4/IRQ2/POE2/CASH

Vss

PB5/IRQ3/POE3/RDWR

PB6/IRQ4/A18/BACK

PB7/IRQ5/A19/BREQ

PB8/IRQ6/A20/WAIT

PB9/IRQ7/A21/ADTRG

Vss

PA14/RD

WDTOVF

PA13/WRH

Vcc

PA12/WRL

Vss

PA11/CS1

PA10/CS0

PA9/TCLKD/IRQ3

PA8/TCLKC/IRQ2

PA7/TCLKB/CS3

PA6/TCLKA/CS2

PA5/SCK1/DREQ1/IRQ1

PA4/TXD1

PA3/RXD1

PA2/SCK0/DREQ0/IRQ0

PA1/TXD0

PA0/RXD0

PD15/D15

PD14/D14

PD13/D13

Vss

PD12/D12

RES/(Vpp*)

PA15/CK

PLLVss

PLLCAP

PLLVcc

MD0

MD1

Vcc

NMI

MD2

EXTAL

MD3

XTAL

Vss

PD0/D0

PD1/D1

PD2/D2

PD3/D3

PD4/D4

Vcc

PD5/D5

PD6/D6

PD7/D7

Vss

PD8/D8

PD9/D9

PD10/D10

PD11/D11

PE13/TIOC4B/MRES

PE12/TIOC4A

PE11/TIOC3D

Vss

PE10/TIOC3C

PE9/TIOC3B

PE8/TIOC3A

PE7/TIOC2B

PE6/TIOC2A

Vcc

PE5/TIOC1B

Vss

AVcc

PF7/AN7

PF6/AN6

AVss

PF5/AN5

PF4/AN4

PF3/AN3

PF2/AN2

PF1/AN1

PF0/AN0

Vss

PE4/TIOC1A

PE3/TIOC0D/DRAK1

PE2/TIOC0C/DREQ

PE1/TIOC0B/DRAK0

120

119

118

117

116

115

114

113

112

111

110

109

108

107

106

105

104

103

102

101

100

60 PE0/TIOC0A/DREQ0

Note: *Vpp: ZTAT version only

Figure 1.4 SH7040, SH7042 Pin Arrangement (TQFP-120 Top View)

Figure 1.5 shows the pin arrangement for the QFP-144 (top view).

PA23/WRHH

PE14/TIOC4C/DACK0/AH

PA22/WRHL

PA21/CASHH

PE15/TIOC4D/DACK1/IRQOUT

PC0/A0

PC1/A1

PC2/A2

PC3/A3

PC4/A4

PC6/A6

PC7/A7

PC8/A8

PC9/A9

PC10/A10

PC11/A11

PC12/A12

PC13/A13

PC15/A15

PB0/A16

PB1/A17

PC5/A5

PC14/A14

PA20/CASHL

PA19/BACK/DRAK1

PB3/IRQ1/POE1/CASL

PA18/BREQ/DRAK0

PB4/IRQ2/POE2/CASH

VSS

PB5/IRQ3/POE3/RDWR

PB2/IRQ0/POE0/RAS

RES/V

PA15/CK

PLLVSS

PLLCAP

PLLVCC

MD0

MD1

PA17/WAIT

PA16/AH

CC (FWP

NMI

MD2

EXTAL

MD3

XTAL

PD0/D0

PD1/D1

PD2/D2

PD3/D3

PD4/D4

PD5/D5

PD6/D6

PD7/D7

PD8/D8

PD9/D9

108

107

106

105

104

103

102

101

100

PD10/D10

PD11/D11

PD12/D12

PD13/D13

PD14/D14

PD15/D15

72 PD16/D16/IRQ0

PD17/D17/IRQ1

PD18/D18/IRQ2

PD19/D19/IRQ3

PD20/D20/IRQ4

PD21/D21/IRQ5

PD22/D22/IRQ6

PD23/D23/IRQ7

PD24/D24/DREQ0

PD27/D27/DACK1

PD28/D28/CS2

PD29/D29/CS3

PA6/TCLKA/CS2

PA7/TCLKB/CS3

PA8/TCLKC/IRQ2

PA9/TCLKD/IRQ3

PA11/CS1

PA12/WRL

PA13/WRH

PD30/D30/IRQOUT

PD31/D31/ADTRG

PD25/D25/DREQ1

PD26/D26/DACK0

PA10/CS0

WDTOVF

PA14/RD

PB9/IRQ7/A21/ADTRG

PB8/IRQ6/A20/WAIT

PB7/IRQ5/A19/BREQ

PB6/IRQ4/A18/BACK

109

110

111

112

113

114

115

116

117

118

119

123

124

125

126

127

128

129

130

132

133

134

135

136

120

121

122

131

PE0/TIOC0A/DREQ0

PE1/TIOC0B/DRAK0

PE2/TIOC0C/DREQ1

PE3/TIOC0D/DRAK1

PE4/TIOC1A

PE5/TIOC1B

PE6/TIOC2A

PF0/AN0

PF1/AN1

PF2/AN2

PF3/AN3

PF4/AN4

PF5/AN5

PF6/AN6

PF7/AN7

AVref

PA0/RXD0

PA1/TXD0

PA2/SCK0/DREQ0/IRQ0

PA3/RXD1

PA4/TXD1

PA5/SCK1/DREQ1/IRQ1

PE7/TIOC2B

PE8/TIOC3A

PE9/TIOC3B

PE10/TIOC3C

PE11/TIOC3D

PE12/TIOC4A

PE13/TIOC4B/MRES

137

138

140

141

142

143

144

139

QFP-144

Notes:*1V

in the mask and ZTAT versions; FWP in the F-ZTAT version (however, FWE in writer mode)

*2V

: ZTAT version only



Figure 1.5 SH7041, SH7043, SH7045 Pin Arrangement (QFP-144 Top View)

1.3.2 Pin Arrangement by Mode

Table 1.2 Pin Arrangement by Mode for SH7040, SH7042 (QFP-112 Pin)

Pin No. MCU Mode PROM Mode

1 PE14/TIOC4C/DACK0/AH VCC

2 PE15/TIOC4D/DACK1/IRQOUT CE

SS VSS

4 PC0/A0 A0

5 PC1/A1 A1

6 PC2/A2 A2

7 PC3/A3 A3

8 PC4/A4 A4

9 PC5/A5 A5

10 PC6/A6 A6

11 PC7/A7 A7

12 PC8/A8 A8

13 PC9/A9 NC

14 PC10/A10 A10

15 PC11/A11 A11

16 PC12/A12 A12

17 PC13/A13 A13

18 PC14/A14 A14

19 PC15/A15 A15

20 PB0/A16 A16

21 VCC VCC

22 PB1/A17 NC

23 VSS VSS

24 PB2/IRQ0/POE0/RAS NC

25 PB3/IRQ1/POE1/CASL OE

26 PB4/IRQ2/POE2/CASH PGM

27 VSS VSS

28 PB5/IRQ3/POE3/RDWR VCC

Table 1.2 Pin Arrangement by Mode for SH7040, SH7042 (QFP-112 Pin) (cont)

Pin No. MCU Mode PROM Mode

29 PB6/IRQ4/A18/BACK NC

30 PB7/IRQ5/A19/BREQ NC

31 PB8/IRQ6/A20/WAIT NC

32 PB9/IRQ7/A21/ADTRG NC

33 VSS VSS

34 PA14/RD NC

35 WDTOVF NC

36 PA13/WRH NC

37 VCC VCC

38 PA12/WRL NC

39 VSS VSS

40 PA11/CS1 NC

41 PA10/CS0 NC

42 PA9/TCLKD/IRQ3 NC

43 PA8/TCLKC/IRQ2 NC

44 PA7/TCLKB/CS3 NC

45 PA6/TCLKA/CS2 NC

46 PA5/SCK1/DREQ1/IRQI NC

47 PA4/TXD1 NC

48 PA3 /RXD1 NC

49 PA2/SCK0/DREQ0/IRQ0 NC

50 PA1/TXD0 NC

51 PA0/RXD0 NC

52 PD15/D15 NC

53 PD14/D14 NC

54 PD13/D13 NC

55 VSS VSS

56 PD12/D12 NC

57 PD11/D11 NC

58 PD10/D10 NC

Table 1.2 Pin Arrangement by Mode for SH7040, SH7042 (QFP-112 Pin) (cont)

Pin No. MCU Mode PROM Mode

59 PD9/D9 NC

60 PD8/D8 NC

61 VSS VSS

62 PD7/D7 D7

63 PD6/D6 D6

64 PD5/D5 D5

65 VCC VCC

66 PD4/D4 D4

67 PD3/D3 D3

68 PD2/D2 D2

69 PD1/D1 D1

70 PD0/D0 D0

71 VSS VSS

72 XTAL NC

73 MD3 VCC

74 EXTAL VSS

75 MD2 VCC

76 NMI A9

77 VCC VCC

78 MD1 VCC

79 MD0 VCC

80 PLLVCC VCC

81 PLLCAP VSS

82 PLLVSS VSS

83 PA15/CK NC

84 RES VPP

85 PE0/TIOC0A/DREQ0 NC

86 PE1/TIOC0B/DRAK0 NC

87 PE2/TIOC0C/DREQ1 NC

88 PE3/TIOC0D/DRAK1 NC

Table 1.2 Pin Arrangement by Mode for SH7040, SH7042 (QFP-112 Pin) (cont)

Pin No. MCU Mode PROM Mode

89 PE4/TIOC1A NC

90 VSS VSS

91 PF0/AN0 VSS

92 PF1/AN1 VSS

93 PF2/AN2 VSS

94 PF3/AN3 VSS

95 PF4/AN4 VSS

96 PF5/AN5 VSS

97 AVSS VSS

98 PF6/AN6 VSS

99 PF7/AN7 VSS

100 AVCC VCC

101 VSS VSS

102 PE5/TIOC1B NC

103 VCC VCC

104 PE6/TIOC2A NC

105 PE7/TIOC2B NC

106 PE8/TIOC3A NC

107 PE9/TIOC3B NC

108 PE10/TIOC3C NC

109 VSS VSS

110 PE11/TIOC3D NC

111 PE12/TIOC4A NC

112 PE13/TIOC4B/MRES NC

Table 1.3 Pin Arrangement by Mode for SH7040, SH7042 (TQFP-120 Pin)

TQFP120 Pin No. MCU Mode PROM Mode

1NC NC

2 PE14/TIOC4C/DACK0/AH VCC

3 PE15/TIOC4D/DACK1/IRQOUT CE

SS VSS

5 PC0/A0 A0

6 PC1/A1 A1

7 PC2/A2 A2

8 PC3/A3 A3

9 PC4/A4 A4

10 PC5/A5 A5

11 PC6/A6 A6

12 PC7/A7 A7

13 PC8/A8 A8

14 PC9/A9 NC

15 PC10/A10 A10

16 PC11/A11 A11

17 PC12/A12 A12

18 PC13/A13 A13

19 PC14/A14 A14

20 PC15/A15 A15

21 PB0/A16 A16

22 VCC VCC

23 PB1/A17 NC

24 VSS VSS

25 PB2/IRQ0/POE0/RAS NC

26 PB3/IRQ1/POE1/CASL OE

27 PB4/IRQ2/POE2/CASH PGM

28 VSS VSS

29 PB5/IRQ3/POE3/RDWR VCC

30 NC NC

31 NC NC

Table 1.3 Pin Arrangement by Mode for SH7040, SH7042 (TQFP-120 Pin) (cont)

TQFP120 Pin No. MCU Mode PROM Mode

32 PB6/IRQ4/A18/BACK NC

33 PB7/IRQ5/A19/BREQ NC

34 PB8/IRQ6/A20/WAIT NC

35 PB9/IRQ7/A21/ADTRG NC

36 VSS VSS

37 PA14/RD NC

38 WDTOVF NC

39 PA13/WRH NC

40 VCC VCC

41 PA12/WRL NC

42 VSS VSS

43 PA11/CS1 NC

44 PA10/CS0 NC

45 PA9/TCLKD/IRQ3 NC

46 PA8/TCLKC/IRQ2 NC

47 PA7/TCLKB/CS3 NC

48 PA6/TCLKA/CS2 NC

49 PA5/SCK1/DREQ1/IRQ1 NC

50 PA4/TXD1 NC

51 PA3/RXD2 NC

52 PA2/SCK0/DREQ0/IRQ0 NC

53 PA1/TXD0 NC

54 PA0/RXD0 NC

55 PD15/D15 NC

56 PD14/D14 NC

57 PD13/D13 NC

58 VSS VSS

59 PD12/D12 NC

60 NC NC

61 NC NC

62 PD11/D11 NC

Table 1.3 Pin Arrangement by Mode for SH7040, SH7042 (TQFP-120 Pin) (cont)

TQFP120 Pin No. MCU Mode PROM Mode

63 PD10/D10 NC

64 PD9/D9 NC

65 PD8/D8 NC

66 VSS VSS

67 PD7/D7 D7

68 PD6/D6 D6

69 PD5/D5 D5

70 VCC VCC

71 PD4/D4 D4

72 PD3/D3 D3

73 PD2/D2 D2

74 PD1/D1 D1

75 PD0/D0 D0

76 VSS VSS

77 XTAL NC

78 MD3 VCC

79 EXTAL VSS

80 MD2 VCC

81 NMI A9

82 VCC VCC

83 MD1 VCC

84 MD0 VCC

85 PLLVCC VCC

86 PLLCAP VSS

87 PLLVSS VSS

88 PA15/CK NC

89 RES VPP

90 NC NC

91 NC NC

92 PE0/TIOC0A/DREQ0 NC

93 PE1/TIOC0B/DRAK0 NC

Table 1.3 Pin Arrangement by Mode for SH7040, SH7042 (TQFP-120 Pin) (cont)

TQFP120 Pin No. MCU Mode PROM Mode

94 PE2/TIOC0C/DREQ1 NC

95 PE3/TIOC0D/DRAK1 NC

96 PE4/TIOC1A NC

97 VSS VSS

98 PF0/AN0 VSS

99 PF1/AN1 VSS

100 PF2/AN2 VSS

101 PF3/AN3 VSS

102 PF4/AN4 VSS

103 PF5/AN5 VSS

104 AVSS VSS

105 PF6/AN6 VSS

106 PF7/AN7 VSS

107 AVCC VCC

108 VSS VSS

109 PE5/TIOC1B NC

110 NC NC

111 VCC VCC

112 PE6/TIOC2A NC

113 PE7/TIOC2B NC

114 PE8/TIOC3A NC

115 PE9/TIOC3B NC

116 PE10/TIOC3C NC

117 VSS VSS

118 PE11/TIOC3D NC

119 PE12/TIOC4A NC

120 PE13/TIOC4B/MRES NC

Table 1.4 Pin Arrangement by Mode for SH7041, SH7043 (QFP-144 Pin)

Pin No. MCU Mode PROM Mode

1 PA23/WRHH NC

2 PE14/TIOC4C/DACK0/AH VCC

3 PA22/WRHL NC

4 PA21/CASHH NC

5 PE15/TIOC4D/DACK1/IRQOUT CE

SS VSS

7 PC0/A0 A0

8 PC1/A1 A1

9 PC2/A2 A2

10 PC3/A3 A3

11 PC4/A4 A4

12 VCC VCC

13 PC5/A5 A5

14 VSS VSS

15 PC6/A6 A6

16 PC7/A7 A7

17 PC8/A8 A8

18 PC9/A9 NC

19 PC10/A10 A10

20 PC11/A11 A11

21 PC12/A12 A12

22 PC13/A13 A13

23 PC14/A14 A14

24 PC15/A15 A15

25 PB0/A16 A16

26 VCC VCC

27 PB1/A17 NC

28 VSS VSS

29 PA20/CASHL NC

30 PA19/BACK/DRAK1 NC

Table 1.4 Pin Arrangement by Mode for SH7041, SH7043 (QFP-144 Pin) (cont)

Pin No. MCU Mode PROM Mode

31 PB2/IRQ0/POE0/RAS NC

32 PB3/IRQ1/POE1/CASL OE

33 PA18/BREQ/DRAK0 NC

34 PB4/IRQ2/POE2/CASH PGM

35 VSS VSS

36 PB5/IRQ3/POE3/RDWR VCC

37 PB6/IRQ4/A18/BACK NC

38 PB7/IRQ5/A19/BREQ NC

39 PB8/IRQ6/A20/WAIT NC

40 VCC VCC

41 PB9/IRQ7/A21/ADTRG NC

42 VSS VSS

43 PA14/RD NC

44 WDTOVF NC

45 PD31/D31/ADTRG NC

46 PD30/D30/IRQOUT NC

47 PA13/WRH NC

48 PA12/WRL NC

49 PA11/CS1 NC

50 PA10/CS0 NC

51 PA9/TCLKD/IRQ3 NC

52 PA8/TCLKC/IRQ2 NC

53 PA7/TCLKB/CS3 NC

54 PA6/TCLKA/CS2 NC

55 VSS VSS

56 PD29/D29/CS3 NC

57 PD28/D28/CS2 NC

58 PD27/D27/DACK1 NC

59 PD26/D26/DACK0 NC

60 PD25/D25/DREQ1 NC

Table 1.4 Pin Arrangement by Mode for SH7041, SH7043 (QFP-144 Pin) (cont)

Pin No. MCU Mode PROM Mode

61 VSS VSS

62 PD24/D24/DREQ0 NC

63 VCC VCC

64 PD23/D23/IRQ7 NC

65 PD22/D22/IRQ6 NC

66 PD21/D21/IRQ5 NC

67 PD20/D20/IRQ4 NC

68 PD19/D19/IRQ3 NC

69 PD18/D18/IRQ2 NC

70 PD17/D17/IRQ1 NC

71 VSS VSS

72 PD16/D16/IRQ0 NC

73 PD15/D15 NC

74 PD14/D14 NC

75 PD13/D13 NC

76 PD12/D12 NC

77 VCC VCC

78 PD11/D11 NC

79 VSS VSS

80 PD10/D10 NC

81 PD9/D9 NC

82 PD8/D8 NC

83 PD7/D7 D7

84 PD6/D6 D6

85 VCC VCC

86 PD5 /D5 D5

87 VSS VSS

88 PD4/D4 D4

89 PD3/D3 D3

90 PD2/D2 D2

Table 1.4 Pin Arrangement by Mode for SH7041, SH7043 (QFP-144 Pin) (cont)

Pin No. MCU Mode PROM Mode

91 PD1/D1 D1

92 PD0/D0 D0

93 VSS VSS

94 XTAL NC

95 MD3 VCC

96 EXTAL VSS

97 MD2 VCC

98 NMI A9

99 VCC VCC

100 PA16/AH NC

101 PA17/WAIT NC

102 MD1 VCC

103 MD0 VCC

104 PLLVCC VCC

105 PLLCAP VSS

106 PLLVSS VSS

107 PA15/CK NC

108 RES VPP

109 PE0/TIOC0A/DREQ0 NC

110 PE1/TIOC0B/DRAK0 NC

111 PE2/TIOC0C/DREQ1 NC

112 VCC VCC

113 PE3/TIOC0D/DRAK1 NC

114 PE4/TIOC1A NC

115 PE5/TIOC1B NC

116 PE6/TIOC2A NC

117 VSS VSS

118 PF0/AN0 VSS

119 PF1/AN1 VSS

120 PF2/AN2 VSS

Table 1.4 Pin Arrangement by Mode for SH7041, SH7043 (QFP-144 Pin) (cont)

Pin No. MCU Mode PROM Mode

121 PF3/AN3 VSS

122 PF4/AN4 VSS

123 PF5/AN5 VSS

124 AVSS VSS

125 PF6/AN6 VSS

126 PF7/AN7 VSS

127 AVref VCC

128 AVCC VCC

129 VSS VSS

130 PA0/RXD0 NC

131 PA1/TXD0 NC

132 PA2/SCK0/DREQ0 /IREQ0 NC

133 PA3/RXD1 NC

134 PA4/TXD1 NC

135 VCC VCC

136 PA5 /SCK1/DREQ1/IREQ1 NC

137 PE7/TIOC2B NC

138 PE8/TIOC3A NC

139 PE9/TIOC3B NC

140 PE10/TIOC3C NC

141 VSS VSS

142 PE11/TIOC3D NC

143 PE12/TIOC4A NC

144 PE13/TIOC4B /MRES NC

Table 1.5 Pin Arrangement by Mode for SH7044 (QFP-112 Pin)

PinNo. MCU Writer mode

1 PE14/TIOC4C/DACK0/AH NC

2 PE15/TIOC4D/DACK1/IRQOUT NC

SS VSS

4 PC0/A0 A0

5 PC1/A1 A1

6 PC2/A2 A2

7 PC3/A3 A3

8 PC4/A4 A4

9 PC5/A5 A5

10 PC6/A6 A6

11 PC7/A7 A7

12 PC8/A8 A8

13 PC9/A9 A9

14 PC10/A10 A10

15 PC11/A11 A11

16 PC12/A12 A12

17 PC13/A13 A13

18 PC14/A14 A14

19 PC15/A15 A15

20 PB0/A16 A16

21 VCC VCC

22 PB1/A17 NC

23 VSS VSS

24 PB2/IRQ0/POE0/RAS NC

25 PB3/IRQ1/POE1/CASL NC

26 PB4/IRQ2/POE2/CASH A17

27 VSS VSS

28 PB5/IRQ3/POE3/RDWR NC

29 PB6/IRQ4/A18/BACK NC

30 PB7/IRQ5/A19/BREQ NC

31 PB8/IRQ6/A20/WAIT NC

32 PB9/IRQ7/A21/ADTRG NC

Table 1.5 Pin Arrangement by Mode for SH7044 (QFP-112 Pin) (cont)

PinNo. MCU Writer mode

33 VSS VSS

34 PA14/RD NC

35 WDTOVF NC

36 PA13/WRH NC

37 VCC VCC

38 PA12/WRL NC

39 VSS VSS

40 PA11/CS1 NC

41 PA10/CS0 NC

42 PA9/TCLKD/IRQ3 CE

43 PA8/TCLKC/IRQ2 OE

44 PA7/TCLKB/CS3 WE

45 PA6/TCLKA/CS2 NC

46 PA5/SCK1/DREQ1/IRQ1 VCC

47 PA4/TXD1 NC

48 PA3/RXD1 NC

49 PA2/SCK0/DREQ0/IRQ0 VCC

50 PA1/TXD0 VCC

51 PA0/RXD0 NC

52 PD15/D15 NC

53 PD14/D14 NC

54 PD13/D13 NC

55 VSS VSS

56 PD12/D12 NC

57 PD11/D11 NC

58 PD10/D10 NC

59 PD9/D9 NC

60 PD8/D8 NC

61 VSS VSS

62 PD7/D7 D7

63 PD6/D6 D6

64 PD5/D5 D5

Table 1.5 Pin Arrangement by Mode for SH7044 (QFP-112 Pin) (cont)

PinNo. MCU Writer mode

65 VCC VCC

66 PD4/D4 D4

67 PD3/D3 D3

68 PD2/D2 D2

69 PD1/D1 D1

70 PD0/D0 D0

71 VSS VSS

72 XTAL XTAL

73 MD3 MD3

74 EXTAL EXTAL

75 MD2 MD2

76 NMI VCC

77 VCC (FWP)*FWE

78 MD1 MD1

79 MD0 MD0

80 PLLVCC PLLVCC

81 PLLCAP PLLCAP

82 PLLVSS PLLVSS

83 PA15/CK NC

84 RES RES

85 PE0/TIOCA/DREQ0 NC

86 PE1/TIOCB/DRAK0 NC

87 PE2/TIOCC/DREQ1 NC

88 PE3/TIOCD/DRAK1 NC

89 PE4/TIOC1A NC

90 VSS VSS

91 PF0/AN0 VSS

92 PF1/AN1 VSS

93 PF2/AN2 VSS

94 PF3/AN3 VSS

95 PF4/AN4 VSS

96 PF5/AN5 VSS

Note: *VCC in the mask version; FWP in the F-ZTAT version (however, FWE in the writer mode)

Table 1.5 Pin Arrangement by Mode for SH7044 (QFP-112 Pin) (cont)

PinNo. MCU Writer mode

97 AVSS VSS

98 PF6/AN6 VSS

99 PF7/AN7 VSS

100 AVCC VCC

101 VSS VSS

102 PE5/TIOC1B NC

103 VCC VCC

104 PE6/TIOC2A NC

105 PE7/TIOC2B NC

106 PE8/TIOC3A NC

107 PE9/TIOC3B NC

108 PE10/TIOC3C NC

109 VSS VSS

110 PE11/TIOC3D NC

111 PE12/TIOC4A NC

112 PE13/TIOC4B/MRES NC

Table 1.6 Pin Arrangement by Mode for SH7045 (QFP-144 Pin)

PinNo. MCU Writer mode

1 PA23/WRHH NC

2 PE14/TIOC4C/DACK0/AH NC

3 PA22/WRHL NC

4 PA21/CASHH NC

5 PE15/TIOC4D/DACK1/IRQOUT NC

SS VSS

7 PC0/A0 A0

8 PC1/A1 A1

9 PC2/A2 A2

10 PC3/A3 A3

11 PC4/A4 A4

12 VCC VCC

13 PC5/A5 A5

14 VSS VSS

15 PC6/A6 A6

16 PC7/A7 A7

17 PC8/A8 A8

18 PC9/A9 A9

19 PC10/A10 A10

20 PC11/A11 A11

21 PC12/A12 A12

22 PC13/A13 A13

23 PC14/A14 A14

24 PC15/A15 A15

25 PB0/A16 A16

26 VCC VCC

27 PB1/A17 NC

28 VSS VSS

29 PA20/CASHL NC

30 PA19/BACK/DRAK1 NC

31 PB2/IRQ0/POE0/RAS NC

32 PB3/IRQ1/POE1/CASL NC

33 PA18/BREQ/DRAK0 NC

34 PB4/IRQ2/POE2/CASH A17

35 VSS VSS

36 PB5/IRQ3/POE3/RDWR NC

Table 1.6 Pin Arrangement by Mode for SH7045 (QFP-144 Pin) (cont)

PinNo. MCU Writer mode

37 PB6/IRQ4/A18/BACK NC

38 PB7/IRQ5/A19/BREQ NC

39 PB8/IRQ6/A20/WAIT NC

40 VCC VCC

41 PB9/IRQ7/A21/ADTRG NC

42 VSS VSS

43 PA14/RD NC

44 WDTOVF NC

45 PD31/D31/ADTRG NC

46 PD30/D30/IRQOUT NC

47 PA13/WRH NC

48 PA12/WRL NC

49 PA11/CS1 NC

50 PA10/CS0 NC

51 PA9/TCLKD/IRQ3 CE

52 PA8/TCLKC/IRQ2 OE

53 PA7/TCLKB/CS3 WE

54 PA6/TCLKA/CS2 NC

55 VSS VSS

56 PD29/D29/CS3 NC

57 PD28/D28/CS2 NC

58 PD27/D27/DACK1 NC

59 PD26/D26/DACK0 NC

60 PD25/D25/DREQ1 NC

61 VSS VSS

62 PD24/D24/DREQ0 NC

63 VCC VCC

64 PD23/D23/IRQ7 NC

65 PD22/D22/IRQ6 NC

66 PD21/D21/IRQ5 NC

67 PD20/D20/IRQ4 NC

68 PD19/D19/IRQ3 NC

69 PD18/D18/IRQ2 NC

70 PD17/D17/IRQ1 NC

71 VSS VSS

72 PD16/D16/IRQ0 NC

Table 1.6 Pin Arrangement by Mode for SH7045 (QFP-144 Pin) (cont)

PinNo. MCU Writer mode

73 PD15/D15 NC

74 PD14/D14 NC

75 PD13/D13 NC

76 PD12/D12 NC

77 VCC VCC

78 PD11/D11 NC

79 VSS VSS

80 PD10/D10 NC

81 PD9/D9 NC

82 PD8/D8 NC

83 PD7/D7 D7

84 PD6/D6 D6

85 VCC VCC

86 PD5/D5 D5

87 VSS VSS

88 PD4/D4 D4

89 PD3/D3 D3

90 PD2/D2 D2

91 PD1/D1 D1

92 PD0/D0 D0

93 VSS VSS

94 XTAL XTAL

95 MD3 MD3

96 EXTAL EXTAL

97 MD2 MD2

98 NMI VCC

99 VCC (FWP)*FWE

100 PA16/AH NC

101 PA17/WAIT NC

102 MD1 MD1

103 MD0 MD0

104 PLLVCC PLLVCC

105 PLLCAP PLLCAP

106 PLLVSS PLLVSS

107 PA15/CK NC

Note: *VCC in the mask version; FWP in the F-ZTAT version (however, FWE in the writer mode)

Table 1.6 Pin Arrangement by Mode for SH7045 (QFP-144 Pin) (cont)

PinNo. MCU Writer mode

108 RES RES

109 PE0/TIOC0A/DREQ0 NC

110 PE1/TIOC0B/DRAK0 NC

111 PE2/TIOC0C/DREQ1 NC

112 VCC VCC

113 PE3/TIOC0D/DRAK1 NC

114 PE4/TIOC1A NC

115 PE5/TIOC1B NC

116 PE6/TIOC2A NC

117 VSS VSS

118 PF0/AN0 VSS

119 PF1/AN1 VSS

120 PF2/AN2 VSS

121 PF3/AN3 VSS

122 PF4/AN4 VSS

123 PF5/AN5 VSS

124 AVSS VSS

125 PF6/AN6 VSS

126 PF7/AN7 VSS

127 AVref VCC

128 AVCC VCC

129 VSS VSS

130 PA0/RXD0 NC

131 PA1/TXD0 VCC

132 PA2/SCK0/DREQ0/IRQ0 VCC

133 PA3/RXD1 NC

134 PA4/TXD1 NC

135 VCC VCC

136 PA5/SCK1/DREQ1/IRQ1 VCC

137 PE7/TIOC2B NC

138 PE8/TIOC3A NC

139 PE9/TIOC3B NC

140 PE10/TIOC3C NC

141 VSS VSS

142 PE11/TIOC3D NC

143 PE12/TIOC4A NC

144 PE13/TIOC4B/MRES NC

1.3.3 Pin Functions

Table 1.7 lists the pin functions.

Table 1.7 Pin Functions

Classification Symbol I/O Name Function

Power supply VCC I Supply Connects to power supply.

Connect all VCC pins to the system

supply. No operation will occur if

there are any open pins.

VSS I Ground Connects to ground.

Connect all VSS pins to the system

ground. No operation will occur if

there are any open pins.

VPP I Program

supply Connects to the power supply (VCC)

during normal operation.

When in PROM mode, apply 12.5 V.

Clock PLLVCC I PLL supply On-chip PLL oscillator supply.

PLLVSS I PLL ground On-chip PLL oscillator ground.

PLLCAP I PLL

capacitance On-chip PLL oscillator external

capacitance connection pin.

EXTAL I External clock Connect a crystal oscillator. Also, an

external clock can be input to the

EXTAL pin.

XTAL I Crystal Connect a crystal oscillator.

CK O System clock Supplies the system clock to

peripheral devices.

System control RES I Power-on reset Power-on reset when low

MRES I Manual reset Manual reset when low

WDTOVF O Watchdog

timer overflow Overflow output signal from WDT

BREQ I Bus request Goes low when external device

requests bus right release

BACK O Bus request

acknowledge Indicates that bus right has been

released to external device. The

device that output the BREQ signal

receives the BACK signal, notifying

the device that it has obtained the bus

right.

Table 1.7 Pin Functions (cont)

Classification Symbol I/O Name Function

Operating

mode control MD0–MD3 I Mode set Determines the operating mode. Do

not change input value during

operation.

FWP I Flash memory

write protect Protects flash memory from being

written or deleted.

Interrupts NMI I Non-maskable

interrupt Non-maskable interrupt request pin.

Enables selection of whether to

accept on the rising or falling edge.

IRQ0–

IRQ7 I Interrupt

requests 0–7 Maskable interrupt request pins.

Allows selection of level input and

edge input.

IRQOUT O Interrupt request

output Indicates that interrupt cause has

occurred. Enables notification of

interrupt generation also during bus

release.

Address bus A0–A21 O Address bus Outputs addresses.

Data bus D0–D15

(QFP-112)

D0–D31

(QFP-144)

I/O Data bus 16-bit (QFP-112 pin and TQFP-120

pin versions) or 32-bit (QFP-144 pin

version) bidirectional data bus.

Bus control CS0–CS3 O Chip selects 0–3 Chip select signals for external

memory or devices.

RD O Read Indicates reading from an external

device.

WRH O Upper write Indicates writing the upper 8 bits

(15–8) of external data.

WRL O Lower write Indicates writing the lower 8 bits

(7–0) of external data.

WAIT I Wait Input causes insertion of wait cycles

into the bus cycle during external

space access.

RAS O Row address

strobe Timing signal for DRAM row

address strobe.

CASH O Upper column

address strobe Timing signal for DRAM column

address strobe.

Output when the upper 8 bits of

data are accessed.

Table 1.7 Pin Functions (cont)

Classification Symbol I/O Name Function

Bus control

(cont) CASL O Lower column

address strobe Timing signal for DRAM column

address strobe.

Output when the lower 8 bits of

data are accessed.

RDWR O DRAM

read/write DRAM write strobe signal.

AH O Address hold Address hold timing signal for

devices using an address/data

multiplex bus.

WRHH

(QFP-144) O HH write Indicates the writing of bits 31 to

24 of external data.

WRHL

(QFP-144) O HL write Indicates the writing of bits 23 to

16 of external data.

CASHH

(QFP-144) O HH column

address strobe Timing signal for DRAM column

address strobe. Output when bits

31 to 24 of data are accessed.

CASHL

(QFP-144) O HL column

address strobe Timing signal for DRAM column

address strobe. Output when bits

23 to 16 of data are accessed.

Bus control

multifunction

timer/pulse unit

TCLKA

TCLKB

TCLKC

TCLKD

I MTU timer

clock input Input pins for external clocks to

the MTU counter.

TIOC0A

TIOC0B

TIOC0C

TIOC0D

I/O MTU input

capture/ output

compare

(channel 0)

Channel 0 input capture

input/output compare output/PWM

output pins.

TIOC1A

TIOC1B I/O MTU input

capture/output

compare

(channel 1)

Channel 1 input capture

input/output compare output/PWM

output pins.

TIOC2A

TIOC2B I/O MTU input

capture/output

compare

(channel 2)

Channel 2 input capture

input/output compare output/PWM

output pins.

Table 1.7 Pin Functions (cont)

Classification Symbol I/O Name Function

Bus control

multifunction

timer/pulse unit

(cont)

TIOC3A

TIOC3B

TIOC3C

TIOC3D

I/O MTU input

capture/output

compare

(channel 3)

Channel 3 input capture input/output

compare output/PWM output pins.

TIOC4A

TIOC4B

TIOC4C

TIOC4D

I/O MTU input

capture/output

compare

(channel 4)

Channel 4 input capture input/output

compare output/PWM output pins.

Direct memory

access

controller

(DMAC)

DREQ0–

DREQ1 I DMA transfer

request

(channels 0, 1)

Input pin for external requests for

DMA transfer.

DRAK0–

DRAK1 O DREQ request

acknowledgment

(channels 0, 1)

Output the input sampling

acknowledgment of external DMA

transfer requests.

DACK0–

DACK1 O DMA transfer

strobe (channels

0, 1)

Output a strobe to the external I/O of

external DMA transfer requests.

Serial

communication

interface (SCI)

TxD0–

TxD1 O Transmit data

(channels 0, 1) SCI0, SCI1 transmit data output pins.

(TxD1 is used for data transfer during

boot mode of F-ZTAT)

RxD0–

RxD1 I Receive data

(channels 0, 1) SCI0, SCI1 receive data input pins.

(RxD1 is used for data transfer during

boot mode of F-ZTAT)

SCK0–

SCK1 I/O Serial clock

(channels 0, 1) SCI0, SCI1 clock input/output pins.

A/D Converter AVCC I Analog supply Analog supply; connected to VCC.

AVSS I Analog ground Analog supply; connected to VSS.

AVref

(QFP-144

only)

I Analog reference

supply Analog reference supply input pin.

(Connected to AVCC internally in

QFP-112 and TQFP-120.)

AN0–AN7 I Analog input Analog signal input pins.

ADTRG I A/D conversion

trigger input External trigger input for A/D

conversion start.

Table 1.7 Pin Functions (cont)

Classification Symbol I/O Name Function

I/O ports POE0–

POE3 I Port output

enable Input pin for port pin drive control

when general use ports are

established as output.

PA0–

PA15

(QFP-112)

PA0–

PA23

(QFP-144)

I/O General purpose

port General purpose input/output port

pins.

Each bit can be designated for

input/output.

PB0–PB9 I/O General purpose

port General purpose input/output port

pins.

Each bit can be designated for

input/output.

PC0–

PC15 I/O General purpose

port General purpose input/output port

pins.

Each bit can be designated for

input/output.

PD0–

PD15

(QFP-112)

PD0–

PD31

(QFP-144)

I/O General purpose

port General purpose input/output port

pins.

Each bit can be designated for

input/output.

PE0–

PE15 I/O General purpose

port General purpose input/output port

pins.

Each bit can be designated for

input/output.

PF0–PF7 I General purpose

port General purpose input port pins.

Usage Notes

1. Unused input pins should be pulled up or pulled down.

2. The WDTOVF pin should not be pulled down in the SH7044/SH7045 F-ZTAT version.

However, if it is necessary to pull this pin down, a resistance of 100 kΩ or higher should be

used.

1.4 The F-ZTAT Version Onboard Programming

There are 2 modes on the F-ZTAT version: a mode that writes and overwrites programs using the

special writer and a mode that writes and overwrites programs onboard the application system.

When rebooting after setting each mode pin and FWP pin during the reset condition, the

microcomputer will transfer to one of the modes indicated in figure 1.6. In the user mode, data can

be read from the flash memory but cannot be written or deleted. Use the boot mode and the user

program mode to write to the flash memory or delete data.

In the boot mode, SCI1 (TXD1, RXD1) is used for data transfer. It is possible to automatically

adjust the transfer bit rate to the transfer bit rate of the host.

Table 1.8 Pins during the Onboard Programming Mode

Notation I/O Function

FWP Input Hardware protected flash memory write/delete

MD1 Input User programming mode/boot mode setting

MD2 Input Clock mode (PLL) setting

MD3 Input Clock mode (PLL) setting

TxD1 Output Serial sent data output

RxD1 Input Serial receive data input

User mode

Power-on 

reset condition

User 

program 

mode

Boot mode

Onboard programming mode

FWP=1

MD1=1, FWP=1

RES=0

MD1=1, FWP=0

RES=0

FWP=0

MD1=1, FWP=0

RES=0

Notes: For transferring between user mode and user program mode,



proceed while CPU is not programming or erasing the flash 

memory.

* RAM emulation permitted

Figure 1.6 Condition Transfer for Flash Memory

<Host>

Write control program

Write control

program area

Boot program area

Application program

<SH7044/45> RXD1 TXD1

Boot program

SCI 1

Figure. 1.7 Data Transfer during Boot Mode

Section 2 CPU

2.1 Register Configuration

The register set consists of sixteen 32-bit general registers, three 32-bit control registers and four

32-bit system registers.

2.1.1 General Registers (Rn)

The sixteen 32-bit general registers (Rn) are numbered R0–R15. General registers are used for

data processing and address calculation. R0 is also used as an index register. Several instructions

have R0 fixed as their only usable register. R15 is used as the hardware stack pointer (SP). Saving

and recovering the status register (SR) and program counter (PC) in exception processing is

accomplished by referencing the stack using R15. Figure 2.1 shows the general registers.

R0*1

R10

R11

R12

R13

R14

R15, SP (hardware stack pointer)*2

031

R0 functions as an index register in the indirect indexed register addressing

mode and indirect indexed GBR addressing mode. In some instructions, R0

functions as a fixed source register or destination register.

R15 functions as a hardware stack pointer (SP) during exception processing.

Notes:

Figure 2.1 General Registers

2.1.2 Control Registers

The 32-bit control registers consist of the 32-bit status register (SR), global base register (GBR),

and vector base register (VBR). The status register indicates processing states. The global base

registers of on-chip peripheral modules. The vector base register functions as the base address of

the exception processing vector area (including interrupts). Figure 2.2 shows a control register.

9876543210

MQI 3 I2 I1 I0 ST

031

31 GBR

VBR

SR31

S bit: Used by the MAC instruction.

Reserved bits. This bit always read 0. 

The write value should always be 0.

Reserved bits. 0 is read. Write only.

Bits I0–I3: Interrupt mask bits.

M and Q bits: Used by the DIV0U, DIV0S,

and DIV1 instructions.

Global base register (GBR):

Indicates the base address of the indirect 

GBR addressing mode. The indirect GBR 

addressing mode is used in data transfer

for on-chip peripheral modules register

areas and in logic operations.

Vector base register (VBR):

Stores the base address of the exception

processing vector area.

SR: Status register

T bit: The MOVT, CMP/cond, TAS, TST, 

BT (BT/S), BF (BF/S), SETT, and CLRT



instructions use the T bit to indicate true



(1) or false (0). The ADDV, ADDC,

SUBV, SUBC, DIV0U, DIV0S, DIV1,

NEGC, SHAR, SHAL, SHLR, SHLL,

ROTR, ROTL, ROTCR, and ROTCL

instructions also use the T bit to indicate



carry/borrow or overflow/underflow.

Figure 2.2 Control Registers

2.1.3 System Registers

System registers consist of four 32-bit registers: high and low multiply and accumulate registers

(MACH and MACL), the procedure register (PR), and the program counter (PC). The multiply

and accumulate registers store the results of multiply and accumulate operations. The procedure

program addresses to control the flow of the processing. Figure 2.3 shows a system register.

MACL

MACH

31 0

Multiply and accumulate (MAC)

registers high and low (MACH, 

MACL): Stores the results of 

multiply and accumulate operations.

Procedure register (PR): Stores 

a return address from a 

subroutine procedure.

Program counter (PC): Indicates 

the fourth byte (second instruction)



after the current instruction.

Figure 2.3 System Registers

2.1.4 Initial Values of Registers

Table 2.1 lists the values of the registers after reset.

Table 2.1 Initial Values of Registers

Classification Register Initial Value

General registers R0–R14 Undefined

R15 (SP) Value of the stack pointer in the vector address table

Control registers SR Bits I3–I0 are 1111 (H'F), reserved bits are 0, and other

bits are undefined

GBR Undefined

VBR H'00000000

System registers MACH, MACL, PR Undefined

PC Value of the program counter in the vector address table

2.2 Data Formats

2.2.1 Data Format in Registers

bits) or a word (16 bits), it is sign-extended into a longword when loaded into a register (figure

2.4).

31 0

Longword

Figure 2.4 Longword Operand

2.2.2 Data Format in Memory

Memory data formats are classified into bytes, words, and longwords. Byte data can be accessed

from any address, but an address error will occur if you try to access word data starting from an

address other than 2n or longword data starting from an address other than 4n. In such cases, the

data accessed cannot be guaranteed. The hardware stack area, referred to by the hardware stack

pointer (SP, R15), uses only longword data starting from address 4n because this area holds the

program counter and status register (figure 2.5).

31 015

23 7

Byte Byte Byte Byte

WordWord

Address 2n

Address 4n Longword

Address m Address m + 2

Address m + 1 Address m + 3

Figure 2.5 Byte, Word, and Longword Alignment

2.2.3 Immediate Data Format

Byte (8-bit) immediate data resides in an instruction code. Immediate data accessed by the MOV,

ADD, and CMP/EQ instructions is sign-extended and handled in registers as longword data.

Immediate data accessed by the TST, AND, OR, and XOR instructions is zero-extended and

handled as longword data. Consequently, AND instructions with immediate data always clear the

upper 24-bits of the destination register.

Word or longword immediate data is not located in the instruction code, but instead is stored in a

memory table. An immediate data transfer instruction (MOV) accesses the memory table using the

PC relative addressing mode with displacement.

2.3 Instruction Features

2.3.1 RISC-Type Instruction Set

All instructions are RISC type. This section details their functions.

16-Bit Fixed Length: All instructions are 16 bits long, increasing program code efficiency.

One Instruction per Cycle: The microprocessor can execute basic instructions in one cycle using

the pipeline system. Instructions are executed in 35 ns at 28.7 MHz.

Data Length: Longword is the standard data length for all operations. Memory can be accessed in

bytes, words, or longwords. Byte or word data accessed from memory is sign-extended and

handled as longword data. Immediate data is sign-extended for arithmetic operations or zero-

extended for logic operations. It also is handled as longword data (table 2.2).

Table 2.2 Sign Extension of Word Data

SH7040 Series CPU Description Example of Conventional CPU

MOV.W @(disp,PC),R1

ADD R1,R0

.........

.DATA.W H'1234

Data is sign-extended to 32

bits, and R1 becomes

H'00001234. It is next

operated upon by an ADD

instruction.

ADD.W #H'1234,R0

Note: @(disp, PC) accesses the immediate data.

Load-Store Architecture: Basic operations are executed between registers. For operations that

involve memory access, data is loaded to the registers and executed (load-store architecture).

Instructions such as AND that manipulate bits, however, are executed directly in memory.

Delayed Branch Instructions: Unconditional branch instructions are delayed. Executing the

instruction that follows the branch instruction and then branching reduces pipeline disruption

during branching (table 2.3). There are two types of conditional branch instructions: delayed

branch instructions and ordinary branch instructions.

Table 2.3 Delayed Branch Instructions

SH7040 Series CPU Description Example of Conventional CPU

BRA TRGET

ADD R1,R0

Executes an ADD before

branching to TRGET ADD.W R1,R0

BRA TRGET

Multiplication/Accumulation Operation: 16-bit × 16-bit → 32-bit multiplication operations are

executed in one to two cycles. 16-bit × 16-bit + 64-bit → 64-bit multiplication/accumulation

operations are executed in two to three cycles. 32-bit × 32-bit → 64-bit and 32-bit × 32-bit + 64-

bit → 64-bit multiplication/accumulation operations are executed in two to four cycles.

T Bit: The T bit in the status register changes according to the result of the comparison, and in

turn is the condition (true/false) that determines if the program will branch. The number of

instructions that change the T bit is kept to a minimum to improve the processing speed (table

2.4).

Table 2.4 T Bit

SH7040 Series CPU Description Example of Conventional CPU

CMP/GE R1,R0

BT TRGET0

BF TRGET1

T bit is set when R0 ≥ R1. The

program branches to TRGET0

when R0 ≥ R1 and to TRGET1

when R0 < R1.

CMP.W R1,R0

BGE TRGET0

BLT TRGET1

ADD #1,R0

CMP/EQ #0,R0

BT TRGET

T bit is not changed by ADD. T bit is

set when R0 = 0. The program

branches if R0 = 0.

SUB.W #1,R0

BEQ TRGET

Immediate Data: Byte (8-bit) immediate data resides in instruction code. Word or longword

immediate data is not input via instruction codes but is stored in a memory table. An immediate

data transfer instruction (MOV) accesses the memory table using the PC relative addressing mode

with displacement (table 2.5).

Table 2.5 Immediate Data Accessing

Classification SH7040 Series CPU Example of Conventional CPU

8-bit immediate MOV #H'12,R0 MOV.B #H'12,R0

16-bit immediate MOV.W @(disp,PC),R0

.................

.DATA.W H'1234

MOV.W #H'1234,R0

32-bit immediate MOV.L @(disp,PC),R0

.................

.DATA.L H'12345678

MOV.L #H'12345678,R0

Note: @(disp, PC) accesses the immediate data.

Absolute Address: When data is accessed by absolute address, the value already in the absolute

address is placed in the memory table. Loading the immediate data when the instruction is

executed transfers that value to the register and the data is accessed in the indirect register

addressing mode (table 2.6).

Table 2.6 Absolute Address Accessing

Classification SH7040 Series CPU Example of Conventional CPU

Absolute address MOV.L @(disp,PC),R1

MOV.B @R1,R0

..................

.DATA.L H'12345678

MOV.B @H'12345678,R0

Note: @(disp,PC) accesses the immediate data.

16-Bit/32-Bit Displacement: When data is accessed by 16-bit or 32-bit displacement, the pre-

existing displacement value is placed in the memory table. Loading the immediate data when the

instruction is executed transfers that value to the register and the data is accessed in the indirect

indexed register addressing mode (table 2.7).

Table 2.7 Displacement Accessing

Classification SH7040 Series CPU Example of Conventional CPU

16-bit displacement MOV.W @(disp,PC),R0

MOV.W @(R0,R1),R2

..................

.DATA.W H'1234

MOV.W @(H'1234,R1),R2

Note: @(disp,PC) accesses the immediate data.

2.3.2 Addressing Modes

Table 2.8 describes addressing modes and effective address calculation.

Table 2.8 Addressing Modes and Effective Addresses

Addressing

Mode Instruction

Format Effective Addresses Calculation Equation

Direct register

addressing Rn The effective address is register Rn. (The operand

is the contents of register Rn.) —

Indirect register

addressing @Rn The effective address is the content of register Rn.

Rn Rn

Post-increment

indirect register

addressing

@Rn+ The effective address is the content of register Rn.

A constant is added to the content of Rn after the

instruction is executed. 1 is added for a byte

operation, 2 for a word operation, and 4 for a

longword operation.

Rn Rn

1/2/4

Rn + 1/2/4

(After the

instruction

executes)

Byte: Rn + 1

→ Rn

Word: Rn + 2

→ Rn

Longword:

Rn + 4 → Rn

Pre-decrement

indirect register

addressing

@–Rn The effective address is the value obtained by

subtracting a constant from Rn. 1 is subtracted for

a byte operation, 2 for a word operation, and 4 for

a longword operation.

1/2/4

Rn – 1/2/4

–

Rn – 1/2/4

Byte: Rn – 1

→ Rn

Word: Rn – 2

→ Rn

Longword:

Rn – 4 → Rn

(Instruction

executed with

Rn after

calculation)

Table 2.8 Addressing Modes and Effective Addresses (cont)

Addressing

Mode Instruction

Format Effective Addresses Calculation Equation

Indirect register

addressing with

displacement

@(disp:4,

Rn) The effective address is Rn plus a 4-bit

displacement (disp). The value of disp is zero-

extended, and remains the same for a byte

operation, is doubled for a word operation, and is

quadrupled for a longword operation.

Rn + disp × 1/2/4

1/2/4

disp

(zero-extended)

Byte: Rn +

disp

Word: Rn +

disp × 2

Longword: Rn

+ disp × 4

Indirect indexed

addressing

@(R0, Rn) The effective address is the Rn value plus R0.

Rn + R0

Indirect GBR

addressing with

displacement

@(disp:8,

GBR) The effective address is the GBR value plus an

8-bit displacement (disp). The value of disp is zero-

extended, and remains the same for a byte opera-

tion, is doubled for a word operation, and is

quadrupled for a longword operation.

GBR

1/2/4

GBR

+ disp × 1/2/4

disp

(zero-extended)

Byte: GBR +

disp

Word: GBR +

disp × 2

Longword:

GBR + disp ×

Table 2.8 Addressing Modes and Effective Addresses (cont)

Addressing

Mode Instruction

Format Effective Addresses Calculation Equation

Indirect indexed

GBR addressing @(R0, GBR) The effective address is the GBR value plus the R0.

GBR

GBR + R0

PC relative

addressing with

displacement

@(disp:8,

PC) The effective address is the PC value plus an 8-bit

displacement (disp). The value of disp is zero-

extended, and is doubled for a word operation, and

quadrupled for a longword operation. For a

longword operation, the lowest two bits of the PC

value are masked.

H'FFFFFFFC PC + disp × 2

or

PC & H'FFFFFFFC



+ disp × 4

2/4

&(for longword)

disp

(zero-extended)

Word: PC +

disp × 2

Longword:

PC &

H'FFFFFFFC

+ disp × 4

Table 2.8 Addressing Modes and Effective Addresses (cont)

Addressing

Mode Instruction

Format Effective Addresses Calculation Equation

PC relative

addressing disp:8 The effective address is the PC value sign-extended

with an 8-bit displacement (disp), doubled, and

added to the PC value.

disp

(sign-extended) PC + disp × 2

PC + disp × 2

disp:12 The effective address is the PC value sign-extended

with a 12-bit displacement (disp), doubled, and

added to the PC value.

disp

(sign-extended) PC + disp × 2

PC + disp × 2

Rn The effective address is the register PC value

plus Rn.

PC + Rn

Immediate

addressing #imm:8 The 8-bit immediate data (imm) for the TST, AND,

OR, and XOR instructions are zero-extended. —

#imm:8 The 8-bit immediate data (imm) for the MOV, ADD,

and CMP/EQ instructions are sign-extended. —

#imm:8 The 8-bit immediate data (imm) for the TRAPA

instruction is zero-extended and is quadrupled. —

2.3.3 Instruction Format

Table 2.9 lists the instruction formats for the source operand and the destination operand. The

meaning of the operand depends on the instruction code. The symbols are used as follows:

• xxxx: Instruction code

• mmmm: Source register

• nnnn: Destination register

• iiii: Immediate data

• dddd: Displacement

Table 2.9 Instruction Formats

Instruction Formats Source

Operand Destination

Operand Example

0 format

xxxx xxxx xxxxxxxx

15 0 —— NOP

n format — nnnn: Direct

xxxx xxxx xxxxnnnn

15 0 Control register

or system

nnnn: Direct

Control register

or system

nnnn: Indirect pre-

decrement register STC.L SR,@-Rn

m format mmmm: Direct

system register LDC Rm,SR

xxxx

mmmm

xxxx xxxx

15 0 mmmm: Indirect

post-increment

Control register or

system register LDC.L @Rm+,SR

mmmm: Direct

mmmm: PC

relative using Rm —BRAF Rm

Table 2.9 Instruction Formats (cont)

Instruction Formats Source Operand Destination

Operand Example

nm format mmmm: Direct

nnnn

xxxx xxxx

15 0

mmmm mmmm: Direct

mmmm: Indirect

post-increment

accumulate)

nnnn*: Indirect

post-increment

accumulate)

MACH, MACL MAC.W

@Rm+,@Rn+

mmmm: Indirect

post-increment

nnnn: Direct

mmmm: Direct

decrement

MOV.L Rm,@-Rn

mmmm: Direct

indexed register MOV.L

Rm,@(R0,Rn)

md format

xxxx dddd

15 0

mmmm

xxxx

mmmmdddd:

indirect register

with

displacement

R0 (Direct

@(disp,Rm),R0

nd4 format

xxxx

xxxx dddd

15 0

nnnn

R0 (Direct

Indirect register

with displacement

MOV.B

R0,@(disp,Rn)

nmd format

nnnn

xxxx dddd

15 0

mmmm

mmmm: Direct

displacement

MOV.L

Rm,@(disp,Rn)

mmmmdddd:

Indirect register

with

displacement

nnnn: Direct

@(disp,Rm),Rn

Note: * In multiply/accumulate instructions, nnnn is the source register.

Table 2.9 Instruction Formats (cont)

Instruction Formats Source Operand Destination

Operand Example

d format

dddd

xxxx

15 0

xxxx dddd

dddddddd:

Indirect GBR

with

displacement

R0 (Direct register) MOV.L

@(disp,GBR),R0

R0(Direct

GBR with

displacement

MOV.L

R0,@(disp,GBR)

dddddddd: PC

relative with

displacement

R0 (Direct register) MOVA

@(disp,PC),R0

dddddddd: PC

relative —BF label

d12 format

dddd

xxxx

15 0

dddd dddd

dddddddddddd:

PC relative —BRA label

(label = disp +

PC)

nd8 format

dddd

nnnn

xxxx

15 0

dddd

dddddddd: PC

relative with

displacement

nnnn: Direct

@(disp,PC),Rn

i format iiiiiiii: Immediate Indirect indexed

GBR AND.B

#imm,@(R0,GBR)

xxxxxxxx i i i i

15 0

i i i i iiiiiiii: Immediate R0 (Direct register) AND #imm,R0

iiiiiiii: Immediate — TRAPA #imm

ni format

nnnn i i i i

xxxx

15 0

i i i i

iiiiiiii: Immediate nnnn: Direct

2.4 Instruction Set by Classification

Table 2.10 Classification of Instructions

Classification Types Operation

Code Function No. of

Instructions

Data transfer 5 MOV Data transfer, immediate data transfer,

peripheral module data transfer, structure data

transfer

MOVA Effective address transfer

MOVT T bit transfer

SWAP Swap of upper and lower bytes

XTRCT Extraction of the middle of registers connected

Arithmetic 21 ADD Binary addition 33

operations ADDC Binary addition with carry

ADDV Binary addition with overflow check

CMP/cond Comparison

DIV1 Division

DIV0S Initialization of signed division

DIV0U Initialization of unsigned division

DMULS Signed double-length multiplication

DMULU Unsigned double-length multiplication

DT Decrement and test

EXTS Sign extension

EXTU Zero extension

MAC Multiply/accumulate, double-length

multiply/accumulate operation

MUL Double-length multiply operation

MULS Signed multiplication

MULU Unsigned multiplication

NEG Negation

NEGC Negation with borrow

SUB Binary subtraction

SUBC Binary subtraction with borrow

SUBV Binary subtraction with underflow

Table 2.10 Classification of Instructions (cont)

Classification Types Operation

Code Function No. of

Instructions

Logic 6 AND Logical AND 14

operations NOT Bit inversion

OR Logical OR

TAS Memory test and bit set

TST Logical AND and T bit set

XOR Exclusive OR

Shift 10 ROTL One-bit left rotation 14

ROTR One-bit right rotation

ROTCL One-bit left rotation with T bit

ROTCR One-bit right rotation with T bit

SHAL One-bit arithmetic left shift

SHAR One-bit arithmetic right shift

SHLL One-bit logical left shift

SHLLn n-bit logical left shift

SHLR One-bit logical right shift

SHLRn n-bit logical right shift

Branch 9 BF Conditional branch, conditional branch with

delay (Branch when T = 0) 11

BT Conditional branch, conditional branch with

delay (Branch when T = 1)

BRA Unconditional branch

BRAF Unconditional branch

BSR Branch to subroutine procedure

BSRF Branch to subroutine procedure

JMP Unconditional branch

JSR Branch to subroutine procedure

RTS Return from subroutine procedure

Table 2.10 Classification of Instructions (cont)

Classification Types Operation

Code Function No. of

Instructions

System 11 CLRT T bit clear 31

control CLRMAC MAC register clear

LDC Load to control register

LDS Load to system register

NOP No operation

RTE Return from exception processing

SETT T bit set

SLEEP Shift into power-down mode

STC Storing control register data

STS Storing system register data

TRAPA Trap exception handling

Total: 62 142

Table 2.11 shows the format used in tables 2.12 to 2.17, which list instruction codes, operation,

and execution states in order by classification.

Table 2.11 Instruction Code Format

Item Format Explanation

Instruction OP.Sz SRC,DEST OP: Operation code

Sz: Size (B: byte, W: word, or L: longword)

SRC: Source

DEST: Destination

Rm: Source register

Rn: Destination register

imm: Immediate data

disp: Displacement*1

Instruction

code MSB ↔ LSB mmmm: Source register

nnnn: Destination register

0000: R0

0001: R1 .

1111: R15

iiii: Immediate data

dddd: Displacement

Operation →, ←Direction of transfer

(xx) Memory operand

M/Q/T Flag bits in the SR

& Logical AND of each bit

| Logical OR of each bit

^ Exclusive OR of each bit

~ Logical NOT of each bit

<<n n-bit left shift

>>n n-bit right shift

Execution

cycles — Value when no wait states are inserted*2

T bit — Value of T bit after instruction is executed. An em-dash (—)

in the column means no change.

Notes: *1 Depending on the operand size, displacement is scaled ×1, ×2, or ×4. For details, see

the SH-1/SH-2/SH-DSP Programming Manual.

*2 Instruction execution cycles: The execution cycles shown in the table are minimums.

The actual number of cycles may be increased when (1) contention occurs between

instruction fetches and data access, or (2) when the destination register of the load

instruction (memory → register) and the register used by the next instruction are the

same.

Table 2.12 Data Transfer Instructions

Instruction Instruction Code Operation

Execu-

tion

Cycles T

Bit

MOV #imm,Rn 1110nnnniiiiiiii #imm → Sign extension →

Rn 1—

MOV.W @(disp,PC),Rn 1001nnnndddddddd (disp × 2 + PC) → Sign

extension → Rn 1—

MOV.L @(disp,PC),Rn 1101nnnndddddddd (disp × 4 + PC) → Rn 1 —

MOV Rm,Rn 0110nnnnmmmm0011 Rm → Rn 1 —

MOV.B Rm,@Rn 0010nnnnmmmm0000 Rm → (Rn) 1 —

MOV.W Rm,@Rn 0010nnnnmmmm0001 Rm → (Rn) 1 —

MOV.L Rm,@Rn 0010nnnnmmmm0010 Rm → (Rn) 1 —

MOV.B @Rm,Rn 0110nnnnmmmm0000 (Rm) → Sign extension →

Rn 1—

MOV.W @Rm,Rn 0110nnnnmmmm0001 (Rm) → Sign extension →

Rn 1—

MOV.L @Rm,Rn 0110nnnnmmmm0010 (Rm) → Rn 1 —

MOV.B Rm,@–Rn 0010nnnnmmmm0100 Rn–1 → Rn, Rm → (Rn) 1 —

MOV.W Rm,@–Rn 0010nnnnmmmm0101 Rn–2 → Rn, Rm → (Rn) 1 —

MOV.L Rm,@–Rn 0010nnnnmmmm0110 Rn–4 → Rn, Rm → (Rn) 1 —

MOV.B @Rm+,Rn 0110nnnnmmmm0100 (Rm) → Sign extension →

Rn,Rm + 1 → Rm 1—

MOV.W @Rm+,Rn 0110nnnnmmmm0101 (Rm) → Sign extension →

Rn,Rm + 2 → Rm 1—

MOV.L @Rm+,Rn 0110nnnnmmmm0110 (Rm) → Rn,Rm + 4 → Rm 1 —

MOV.B R0,@(disp,Rn) 10000000nnnndddd R0 → (disp + Rn) 1 —

MOV.W R0,@(disp,Rn) 10000001nnnndddd R0 → (disp × 2 + Rn) 1 —

MOV.L Rm,@(disp,Rn) 0001nnnnmmmmdddd Rm → (disp × 4 + Rn) 1 —

MOV.B @(disp,Rm),R0 10000100mmmmdddd (disp + Rm) → Sign

extension → R0 1—

MOV.W @(disp,Rm),R0 10000101mmmmdddd (disp × 2 + Rm) → Sign

extension → R0 1—

MOV.L @(disp,Rm),Rn 0101nnnnmmmmdddd (disp × 4 + Rm) → Rn 1 —

MOV.B Rm,@(R0,Rn) 0000nnnnmmmm0100 Rm → (R0 + Rn) 1 —

Table 2.12 Data Transfer Instructions (cont)

Instruction Instruction Code Operation

Execu-

tion

Cycles T

Bit

MOV.W Rm,@(R0,Rn) 0000nnnnmmmm0101 Rm → (R0 + Rn) 1 —

MOV.L Rm,@(R0,Rn) 0000nnnnmmmm0110 Rm → (R0 + Rn) 1 —

MOV.B @(R0,Rm),Rn 0000nnnnmmmm1100 (R0 + Rm) → Sign

extension → Rn 1—

MOV.W @(R0,Rm),Rn 0000nnnnmmmm1101 (R0 + Rm) → Sign

extension → Rn 1—

MOV.L @(R0,Rm),Rn 0000nnnnmmmm1110 (R0 + Rm) → Rn 1 —

MOV.B R0,@(disp,GBR) 11000000dddddddd R0 → (disp + GBR) 1 —

MOV.W R0,@(disp,GBR) 11000001dddddddd R0 → (disp × 2 + GBR) 1 —

MOV.L R0,@(disp,GBR) 11000010dddddddd R0 → (disp × 4 + GBR) 1 —

MOV.B @(disp,GBR),R0 11000100dddddddd (disp + GBR) → Sign

extension → R0 1—

MOV.W @(disp,GBR),R0 11000101dddddddd (disp × 2 + GBR) → Sign

extension → R0 1—

MOV.L @(disp,GBR),R0 11000110dddddddd (disp × 4 + GBR) → R0 1 —

MOVA @(disp,PC),R0 11000111dddddddd disp × 4 + PC → R0 1 —

MOVT Rn 0000nnnn00101001 T → Rn 1 —

SWAP.B Rm,Rn 0110nnnnmmmm1000 Rm → Swap the bottom two

bytes → Rn 1—

SWAP.W Rm,Rn 0110nnnnmmmm1001 Rm → Swap two

consecutive words → Rn 1—

XTRCT Rm,Rn 0010nnnnmmmm1101 Rm: Middle 32 bits of

Rn → Rn 1—

Table 2.13 Arithmetic Operation Instructions

Instruction Instruction Code Operation

Execu-

tion

Cycles T Bit

ADD Rm,Rn 0011nnnnmmmm1100 Rn + Rm → Rn 1 —

ADD #imm,Rn 0111nnnniiiiiiii Rn + imm → Rn 1 —

ADDC Rm,Rn 0011nnnnmmmm1110 Rn + Rm + T → Rn,

Carry → T 1 Carry

ADDV Rm,Rn 0011nnnnmmmm1111 Rn + Rm → Rn,

Overflow → T 1 Overflow

CMP/EQ #imm,R0 10001000iiiiiiii If R0 = imm, 1 → T 1 Comparison

result

CMP/EQ Rm,Rn 0011nnnnmmmm0000 If Rn = Rm, 1 → T 1 Comparison

result

CMP/HS Rm,Rn 0011nnnnmmmm0010 If Rn≥Rm with unsigned

data, 1 → T 1 Comparison

result

CMP/GE Rm,Rn 0011nnnnmmmm0011 If Rn ≥ Rm with signed

data, 1 → T 1 Comparison

result

CMP/HI Rm,Rn 0011nnnnmmmm0110 If Rn > Rm with

unsigned data, 1 → T 1 Comparison

result

CMP/GT Rm,Rn 0011nnnnmmmm0111 If Rn > Rm with signed

data, 1 → T 1 Comparison

result

CMP/PL Rn 0100nnnn00010101 If Rn > 0, 1 → T 1 Comparison

result

CMP/PZ Rn 0100nnnn00010001 If Rn ≥ 0, 1 → T 1 Comparison

result

CMP/STR Rm,Rn 0010nnnnmmmm1100 If Rn and Rm have

an equivalent byte,

1 → T

1 Comparison

result

DIV1 Rm,Rn 0011nnnnmmmm0100 Single-step division

(Rn/Rm) 1 Calculation

result

DIV0S Rm,Rn 0010nnnnmmmm0111 MSB of Rn → Q, MSB

of Rm → M, M ^ Q → T 1 Calculation

result

DIV0U 0000000000011001 0 → M/Q/T 1 0

Table 2.13 Arithmetic Operation Instructions (cont)

Instruction Instruction Code Operation

Execu-

tion

Cycles T Bit

DMULS.L Rm,Rn 0011nnnnmmmm1101 Signed operation of Rn

× Rm → MACH, MACL

32 × 32 → 64 bit

2 to 4*—

DMULU.L Rm,Rn 0011nnnnmmmm0101 Unsigned operation of

Rn × Rm → MACH,

MACL 32 × 32 → 64 bit

2 to 4*—

DT Rn 0100nnnn00010000 Rn – 1 → Rn, when Rn

is 0, 1 → T. When Rn is

nonzero, 0 → T

1 Comparison

result

EXTS.B Rm,Rn 0110nnnnmmmm1110 A byte in Rm is sign-

extended → Rn 1—

EXTS.W Rm,Rn 0110nnnnmmmm1111 A word in Rm is sign-

extended → Rn 1—

EXTU.B Rm,Rn 0110nnnnmmmm1100 A byte in Rm is zero-

extended → Rn 1—

EXTU.W Rm,Rn 0110nnnnmmmm1101 A word in Rm is zero-

extended → Rn 1—

MAC.L @Rm+,@Rn+ 0000nnnnmmmm1111 Signed operation of

(Rn) × (Rm) + MAC →

MAC 32 × 32 → 64 bit

3/(2 to

4)*—

MAC.W @Rm+,@Rn+ 0100nnnnmmmm1111 Signed operation of

(Rn) × (Rm) + MAC →

MAC 16 × 16 + 64 →

64 bit

3/(2)*—

MUL.L Rm,Rn 0000nnnnmmmm0111 Rn × Rm → MACL, 32

× 32 → 32 bit 2 to 4*—

MULS.W Rm,Rn 0010nnnnmmmm1111 Signed operation of Rn

× Rm → MAC 16 × 16

→ 32 bit

1 to 3*—

MULU.W Rm,Rn 0010nnnnmmmm1110 Unsigned operation of

Rn × Rm → MAC 16 ×

16 → 32 bit

1 to 3*—

NEG Rm,Rn 0110nnnnmmmm1011 0–Rm → Rn 1 —

NEGC Rm,Rn 0110nnnnmmmm1010 0–Rm–T → Rn, Borrow

→ T 1 Borrow

Table 2.13 Arithmetic Operation Instructions (cont)

Instruction Instruction Code Operation

Execu-

tion

Cycles T Bit

SUB Rm,Rn 0011nnnnmmmm1000 Rn–Rm → Rn 1 —

SUBC Rm,Rn 0011nnnnmmmm1010 Rn–Rm–T → Rn,

Borrow → T 1 Borrow

SUBV Rm,Rn 0011nnnnmmmm1011 Rn–Rm → Rn,

Underflow → T 1 Overflow

Note: *The normal minimum number of execution cycles. (The number in parentheses is the

number of cycles when there is contention with following instructions.)

Table 2.14 Logic Operation Instructions

Instruction Instruction Code Operation

Execu-

tion

Cycles T Bit

AND Rm,Rn 0010nnnnmmmm1001 Rn & Rm → Rn 1 —

AND #imm,R0 11001001iiiiiiii R0 & imm → R0 1 —

AND.B #imm,@(R0,GBR) 11001101iiiiiiii (R0 + GBR) & imm →

(R0 + GBR) 3—

NOT Rm,Rn 0110nnnnmmmm0111 ~Rm → Rn 1 —

OR Rm,Rn 0010nnnnmmmm1011 Rn | Rm → Rn 1 —

OR #imm,R0 11001011iiiiiiii R0 | imm → R0 1 —

OR.B #imm,@(R0,GBR) 11001111iiiiiiii (R0 + GBR) | imm →

(R0 + GBR) 3—

TAS.B @Rn 0100nnnn00011011 If (Rn) is 0, 1 → T; 1 →

MSB of (Rn)*4 Test

result

TST Rm,Rn 0010nnnnmmmm1000 Rn & Rm; if the result is

0, 1 → T 1 Test

result

TST #imm,R0 11001000iiiiiiii R0 & imm; if the result is

0, 1 → T 1 Test

result

TST.B #imm,@(R0,GBR) 11001100iiiiiiii (R0 + GBR) & imm; if

the result is 0, 1 → T 3 Test

result

XOR Rm,Rn 0010nnnnmmmm1010 Rn ^ Rm → Rn 1 —

XOR #imm,R0 11001010iiiiiiii R0 ^ imm → R0 1 —

XOR.B #imm,@(R0,GBR) 11001110iiiiiiii (R0 + GBR) ^ imm →

(R0 + GBR) 3—

Note: *The on-chip DMAC/DTC bus cycles are not inserted between the read and write cycles of

TAS instruction execution. However, bus release due to BREQ is carried out.

Table 2.15 Shift Instructions

Instruction Instruction Code Operation

Execu-

tion

Cycles T Bit

ROTL Rn 0100nnnn00000100 T ← Rn ← MSB 1 MSB

ROTR Rn 0100nnnn00000101 LSB → Rn → T 1 LSB

ROTCL Rn 0100nnnn00100100 T ← Rn ← T 1 MSB

ROTCR Rn 0100nnnn00100101 T → Rn → T 1 LSB

SHAL Rn 0100nnnn00100000 T ← Rn ← 0 1 MSB

SHAR Rn 0100nnnn00100001 MSB → Rn → T 1 LSB

SHLL Rn 0100nnnn00000000 T ← Rn ← 0 1 MSB

SHLR Rn 0100nnnn00000001 0 → Rn → T 1 LSB

SHLL2 Rn 0100nnnn00001000 Rn<<2 → Rn 1 —

SHLR2 Rn 0100nnnn00001001 Rn>>2 → Rn 1 —

SHLL8 Rn 0100nnnn00011000 Rn<<8 → Rn 1 —

SHLR8 Rn 0100nnnn00011001 Rn>>8 → Rn 1 —

SHLL16 Rn 0100nnnn00101000 Rn<<16 → Rn 1 —

SHLR16 Rn 0100nnnn00101001 Rn>>16 → Rn 1 —

Table 2.16 Branch Instructions

Instruction Instruction Code Operation Exec.

Cycles T

Bit

BF label 10001011dddddddd If T = 0, disp × 2 + PC → PC; if T =

1, nop 3/1*—

BF/S label 10001111dddddddd Delayed branch, if T = 0, disp × 2 +

PC → PC; if T = 1, nop 2/1*—

BT label 10001001dddddddd If T = 1, disp × 2 + PC → PC; if T =

0, nop 3/1*—

BT/S label 10001101dddddddd Delayed branch, if T = 1, disp × 2 +

PC → PC; if T = 0, nop 2/1*—

BRA label 1010dddddddddddd Delayed branch, disp × 2 + PC →

PC 2—

BRAF Rm 0000mmmm00100011 Delayed branch, Rm + PC → PC 2 —

BSR label 1011dddddddddddd Delayed branch, PC → PR, disp × 2

+ PC → PC 2—

BSRF Rm 0000mmmm00000011 Delayed branch, PC → PR,

Rm + PC → PC 2—

JMP @Rm 0100mmmm00101011 Delayed branch, Rm → PC 2 —

JSR @Rm 0100mmmm00001011 Delayed branch, PC → PR,

Rm → PC 2—

RTS 0000000000001011 Delayed branch, PR → PC 2 —

Note: *One state when it does not branch.

Table 2.17 System Control Instructions

Instruction Instruction Code Operation Exec.

Cycles T Bit

CLRT 0000000000001000 0 → T 1 0

CLRMAC 0000000000101000 0 → MACH, MACL 1 —

LDC Rm,SR 0100mmmm00001110 Rm → SR 1 LSB

LDC Rm,GBR 0100mmmm00011110 Rm → GBR 1 —

LDC Rm,VBR 0100mmmm00101110 Rm → VBR 1 —

LDC.L @Rm+,SR 0100mmmm00000111 (Rm) → SR, Rm + 4 → Rm 3 LSB

LDC.L @Rm+,GBR 0100mmmm00010111 (Rm) → GBR, Rm + 4 → Rm 3 —

LDC.L @Rm+,VBR 0100mmmm00100111 (Rm) → VBR, Rm + 4 → Rm 3 —

LDS Rm,MACH 0100mmmm00001010 Rm → MACH 1 —

LDS Rm,MACL 0100mmmm00011010 Rm → MACL 1 —

LDS Rm,PR 0100mmmm00101010 Rm → PR 1 —

LDS.L @Rm+,MACH 0100mmmm00000110 (Rm) → MACH, Rm + 4 → Rm 1 —

LDS.L @Rm+,MACL 0100mmmm00010110 (Rm) → MACL, Rm + 4 → Rm 1 —

LDS.L @Rm+,PR 0100mmmm00100110 (Rm) → PR, Rm + 4 → Rm 1 —

NOP 0000000000001001 No operation 1 —

RTE 0000000000101011 Delayed branch, stack area

→ PC/SR 4—

SETT 0000000000011000 1 → T 1 1

SLEEP 0000000000011011 Sleep 3*—

STC SR,Rn 0000nnnn00000010 SR → Rn 1 —

STC GBR,Rn 0000nnnn00010010 GBR → Rn 1 —

STC VBR,Rn 0000nnnn00100010 VBR → Rn 1 —

STC.L SR,@–Rn 0100nnnn00000011 Rn–4 → Rn, SR → (Rn) 2 —

STC.L GBR,@–Rn 0100nnnn00010011 Rn–4 → Rn, GBR → (Rn) 2 —

STC.L VBR,@–Rn 0100nnnn00100011 Rn–4 → Rn, BR → (Rn) 2 —

STS MACH,Rn 0000nnnn00001010 MACH → Rn 1 —

STS MACL,Rn 0000nnnn00011010 MACL → Rn 1 —

STS PR,Rn 0000nnnn00101010 PR → Rn 1 —

Table 2.17 System Control Instructions (cont)

Instruction Instruction Code Operation Exec.

Cycles T Bit

STS.L MACH,@–Rn 0100nnnn00000010 Rn–4 → Rn, MACH → (Rn) 1 —

STS.L MACL,@–Rn 0100nnnn00010010 Rn–4 → Rn, MACL → (Rn) 1 —

STS.L PR,@–Rn 0100nnnn00100010 Rn–4 → Rn, PR → (Rn) 1 —

TRAPA #imm 11000011iiiiiiii PC/SR → stack area,

(imm × 4 + VBR) → PC 8—

Note: *The number of execution cycles before the chip enters sleep mode: The execution cycles

shown in the table are minimums. The actual number of cycles may be increased when

(1) contention occurs between instruction fetches and data access, or (2) when the

destination register of the load instruction (memory → register) and the register used by

the next instruction are the same.

2.5 Processing States

2.5.1 State Transitions

The CPU has five processing states: reset, exception processing, bus release, program execution

and power-down. Figure 2.6 shows the transitions between the states.

RES = 0

Power-on reset state Manual reset state

Sleep mode Standby mode

Program execution state

Bus release state

Exception processing state

RES = 1

MRES = 1

RES = 1

When an interrupt source

or DMA address error occurs

NMI interrupt

source occurs

Exception 

processing

ends

Bus request

generated

Exception

processing

source occurs

Bus request

cleared

Bus request

generated

Bus request

cleared

SBY bit

cleared

for SLEEP

instruction

SBY bit set 

for SLEEP 

instruction

From any state

when RES = 0 From any state when

RES = 1 and MRES = 0

Reset states

Power-down state

Bus request

generated

Bus request

cleared

Figure 2.6 Transitions between Processing States

Reset State: The CPU resets in the reset state. When the RES pin level goes low, a power-on reset

results. When the RES pin is high and MRES is low, a manual reset will occur.

Exception Processing State: The exception processing state is a transient state that occurs when

exception processing sources such as resets or interrupts alter the CPU’s processing state flow.

For a reset, the initial values of the program counter (PC) (execution start address) and stack

pointer (SP) are fetched from the exception processing vector table and stored; the CPU then

branches to the execution start address and execution of the program begins.

For an interrupt, the stack pointer (SP) is accessed and the program counter (PC) and status

from the exception processing vector table; the CPU then branches to that address and the program

starts executing, thereby entering the program execution state.

Program Execution State: In the program execution state, the CPU sequentially executes the

program.

Power-Down State: In the power-down state, the CPU operation halts and power consumption

declines. The SLEEP instruction places the CPU in the power-down state. This state has two

modes: sleep mode and standby mode.

Bus Release State: In the bus release state, the CPU releases access rights to the bus to the device

that has requested them.

2.5.2 Power-Down State

Besides the ordinary program execution states, the CPU also has a power-down state in which

CPU operation halts, lowering power consumption. There are two power-down state modes: sleep

mode and standby mode.

Sleep Mode: When standby bit SBY (in the standby control register SBYCR) is cleared to 0 and a

SLEEP instruction executed, the CPU moves from program execution state to sleep mode. In the

sleep mode, the CPU halts and the contents of its internal registers and the data in on-chip cache

(or on-chip RAM) is maintained. The on-chip peripheral modules other than the CPU do not halt

in the sleep mode.

To return from sleep mode, use a reset (power-on or manual), any interrupt, or a DMA address

error; the CPU returns to the ordinary program execution state through the exception processing

state.

Standby Mode: To enter the standby mode, set the standby bit SBY (in the standby control

peripheral module, and oscillator functions are halted. However, when entering standby mode, the

DMA master enable bit of the DMAC should be set to 0. If multiplication-related instructions are

being executed at the time of entry into standby mode, the values of MACH and MACL will

become undefined.

To return from standby mode, use a reset (power-on or manual) or an NMI interrupt. For resets,

the CPU returns to ordinary program execution state through the exception processing state when

placed in a reset state for the duration of the oscillator stabilization time. For NMI interrupts, the

CPU returns to ordinary program execution state through the exception processing state after the

oscillator stabilization time has elapsed. In this mode, power consumption drops markedly, since

the oscillator stops (table 2.18).

Table 2.18 Power-Down State

State

Mode Transition

Conditions Clock CPU

On-Chip

Peripheral

Modules CPU

Registers

On-Chip

Cache or

On-Chip

RAM

I/O

Port

Pins Canceling

Sleep Execute

SLEEP

instruction

with SBY bit

cleared to 0

in SBYCR

Run Halt Run Held Held Held • Interrupt

• DMA address

error

• Power-on reset

• Manual reset

Stand-

by Execute

SLEEP

instruction

with SBY bit

set to 1 in

SBYCR

Halt Halt Halt and

initialize*Held Held Held or

Hi-Z

(select-

able)

• NMI interrupt

• Power-on reset

• Manual reset

Note: *Differs depending on the peripheral module and pin.

Section 3 Operating Modes

3.1 Operating Modes, Types, and Selection

This LSI has five operating modes and three clock modes, determined by the setting of the mode

pins (MD3–MD0). Do not change the mode pin settings during LSI operation (while power is on).

(In the F-ZTAT version, however, MD1 can be changed in the power-on reset state.)

Table 3.1 indicates the setting method for the operating mode.

Table 3.1 Operating Mode Setting

Mode Pin Setting Mode On-Chip CS0 Area

No. FWP MD3*1MD2*1MD1 MD0 Name ROM 112 Pin 144 Pin

0 1 x x 0 0 MCU mode 0 Not Active 8-bit space 16-bit

space

1 1 x x 0 1 MCU mode 1 Not Active 16-bit space 32-bit

space

2 1 x x 1 0 MCU mode 2 Active 8/16-bit

space*28/16/32-bit

space*2

3 1 x x 1 1 Single chip

mode Active — —

4 1 1 1 1 1 PROM mode*3Active — —

— 0 x x 0 0 Boot mode*4Active 8/16-bit

space*28/16/32-bit

space*2

—0xx01 — —

— 0 x x 1 0 User

programming

mode*4

Active 8/16-bit

space*28/16/32-bit

space*2

—0xx11 — —

— 1 1 1 0 1 Flash

programmer

mode*4

Active — —

Notes: *1 MD2 and MD3 pins select the clock mode in modes 0–3 (table 3.2).

*2 Set by BCR2 of BSC.

*3 Only ZTAT.

*4 Only F-ZTAT.

Table 3.2 indicates the setting method for the clock mode.

Table 3.2 Clock Mode Setting

MD3 MD2 Clock Mode

0 0 PLL ON × 1

0 1 PLL ON × 2

1 0 PLL ON × 4

1 1 Reserved (PROM mode only)

3.2 Explanation of Operating Modes

Table 3.3 describes the operating modes.

Table 3.3 Operating Modes

Mode Description

(MCU) Mode 0 CS0 area becomes an external memory space with 8-bit bus width for

the 112-pin version, and 16-bit for the 144-pin version.

(MCU) Mode 1 CS0 area becomes an external memory space with 16-bit bus width for

the 112-pin version, and 32-bit for the 144-pin version

(MCU) Mode 2 The on-chip ROM becomes effective. The bus width for the on-chip ROM

space is 32 bit.

Mode 3 (single chip

mode) Any port can be used, but external addresses can not be employed.

Mode 4 (PROM mode) On-chip ROM can be programmed using a general PROM writer.

Clock mode The input waveform frequency can be used as is, doubled or quadrupled

as an internal clock in modes 0 to 3.

3.3 Pin Configuration

Table 3.4 describes the function of each operating mode related pin.

Table 3.4 Operating Mode Pin Function

Name Input/Output Function

XTAL Input Connects to a crystal oscillator

EXTAL Input Connects to a crystal oscillator, or used for external clock input pin

PLLCAP Input Connects to a capacitor for PLL circuit operation

MD0 Input Designates operating mode through the level applied to this pin

MD1 Input Designates operating mode through the level applied to this pin

MD2 Input Designates clock mode through the level applied to this pin

MD3 Input Designates clock mode through the level applied to this pin

Section 4 Clock Pulse Generator (CPG)

4.1 Overview

The SH7040 Series has an on-chip clock pulse generator (CPG) that generates the system clock

(φ), as well as the internal clock (φ/2 to φ/8192). The CPG consists of an oscillator, a PLL, and a

prescaler.

4.1.1 Block Diagram

A block diagram of the clock pulse generator is shown in figure 4.1.

PLLCAP

EXTAL

XTAL

MD2

MD3

Oscillator PLL circuit

Clock mode

control circuitry

Prescaler

Within the LSI

φφ/2 to

φ/8192

Figure 4.1 Block Diagram of the Clock Pulse Generator

4.2 Oscillator

Clock pulses can be supplied from a connected crystal resonator or an external clock.

4.2.1 Connecting a Crystal Oscillator

Circuit Configuration: A crystal oscillator can be connected as shown in figure 4.2. Use the

damping resistance (Rd) listed in table 4.1. Use a 4–10 MHz crystal oscillator (consult your dealer

concerning the compatibility of the crystal oscillator and the LSI).

XTAL

EXTAL

CL1

CL2



4–10 MHz

CL1 = CL2 = 18–22 pF (Recommended value)

Figure 4.2 Connection of the Crystal Oscillator (Example)

Table 4.1 Damping Resistance Values (Recommended Values)

Frequency (MHz)

Parameter 4 8 10

Rd (Ω) 500 200 0

Crystal Oscillator: Figure 4.3 shows an equivalent circuit of the crystal oscillator. Use a crystal

oscillator with the characteristics listed in table 4.2.

EXTAL

LRs

XTAL

Figure 4.3 Crystal Oscillator Equivalent Circuit

Table 4.2 Crystal Oscillator Parameters

Frequency (MHz)

Parameter 4 8 10

Rs max (Ω) 120 80 60

Co max (pF) 7 7 7

4.2.2 External Clock Input Method

Figure 4.4 shows an example of an external clock input connection. In this case, make the external

clock high level to stop it when in standby mode. During operation, make the external input clock

frequency 4–10 MHz.

When leaving the XTAL pin open, make sure the parasitic capacitance is less than 10 pF.

Even when inputting an external clock, be sure to delay until after the oscillation stabilization time

(upon power-on) or after release from standby, in order to ensure the PLL stabilization time.

EXTAL

XTAL Open

External clock

input 4–10 MHz

Figure 4.4 Example of External Clock Connection

4.3 Prescaler

The prescaler divides the system clock (φ) to generate an internal clock (φ/2 to φ/8192) for supply

to peripheral modules.

4.4 Oscillator Halt Function

This CPG can detect a clock halt and automatically cause the timer pins to become high-

impedance when any system abnormality causes the oscillator to halt. That is, when a change of

EXTAL has not been detected, the high-current six pins (PE9/TIOC3B, PE11/TIOC3D,

PE12/TIOC4A, PE13/TIOC4B/MRES, PE14/TIOC4C/DACK0/AH, PE15/TIOC4D/DACK1/

IRQOUT) are set to high-impedance regardless of PFC setting.

Even in standby mode, these six pins become high-impedance regardless of PFC setting. These

pins enter the normal state after standby mode is cancelled.When abnormalities that halt the

oscillator occur except in standby mode, other LSI operations become undefined. In this case, LSI

operations, including these six pins, become undefined even when the oscillator operation starts

again.

4.5 Usage Notes

4.5.1 Oscillator Usage Notes

Since the characteristics of the oscillator are closely related to the user-defined board settings, the

user should refer to the connection examples in this section and perform a careful evaluation. The

oscillator circuit ratings will differ depending on factors such as the oscillator used and the stray

capacitance of the mounted circuitry. Therefore, the oscillator manufacturer should be consulted

before a decision is made. Make sure that the voltage applied to the oscillator does not exceed the

maximum rating.

4.5.2 Notes on Board Design

When connecting a crystal oscillator, observe the following precautions:

• To prevent induction from interfering with correct oscillation, do not route any signal lines

near the oscillator circuitry.

• When designing the board, place the crystal oscillator and its load capacitors as close as

possible to the XTAL and EXTAL pins.

Figure 4.5 shows the precautions regarding oscillator block board settings.

Crossing of signal

lines prohibited

CL1 XTAL

EXTAL

CL2

Figure 4.5 Cautions for Oscillator Circuit System Board Design

External circuitry such as that shown in figure 4.6 is recommended around the PLL.

PLLCAP

PLLVCC

PLLVSS

VCC

VSS

R1: 3 kΩC1: 470 pF

Rp: 200 Ω

CPB: 0.1 µF*

CB: 0.1 µF*

Note: * CB and CPB are laminated ceramic capacitors

(Recommended values)

Figure 4.6 Cautions for Use of PLL Oscillator Circuit

Place oscillation stabilization capacitor C1 and resistor R1 near the PLLCAP pin, and ensure that

these lines do not cross any other signal lines. Supply the C1 ground from PLLVSS.

Also, separate PLLVCC and PLLVSS, and the other VCC and VSS pins, from the board power supply

source, and be sure to insert bypass capacitors CPB and CB close to the pins.

If VCC and PLLVCC are both 3.3 V ± 0.3 V, it is recommended that Rp be set to 0 Ω.

4.5.3 Spread Spectrum Clock Generator Usage Notes

The following points should be borne in mind when using a spread spectrum clock generator as an

external oscillator in order to reduce radiation noise.

• Set the center frequency and the spread amplitude such that the internal clock does not exceed

the maximum frequency during spread spectrum operation.

• Using a spread spectrum clock generator may trigger the oscillator halt function described in

section 4.4. If the system configuration is such that this function will cause problems, a spread

spectrum clock generator should not be used.

Section 5 Exception Processing

5.1 Overview

5.1.1 Types of Exception Processing and Priority

Exception processing is started by four sources: resets, address errors, interrupts and instructions

and have the priority shown in table 5.1. When several exception processing sources occur at once,

they are processed according to the priority shown.

Table 5.1 Types of Exception Processing and Priority Order

Exception Source Priority

Reset Power-on reset High

Manual reset

Address CPU address error

error DMAC/DTC address error

Interrupt NMI

User break

IRQ

On-chip peripheral modules: • Direct memory access controller (DMAC)

• Multifunction timer/pulse unit (MTU)

• Serial communications interface (SCI)

• A/D converter (A/D)*3

• Data transfer controller (DTC)

• Compare match timer (CMT)

• Watchdog timer (WDT)

• Bus state controller (BSC)

• Port output enable control section

Instructions Trap instruction (TRAPA instruction)

General illegal instructions (undefined code)

Illegal slot instructions (undefined code placed directly after a delay branch

instruction*1 or instructions that rewrite the PC*2)Low

Notes: *1 Delayed branch instructions: JMP, JSR, BRA, BSR, RTS, RTE, BF/S, BT/S, BSRF,

BRAF.

*2 Instructions that rewrite the PC: JMP, JSR, BRA, BSR, RTS, RTE, BT, BF, TRAPA,

BF/S, BT/S, BSRF, BRAF.

*3 A mask products: A/D0, A/D1.

5.1.2 Exception Processing Operations

The exception processing sources are detected and begin processing according to the timing

shown in table 5.2.

Table 5.2 Timing of Exception Source Detection and the Start of Exception Processing

Exception Source Timing of Source Detection and Start of Processing

Reset Power-on reset Starts when the RES pin changes from low to high.

Manual reset Starts when the RES pin is high and the MRES pin changes

from low to high.

Address error Detected when instruction is decoded and starts when the

previous executing instruction finishes executing.

Interrupts Detected when instruction is decoded and starts when the

previous executing instruction finishes executing.

Instructions Trap instruction Starts from the execution of a TRAPA instruction.

General illegal

instructions Starts from the decoding of undefined code anytime except after

a delayed branch instruction (delay slot).

Illegal slot

instructions Starts from the decoding of undefined code placed in a delayed

branch instruction (delay slot) or of instructions that rewrite the

PC.

When exception processing starts, the CPU operates as follows:

1. Exception processing triggered by reset:

The initial values of the program counter (PC) and stack pointer (SP) are fetched from the

exception processing vector table (PC and SP are respectively the H'00000000 and

H'00000004 addresses for power-on resets and the H'00000008 and H'0000000C addresses for

manual resets). See section 5.1.3, Exception Processing Vector Table, for more information. 0

is then written to the vector base register (VBR) and 1111 is written to the interrupt mask bits

(I3–I0) of the status register (SR). The program begins running from the PC address fetched

from the exception processing vector table.

2. Exception processing triggered by address errors, interrupts and instructions:

SR and PC are saved to the stack indicated by R15. For interrupt exception processing, the

interrupt priority level is written to the SR’s interrupt mask bits (I3–I0). For address error and

instruction exception processing, the I3–I0 bits are not affected. The start address is then

fetched from the exception processing vector table and the program begins running from that

address.

5.1.3 Exception Processing Vector Table

Before exception processing begins running, the exception processing vector table must be set in

memory. The exception processing vector table stores the start addresses of exception service

routines. (The reset exception processing table holds the initial values of PC and SP.)

All exception sources are given different vector numbers and vector table address offsets, from

which the vector table addresses are calculated. During exception processing, the start addresses of

the exception service routines are fetched from the exception processing vector table, which

indicated by this vector table address.

Table 5.3 shows the vector numbers and vector table address offsets. Table 5.4 shows how vector

table addresses are calculated.

Table 5.3 Exception Processing Vector Table

Exception Sources Vector

Numbers Vector Table Address Offset

Power-on reset PC 0 H'00000000–H'00000003

SP 1 H'00000004–H'00000007

Manual reset PC 2 H'00000008–H'0000000B

SP 3 H'0000000C–H'0000000F

General illegal instruction 4 H'00000010–H'00000013

(Reserved by system) 5 H'00000014–H'00000017

Slot illegal instruction 6 H'00000018–H'0000001B

(Reserved by system) 7 H'0000001C–H'0000001F

(Reserved by system) 8 H'00000020–H'00000023

CPU address error 9 H'00000024–H'00000027

DMAC/DTC address

error 10 H'00000028–H'0000002B

Interrupts NMI 11 H'0000002C–H'0000002F

User break 12 H'00000030–H'00000033

(Reserved by system) 13

H'00000034–H'00000037

H'0000007C–H'0000007F

Trap instruction (user vector) 32

H'00000080–H'00000083

H'000000FC–H'000000FF

Table 5.3 Exception Processing Vector Table (cont)

Exception Sources Vector

Numbers Vector Table Address Offset

Interrupts IRQ0 64 H'00000100–H'00000103

IRQ1 65 H'00000104–H'00000107

IRQ2 66 H'00000108–H'0000010B

IRQ3 67 H'0000010C–H'0000010F

IRQ4 68 H'00000110–H'00000113

IRQ5 69 H'00000114–H'00000117

IRQ6 70 H'00000118–H'0000011B

IRQ7 71 H'0000011C–H'0000011F

On-chip peripheral

module*72

255

H'00000120–H'00000124

H'000003FC–H'000003FF

Note: *The vector numbers and vector table address offsets for each on-chip peripheral module

interrupt are given in section 6, Interrupt Controller (INTC), and table 6.3, Interrupt

Exception Processing Vectors and Priorities.

Table 5.4 Calculating Exception Processing Vector Table Addresses

Exception Source Vector Table Address Calculation

Resets Vector table address = (vector table address offset)

= (vector number) × 4

Address errors, interrupts,

instructions Vector table address = VBR + (vector table address offset)

= VBR + (vector number) × 4

Notes: 1. VBR: Vector base register

2. Vector table address offset: See table 5.3.

3. Vector number: See table 5.3.

5.2 Resets

Resets have the highest priority of any exception source. There are two types of resets: manual

resets and power-on resets. As table 5.5 shows, both types of resets initialize the internal status of

the CPU. In power-on resets, all registers of the on-chip peripheral modules are initialized; in

manual resets, they are not.

Table 5.5 Types of Resets

Conditions for Transition

to Reset Status Internal Status

Type RES MRES CPU On-Chip Peripheral Module

Power-on reset Low — Initialized Initialized

Manual reset High Low Initialized Not initialized

5.2.1 Power-On Reset

When the RES pin is driven low, the LSI does a power-on reset. To reliably reset the LSI, the RES

pin should be kept at low for at least the duration of the oscillation settling time when applying

power or when in standby mode (when the clock circuit is halted) or at least 20 tcyc (when the

clock circuit is running). During power-on reset, CPU internal status and all registers of on-chip

peripheral modules are initialized. See Appendix C, Pin States, for the status of individual pins

during the power-on reset status.

In the power-on reset status, power-on reset exception processing starts when the RES pin is first

driven low for a set period of time and then returned to high. The CPU will then operate as

follows:

1. The initial value (execution start address) of the program counter (PC) is fetched from the

exception processing vector table.

2. The initial value of the stack pointer (SP) is fetched from the exception processing vector table.

3. The vector base register (VBR) is cleared to H'00000000 and the interrupt mask bits (I3–I0) of

the status register (SR) are set to H'F (1111).

4. The values fetched from the exception processing vector table are set in the program counter

(PC) and SP and the program begins executing.

Be certain to always perform power-on reset processing when turning the system power on.

5.2.2 Manual Reset

When the RES pin is high and the MRES pin is driven low, the LSI does a manual reset. To

reliably reset the LSI, the MRES pin should be kept at low for at least the duration of the

oscillation settling time when in standby mode (when the clock is halted) or at least 20 tcyc when

the clock is operating. During manual reset, the CPU internal status is initialized. Registers of on-

chip peripheral modules are not initialized. Since the BSC is not affected, the DRAM refresh

control functions remain operational even when the manual reset status continues for a long period

of time. When the LSI enters manual reset status in the middle of a bus cycle, manual reset

exception processing does not start until the bus cycle has ended. Thus, manual resets do not abort

bus cycles. However, the bus cycle ends once MRES is driven low. Hold at low level until manual

reset mode. (Keep at low level for at least the longest bus cycle.) See Appendix C, Pin States, for

the status of individual pins during manual reset mode.

In the manual reset status, manual reset exception processing starts when the MRES pin is first

kept low for a set period of time and then returned to high. The CPU will then operate the same as

described for power-on resets.

5.3 Address Errors

Address errors occur when instructions are fetched or data read or written, as shown in table 5.6.

Table 5.6 Bus Cycles and Address Errors

Bus Cycle

Type Bus

Master Bus Cycle Description Address Errors

Instruction CPU Instruction fetched from even address None (normal)

fetch Instruction fetched from odd address Address error occurs

Instruction fetched from other than on-chip

peripheral module space*None (normal)

Instruction fetched from on-chip peripheral module

space*Address error occurs

Instruction fetched from external memory space

when in single chip mode Address error occurs

Data CPU or Word data accessed from even address None (normal)

read/write DMAC Word data accessed from odd address Address error occurs

or DTC Longword data accessed from a longword

boundary None (normal)

Longword data accessed from other than a long-

word boundary Address error occurs

Byte or word data accessed in on-chip peripheral

module space*None (normal)

Longword data accessed in 16-bit on-chip

peripheral module space*None (normal)

Longword data accessed in 8-bit on-chip peripheral

module space*Address error occurs

External memory space accessed when in single

chip mode Address error occurs

Note: *See section 10, Bus State Controller (BSC).

5.3.1 Address Error Exception Processing

When an address error occurs, the bus cycle in which the address error occurred ends. When the

executing instruction then finishes, address error exception processing starts up. The CPU operates

as follows:

1. The status register (SR) is saved to the stack.

2. The program counter (PC) is saved to the stack. The PC value saved is the start address of the

instruction to be executed after the last executed instruction.

3. The exception service routine start address is fetched from the exception processing vector

table that corresponds to the address error that occurred and the program starts executing from

that address. The jump that occurs is not a delayed branch.

5.4 Interrupts

Table 5.7 shows the sources that start up interrupt exception processing. These are divided into

NMI, user breaks, IRQ, and on-chip peripheral modules.

Table 5.7 Interrupt Sources

Type Request Source Number of

Sources

NMI NMI pin (external input) 1

User break User break controller 1

IRQ IRQ0–IRQ7 (external input) 8

On-chip peripheral module Direct memory access controller (DMAC) 4

Multifunction timer/pulse unit (MTU) 24

Serial communications interface (SCI) 8

A/D converter 1*

Data transfer controller (DTC) 1

Compare match timer (CMT) 2

Watchdog timer (WDT) 1

Bus state controller (BSC) 1

Port 1

Note: * For A mask products, (A/D0, A/D1) is 2

Each interrupt source is allocated a different vector number and vector table offset. See section 6,

Interrupt Controller (INTC), and table 6.3, Interrupt Exception Processing Vectors and Priorities,

for more information on vector numbers and vector table address offsets.

5.4.1 Interrupt Priority Level

The interrupt priority order is predetermined. When multiple interrupts occur simultaneously

(overlap), the interrupt controller (INTC) determines their relative priorities and starts up

processing according to the results.

The priority order of interrupts is expressed as priority levels 0–16, with priority 0 the lowest and

priority 16 the highest. The NMI interrupt has priority 16 and cannot be masked, so it is always

accepted. The user break interrupt priority level is 15. IRQ interrupts and on-chip peripheral

module interrupt priority levels can be set freely using the INTC’s interrupt priority level setting

registers A through H (IPRA–IPRH) as shown in table 5.8. The priority levels that can be set are

0–15. Level 16 cannot be set. See section 6.3.1, Interrupt Priority Registers A-H (IPRA-IPRH), for

more information on IPRA to IPRH.

Table 5.8 Interrupt Priority Order

Type Priority Level Comment

NMI 16 Fixed priority level. Cannot be masked.

User break 15 Fixed priority level.

IRQ 0–15 Set with interrupt priority level setting registers A

through H (IPRA–IPRH).

On-chip peripheral module 0–15 Set with interrupt priority level setting registers A

through H (IPRA–IPRH).

5.4.2 Interrupt Exception Processing

When an interrupt occurs, its priority level is ascertained by the interrupt controller (INTC). NMI

is always accepted, but other interrupts are only accepted if they have a priority level higher than

the priority level set in the interrupt mask bits (I3–I0) of the status register (SR).

When an interrupt is accepted, exception processing begins. In interrupt exception processing, the

CPU saves SR and the program counter (PC) to the stack. The priority level value of the accepted

interrupt is written to SR bits I3–I0. For NMI, however, the priority level is 16, but the value set in

I3–I0 is H'F (level 15). Next, the start address of the exception service routine is fetched from the

exception processing vector table for the accepted interrupt, that address is jumped to and

execution begins. See section 6.4, Interrupt Operation, for more information on the interrupt

exception processing.

5.5 Exceptions Triggered by Instructions

Exception processing can be triggered by trap instructions, general illegal instructions, and illegal

slot instructions, as shown in table 5.9.

Table 5.9 Types of Exceptions Triggered by Instructions

Type Source Instruction Comment

Trap instructions TRAPA —

Illegal slot

instructions Undefined code placed

immediately after a delayed

branch instruction (delay slot)

and instructions that rewrite the

Delayed branch instructions: JMP, JSR,

BRA, BSR, RTS, RTE, BF/S, BT/S, BSRF,

BRAF

Instructions that rewrite the PC: JMP, JSR,

BRA, BSR, RTS, RTE, BT, BF, TRAPA,

BF/S, BT/S, BSRF, BRAF

General illegal

instructions Undefined code anywhere

besides in a delay slot —

5.5.1 Trap Instructions

When a TRAPA instruction is executed, trap instruction exception processing starts up. The CPU

operates as follows:

1. The status register (SR) is saved to the stack.

2. The program counter (PC) is saved to the stack. The PC value saved is the start address of the

instruction to be executed after the TRAPA instruction.

3. The exception service routine start address is fetched from the exception processing vector

table that corresponds to the vector number specified in the TRAPA instruction. That address

is jumped to and the program starts executing. The jump that occurs is not a delayed branch.

5.5.2 Illegal Slot Instructions

An instruction placed immediately after a delayed branch instruction is said to be placed in a delay

slot. When the instruction placed in the delay slot is undefined code, illegal slot exception

processing starts up when that undefined code is decoded. Illegal slot exception processing also

starts up when an instruction that rewrites the program counter (PC) is placed in a delay slot. The

processing starts when the instruction is decoded. The CPU handles an illegal slot instruction as

follows:

1. The status register (SR) is saved to the stack.

2. The program counter (PC) is saved to the stack. The PC value saved is the jump address of the

delayed branch instruction immediately before the undefined code or the instruction that

rewrites the PC.

3. The exception service routine start address is fetched from the exception processing vector

table that corresponds to the exception that occurred. That address is jumped to and the

program starts executing. The jump that occurs is not a delayed branch.

5.5.3 General Illegal Instructions

When undefined code placed anywhere other than immediately after a delayed branch instruction

(i.e., in a delay slot) is decoded, general illegal instruction exception processing starts up. The

CPU handles general illegal instructions the same as illegal slot instructions. Unlike processing of

illegal slot instructions, however, the program counter value stored is the start address of the

undefined code.

5.6 When Exception Sources Are Not Accepted

When an address error or interrupt is generated after a delayed branch instruction or interrupt-

disabled instruction, it is sometimes not accepted immediately but stored instead, as shown in

table 5.10. When this happens, it will be accepted when an instruction that can accept the

exception is decoded.

Table 5.10 Generation of Exception Sources Immediately after a Delayed Branch

Instruction or Interrupt-Disabled Instruction

Exception Source

Point of Occurrence Address Error Interrupt

Immediately after a delayed branch instruction*1Not accepted Not accepted

Immediately after an interrupt-disabled instruction*2Accepted Not accepted

Notes: *1 Delayed branch instructions: JMP, JSR, BRA, BSR, RTS, RTE, BF/S, BT/S, BSRF,

BRAF

*2 Interrupt-disabled instructions: LDC, LDC.L, STC, STC.L, LDS, LDS.L, STS, STS.L

5.6.1 Immediately after a Delayed Branch Instruction

When an instruction placed immediately after a delayed branch instruction (delay slot) is decoded,

neither address errors nor interrupts are accepted. The delayed branch instruction and the

instruction located immediately after it (delay slot) are always executed consecutively, so no

exception processing occurs during this period.

5.6.2 Immediately after an Interrupt-Disabled Instruction

When an instruction immediately following an interrupt-disabled instruction is decoded, interrupts

are not accepted. Address errors are accepted.

5.7 Stack Status after Exception Processing Ends

The status of the stack after exception processing ends is as shown in table 5.11.

Table 5.11 Types of Stack Status after Exception Processing Ends

Types Stack Status

Address error 32 bits

32 bitsSR

Address of instruction

after executed instruction

Trap instruction 32 bits

32 bitsSR

Address of instruction

after TRAPA instruction

General illegal instruction 32 bits

32 bitsSR

Start address of illegal

instruction

Interrupt 32 bits

32 bitsSR

Address of instruction

after executed instruction

Illegal slot instruction 32 bits

32 bitsSR

Jump destination address

of delay branch instruction

5.8 Notes on Use

5.8.1 Value of Stack Pointer (SP)

The value of the stack pointer must always be a multiple of four. If it is not, an address error will

occur when the stack is accessed during exception processing.

5.8.2 Value of Vector Base Register (VBR)

The value of the vector base register must always be a multiple of four. If it is not, an address error

will occur when the stack is accessed during exception processing.

5.8.3 Address Errors Caused by Stacking of Address Error Exception Processing

When the stack pointer is not a multiple of four, an address error will occur during stacking of the

exception processing (interrupts, etc.) and address error exception processing will start up as soon

as the first exception processing is ended. Address errors will then also occur in the stacking for

this address error exception processing. To ensure that address error exception processing does not

go into an endless loop, no address errors are accepted at that point. This allows program control

to be shifted to the address error exception service routine and enables error processing.

When an address error occurs during exception processing stacking, the stacking bus cycle (write)

is executed. During stacking of the status register (SR) and program counter (PC), the SP is –4 for

both, so the value of SP will not be a multiple of four after the stacking either. The address value

output during stacking is the SP value, so the address where the error occurred is itself output.

This means the write data stacked will be undefined.

Section 6 Interrupt Controller (INTC)

6.1 Overview

The interrupt controller (INTC) ascertains the priority of interrupt sources and controls interrupt

requests to the CPU. The INTC has registers for setting the priority of each interrupt which can be

used by the user to order the priorities in which the interrupt requests are processed.

6.1.1 Features

The INTC has the following features:

• 16 levels of interrupt priority: By setting the eight interrupt-priority level registers, the

priorities of IRQ interrupts and on-chip peripheral module interrupts can be set in 16 levels for

different request sources.

• NMI noise canceler function: NMI input level bits indicate the NMI pin status. By reading

these bits with the interrupt exception service routine, the pin status can be confirmed, enabling

it to be used as a noise canceler.

• Notification of interrupt occurrence can be reported externally (IRQOUT pin). For example, it

is possible to request bus rights if an external bus master is informed that a peripheral module

interrupt has occurred when the LSI has released the bus rights.

6.1.2 Block Diagram

Figure 6.1 is a block diagram of the INTC.

100

CPU

Interrupt 

request

Com-

parator

CPU/

DTC

request

judg-

ment

Priority

ranking

judg-

ment

Input

control

(Interrupt request)

ISR

ICR IPR

DTER

DTC

IPRA–IPRH

Module bus Bus

interface

Internal bus

I3 I2 I1 I0

INTC

IRQOUT

NMI

IRQ0

IRQ1

IRQ2

IRQ3

IRQ4

IRQ5

IRQ6

IRQ7

UBC

DMAC

MTU

CMT

SCI

A/D

DTC (Interrupt request)

(Interrupt request)

WDT

BSC

I/O

UBC:

DMAC:

MTU:

CMT:

SCI:

A/D:

DTC:

WDT:

BSC:

User break controller

Direct memory access controller

Multifunction timer pulse unit

Compare match timer

Serial communication interface

A/D converter

Data transfer controller

Watchdog timer

Bus state controller (DRAM

refresh control section)

I/O:

ICR:

ISR:

DTER:

IPRA–IPRH: 



SR:

I/O port (port output control section)

Interrupt control register

IRQ ststus register

DTC enable register

Interrupt priority level setting 

registers A to H

Status register

Figure 6.1 INTC Block Diagram

101

6.1.3 Pin Configuration

Table 6.1 shows the INTC pin configuration.

Table 6.1 Pin Configuration

Name Abbreviation I/O Function

Non-maskable interrupt input pin NMI I Input of non-maskable interrupt

request signal

Interrupt request input pins IRQ0–IRQ7 I Input of maskable interrupt request

signals

Interrupt request output pin IRQOUT O Output of notification signal when an

interrupt has occurred

6.1.4 Register Configuration

The INTC has the 10 registers shown in table 6.2. These registers set the priority of the interrupts

and control external interrupt input signal detection.

Table 6.2 Register Configuration

Name Abbr. R/W Initial Value Address Access Sizes

Interrupt priority register A IPRA R/W H'0000 H'FFFF8348 8, 16, 32

Interrupt priority register B IPRB R/W H'0000 H'FFFF834A 8, 16, 32

Interrupt priority register C IPRC R/W H'0000 H'FFFF834C 8, 16, 32

Interrupt priority register D IPRD R/W H'0000 H'FFFF834E 8, 16, 32

Interrupt priority register E IPRE R/W H'0000 H'FFFF8350 8, 16, 32

Interrupt priority register F IPRF R/W H'0000 H'FFFF8352 8, 16, 32

Interrupt priority register G IPRG R/W H'0000 H'FFFF8354 8, 16, 32

Interrupt priority register H IPRH R/W H'0000 H'FFFF8356 8, 16, 32

Interrupt control register ICR R/W *1H'FFFF8358 8, 16, 32

IRQ status register ISR R(W)*2H'0000 H'FFFF835A 8, 16, 32

Notes: *1 The value when the NMI pin is high is H'8000; when the NMI pin is low, it is H'0000.

*2 Only 0 can be written, in order to clear flags.

102

6.2 Interrupt Sources

There are four types of interrupt sources: NMI, user breaks, IRQ, and on-chip peripheral modules.

Each interrupt has a priority expressed as a priority level (0 to 16, with 0 the lowest and 16 the

highest). Giving an interrupt a priority level of 0 masks it.

6.2.1 NMI Interrupts

The NMI interrupt has priority 16 and is always accepted. Input at the NMI pin is detected by

edge. Use the NMI edge select bit (NMIE) in the interrupt control register (ICR) to select either

the rising or falling edge. NMI interrupt exception processing sets the interrupt mask level bits

(I3–I0) in the status register (SR) to level 15.

6.2.2 User Break Interrupt

A user break interrupt has a priority of level 15, and occurs when the break condition set in the

user break controller (UBC) is satisfied. User break interrupt requests are detected by edge and are

held until accepted. User break interrupt exception processing sets the interrupt mask level bits

(I3–I0) in the status register (SR) to level 15. For more information about the user break interrupt,

see section 7, User Break Controller (UBC).

6.2.3 IRQ Interrupts

IRQ interrupts are requested by input from pins IRQ0–IRQ7. Set the IRQ sense select bits

(IRQ0S–IRQ7S) of the interrupt control register (ICR) to select low level detection or falling edge

detection for each pin. The priority level can be set from 0 to 15 for each pin using the interrupt

priority registers A and B (IPRA–IPRB).

When IRQ interrupts are set to low level detection, an interrupt request signal is sent to the INTC

during the period the IRQ pin is low level. Interrupt request signals are not sent to the INTC when

the IRQ pin becomes high level. Interrupt request levels can be confirmed by reading the IRQ

flags (IRQ0F–IRQ7F) of the IRQ status register (ISR).

When IRQ interrupts are set to falling edge detection, interrupt request signals are sent to the

INTC upon detecting a change on the IRQ pin from high to low level. IRQ interrupt request

detection results are maintained until the interrupt request is accepted. Confirmation that IRQ

interrupt requests have been detected is possible by reading the IRQ flags (IRQ0F–IRQ7F) of the

IRQ status register (ISR), and by writing a 0 after reading a 1, IRQ interrupt request detection

results can be withdrawn.

In IRQ interrupt exception processing, the interrupt mask bits (I3–I0) of the status register (SR)

are set to the priority level value of the accepted IRQ interrupt.

103

6.2.4 On-Chip Peripheral Module Interrupts

On-chip peripheral module interrupts are interrupts generated by the following on-chip peripheral

modules:

• Direct memory access controller (DMAC)

• Multifunction timer/pulse unit (MTU)

• Compare match timer (CMT)

• Serial communications interface (SCI)

• A/D converter (A/D)

• Data transfer controller (DTC)

• Watchdog timer (WDT)

• Bus state controller (BSC)

• I/O port (I/O)

A different interrupt vector is assigned to each interrupt source, so the exception service routine

does not have to decide which interrupt has occurred. Priority levels between 0 and 15 can be

assigned to individual on-chip peripheral modules in interrupt priority registers C–H (IPRC–

IPRH).

On-chip peripheral module interrupt exception processing sets the interrupt mask level bits (I3–I0)

in the status register (SR) to the priority level value of the on-chip peripheral module interrupt that

was accepted.

6.2.5 Interrupt Exception Vectors and Priority Rankings

Table 6.3 lists interrupt sources and their vector numbers, vector table address offsets and interrupt

priorities.

Each interrupt source is allocated a different vector number and vector table address offset. Vector

table addresses are calculated from vector numbers and address offsets. In interrupt exception

processing, the exception service routine start address is fetched from the vector table indicated by

the vector table address. See table 5.4, Calculating Exception Processing Vector Table Addresses.

IRQ interrupts and on-chip peripheral module interrupt priorities can be set freely between 0 and

15 for each pin or module by setting interrupt priority registers A–H (IPRA–IPRH). The ranking

of interrupt sources for IPRC–IPRH, however, must be the order listed under Priority Order

Within IPR Setting Range in table 6.3 and cannot be changed. A power-on reset assigns priority

level 0 to IRQ interrupts and on-chip peripheral module interrupts. If the same priority level is

assigned to two or more interrupt sources and interrupts from those sources occur simultaneously,

their priority order is the default priority order indicated at the right in table 6.3.

104

Table 6.3 Interrupt Exception Processing Vectors and Priorities

Interrupt Vector Interrupt Priority

Interrupt Source Vector

No.

Vector Table

Address

Offset

Priority

(Initial

Value)

Corre-

sponding

IPR (Bits)

within IPR

Setting

Range Default

Priority

NMI 11 H'0000002C–

H'0000002F 16 — — High

User break 12 H'00000030–

H'00000033 15 — —

IRQ0 64 H'00000100–

H'00000103 0–15 (0) IPRA

(15–12) —

IRQ1 65 H'00000104–

H'00000107 0–15 (0) IPRA

(11–8) —

IRQ2 66 H'00000108–

H'0000010B 0–15 (0) IPRA

(7–4) —

IRQ3 67 H'0000010C–

H'0000010F 0–15 (0) IPRA

(3–0) —

IRQ4 68 H'00000110–

H'00000113 0–15 (0) IPRB

(15–12) —

IRQ5 69 H'00000114–

H'00000117 0–15 (0) IPRB

(11–8) —

IRQ6 70 H'00000118–

H'0000011B 0–15 (0) IPRB

(7–4) —

IRQ7 71 H'0000011C–

H'0000011F 0–15 (0) IPRB

(3–0) —

DMAC0 DEI0 72 H'00000120–

H'00000123 0–15 (0) IPRC

(15–12) —

DMAC1 DEI1 76 H'00000130–

H'00000133 0–15 (0) IPRC

(11–8) —

DMAC2 DEI2 80 H'00000140–

H'00000143 0–15 (0) IPRC

(7–4) —

DMAC3 DEI3 84 H'00000150–

H'00000153 0–15 (0) IPRC

(3–0) —Low

105

Table 6.3 Interrupt Exception Processing Vectors and Priorities (cont)

Interrupt Vector Interrupt Priority

Interrupt Source Vector

No.

Vector Table

Address

Offset

Priority

(Initial

Value)

Corre-

sponding

IPR (Bits)

within IPR

Setting

Range Default

Priority

MTU0 TGI0A 88 H'00000160–

H'00000163 0–15 (0) IPRD

(15–12) High High

TGI0B 89 H'00000164–

H'00000167 0–15 (0)

TGI0C 90 H'00000168–

H'0000016B 0–15 (0)

TGI0D 91 H'0000016C–

H'0000016F 0–15 (0) Low

TCI0V 92 H'00000170–

H'00000173 0–15 (0) IPRD

(11–8) —

MTU1 TGI1A 96 H'00000180–

H'00000183 0–15 (0) IPRD

(7–4) High

TGI1B 97 H'00000184–

H'00000187 0–15 (0) Low

TCI1V 100 H'00000190–

H'00000193 0–15 (0) IPRD

(3–0) High

TCI1U 101 H'00000194–

H'00000197 0–15 (0) Low

MTU2 TGI2A 104 H'000001A0–

H'000001A3 0–15 (0) IPRE

(15–12) High

TGI2B 105 H'000001A4–

H'000001A7 0–15 (0) Low

TCI2V 108 H'000001B0–

H'000001B3 0–15 (0) IPRE

(11–8) High

TCI2U 109 H'000001B4–

H'000001B7 0–15 (0) Low Low

106

Table 6.3 Interrupt Exception Processing Vectors and Priorities (cont)

Interrupt Vector Interrupt Priority

Interrupt Source Vector

No.

Vector Table

Address

Offset

Priority

(Initial

Value)

Corre-

sponding

IPR (Bits)

within IPR

Setting

Range Default

Priority

MTU3 TGI3A 112 H'000001C0–

H'000001C3 0–15 (0) IPRE

(7–4) High High

TGI3B 113 H'000001C4–

H'000001C7 0–15 (0)

TGI3C 114 H'000001C8–

H'000001CB 0–15 (0)

TGI3D 115 H'000001CC–

H'000001CF 0–15 (0) Low

TCI3V 116 H'000001D0–

H'000001D3 0–15 (0) IPRE

(3–0) —

MTU4 TGI4A 120 H'000001E0–

H'000001E3 0–15 (0) IPRF

(15–12) High

TGI4B 121 H'000001E4–

H'000001E7 0–15 (0)

TGI4C 122 H'000001E8–

H'000001EB 0–15 (0)

TGI4D 123 H'000001EC–

H'000001EF 0–15 (0) Low

TCI4V 124 H'000001F0–

H'000001F3 0–15 (0) IPRF

(11–8) High

Reserved 125 H'000001F4–

H'000001F7 0–15 (0) Low

SCI0 ERI0 128 H'00000200–

H'00000203 0–15 (0) IPRF

(7–4) High

RXI0 129 H'00000204–

H'00000207 0–15 (0)

TXI0 130 H'00000208–

H'0000020B 0–15 (0)

TEI0 131 H'0000020C–

H'0000020F 0–15 (0) Low Low

107

Table 6.3 Interrupt Exception Processing Vectors and Priorities (cont)

Interrupt Vector Interrupt Priority

Interrupt Source Vector

No.

Vector Table

Address

Offset

Priority

(Initial

Value)

Corre-

sponding

IPR (Bits)

within IPR

Setting

Range Default

Priority

SCI1 ERI1 132 H'00000210–

H'00000213 0–15 (0) IPRF

(3–0) High High

RXI1 133 H'00000214–

H'00000217 0–15 (0)

TXI1 134 H'00000218–

H'0000021B 0–15 (0)

TEI1 135 H'0000021C–

H'0000021F 0–15 (0) Low

A/D*ADI 136 H'00000220–

H'00000223 0–15 (0) IPRG

(15–12) —

DTC SWDTCE 140 H'00000230–

H'00000233 0–15 (0) IPRG

(11–8) —

CMT0 CMI0 144 H'00000240–

H'00000243 0–15 (0) IPRG

(7–4) —

CMT1 CMI1 148 H'00000250–

H'00000253 0–15 (0) IPRG

(3–0) —

WDT ITI 152 H'00000260–

H'00000263 0–15 (0) IPRH

(15–12) High

BSC CMI 153 H'00000264–

H'00000267 0–15 (0) Low

I/O OEI 156 H'00000270–

H'00000273 0–15 (0) IPRH

(11–8) —Low

Note: *For A mask products, A/D is as follows

A/D ADI0 136 H'00000220–

H'00000223 0–15 (0) IPRG

(15–12) High

ADI1 137 H'00000224–

H'00000227 0–15 (0) Low

108

6.3 Description of Registers

6.3.1 Interrupt Priority Registers A–H (IPRA–IPRH)

Interrupt priority registers A–H (IPRA–IPRH) are 16-bit readable/writable registers that set

priority levels from 0 to 15 for IRQ interrupts and on-chip peripheral module interrupts.

Correspondence between interrupt request sources and each of the IPRA–IPRH bits is shown in

table 6.4.

Bit: 15 14 13 12 11 10 9 8

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Table 6.4 Interrupt Request Sources and IPRA–IPRH

Bits

Interrupt priority register A IRQ0 IRQ1 IRQ2 IRQ3

Interrupt priority register B IRQ4 IRQ5 IRQ6 IRQ7

Interrupt priority register C DMAC0 DMAC1 DMAC2 DMAC3

Interrupt priority register D MTU0 MTU0 MTU1 MTU1

Interrupt priority register E MTU2 MTTU2 MTU3 MTU3

Interrupt priority register F MTU4 MTU4 SCI0 SCI1

Interrupt priority register G A/D(A/D0,

A/D1)*DTC CMT0 CMT1

Interrupt priority register H WDT, BSC I/O Reserved Reserved

Note: *Excluding A mask products are A/D, A mask products are A/D0 and A/D1.

109

As indicated in table 6.4, four IRQ pins or groups of 4 on-chip peripheral modules are allocated to

each register. Each of the corresponding interrupt priority ranks are established by setting a value

from H'0 (0000) to H'F (1111) in each of the four-bit groups 15–12, 11–8, 7–4, and 3–0. Interrupt

priority rank becomes level 0 (lowest) by setting H'0, and level 15 (highest) by setting H'F. If

multiple on-chip peripheral modules are assigned to WDT and BSC, those multiple modules are

set to the same priority rank.

IPRA–IPRH are initialized to H'0000 by a power-on reset or a manual reset. They are not

initialized in standby mode.

6.3.2 Interrupt Control Register (ICR)

The ICR is a 16-bit register that sets the input signal detection mode of the external interrupt input

pin NMI and IRQ0 –IRQ7 and indicates the input signal level to the NMI pin. A power-on reset

initializes ICR but the standby mode does not.

Bit: 15 14 13 12 11 10 9 8

NMIL — — — — — — NMIE

Initial value: *0000000

R/W: R R R R R R R R/W

Bit: 7 6 5 4 3 2 1 0

IRQ0S IRQ1S IRQ2S IRQ3S IRQ4S IRQ5S IRQ6S IRQ7S

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Note: *When NMI input is high: 1; when NMI input is low: 0

• Bit 15—NMI Input Level (NMIL): Sets the level of the signal input at the NMI pin. This bit

can be read to determine the NMI pin level. This bit cannot be modified.

Bit 15: NMIL Description

0 NMI input level is low

1 NMI input level is high

• Bits 14–9—Reserved: These bits always read as 0. The write value should always be 0.

110

• Bit 8—NMI Edge Select (NMIE)

Bit 8: NMIE Description

0 Interrupt request is detected on falling edge of NMI input (initial value)

1 Interrupt request is detected on rising edge of NMI input

• Bits 7–0—IRQ0–IRQ7 Sense Select (IRQ0S–IRQ7S): These bits set the IRQ0–IRQ7 interrupt

request detection mode.

Bits 7-0: IRQ0S–IRQ7S Description

0 Interrupt request is detected on low level of IRQ input (initial value)

1 Interrupt request is detected on falling edge of IRQ input

6.3.3 IRQ Status Register (ISR)

The ISR is a 16-bit register that indicates the interrupt request status of the external interrupt input

pins IRQ0–IRQ7. When IRQ interrupts are set to edge detection, held interrupt requests can be

withdrawn by writing a 0 to IRQnF after reading an IRQnF = 1.

A power-on reset initializes ISR but the standby mode does not.

Bit: 15 14 13 12 11 10 9 8

————————

Initial value: 0 0 0 0 0 0 0 0

R/W: R R R R R R R R

Bit: 7 6 5 4 3 2 1 0

IRQ0F IRQ1F IRQ2F IRQ3F IRQ4F IRQ5F IRQ6F IRQ7F

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

• Bits 15–8—Reserved: These bits always read as 0. The write value should always be 0.

111

• Bits 7–0—IRQ0–IRQ7 Flags (IRQ0F–IRQ7F): These bits display the IRQ0–IRQ7 interrupt

request status.

Bits 7-0:

IRQ0F–IRQ7F Detection Setting Description

0 Level detection No IRQn interrupt request exists.

Clear conditions: When IRQn input is high level

Edge detection No IRQn interrupt request was detected. (initial value)

Clear conditions:

1. When a 0 is written after reading IRQnF = 1 status

2. When IRQn interrupt exception processing has been

executed

3. When a DTC transfer due to IRQn interrupt has been

executed

1 Level detection An IRQn interrupt request exists.

Set conditions: When IRQn input is low level

Edge detection An IRQn interrupt request was detected.

Set conditions: When a falling edge occurs at an IRQn input

IRQ pin

Edge

detection

Selection

CPU

interrupt



request

DTC

activation

request

Judgment

(IRQn interrupt acceptance/DTC transfer completion/IRQnF = 0 write after IRQnF = 1 read)

RESIRQn

IRQnS

(0: level,

1: edge)

ISR.IRQnF

Level

detection

DTC

Figure 6.2 External Interrupt Process

112

6.4 Interrupt Operation

6.4.1 Interrupt Sequence

The sequence of interrupt operations is explained below. Figure 6.3 is a flowchart of the

operations.

1. The interrupt request sources send interrupt request signals to the interrupt controller.

2. The interrupt controller selects the highest priority interrupt in the interrupt requests sent,

following the priority levels set in interrupt priority level setting registers A–H (IPRA–IPRH).

Lower-priority interrupts are ignored. They are held pending until interrupt requests designated

as edge-detect type are accepted. For IRQ interrupts, however, withdrawal is possible by

accessing the IRQ status register (ISR). See section 6.2.3, IRQ Interrupts, for details. Interrupts

held pending due to edge detection are cleared by a power-on reset or a manual reset. If two of

these interrupts have the same priority level or if multiple interrupts occur within a single

module, the interrupt with the highest default priority or the highest priority within its IPR

setting range (as indicated in table 6.3) is selected.

3. The interrupt controller compares the priority level of the selected interrupt request with the

interrupt mask bits (I3–I0) in the CPU’s status register (SR). If the request priority level is

equal to or less than the level set in I3–I0, the request is ignored. If the request priority level is

higher than the level in bits I3–I0, the interrupt controller accepts the interrupt and sends an

interrupt request signal to the CPU.

4. When the interrupt controller accepts an interrupt, a low level is output from the IRQOUT pin.

5. The CPU detects the interrupt request sent from the interrupt controller when it decodes the

next instruction to be executed. Instead of executing the decoded instruction, the CPU starts

interrupt exception processing (figure 6.4).

6. SR and PC are saved onto the stack.

7. The priority level of the accepted interrupt is copied to the interrupt mask level bits (I3–I0) in

the status register (SR).

8. When the accepted interrupt is sensed by level or is from an on-chip peripheral module, a high

level is output from the IRQOUT pin. When the accepted interrupt is sensed by edge, a high

level is output from the IRQOUT pin at the point when the CPU starts interrupt exception

processing instead of instruction execution as noted in (5) above. However, if the interrupt

controller accepts an interrupt with a higher priority than one it is in the midst of accepting, the

IRQOUT pin will remain low level.

9. The CPU reads the start address of the exception service routine from the exception vector

table for the accepted interrupt, jumps to that address, and starts executing the program there.

This jump is not a delay branch.

113

Yes

NMI? No

Yes User break? No

Yes Level 15

interrupt? No

Yes

I3 to I0 ≤

level 14?

Yes

Level 14

interrupt? No

Yes

I3 to I0 ≤

level 13?

Yes

Level 1

interrupt? No

Yes

I3 to I0 =

level 0?

Program

execution state

IRQOUT = low level*1

Save SR to stack

Save PC to stack

IRQOUT = high level*2

Branches to exception

service routine

I3 to I0: Interrupt mask bits of status register

Interrupt?

Copy accept-interrupt

level to I3 to I0

Reads exception

vector table

Notes: *1

IRQOUT is the same signal as the interrupt request signal to the CPU (see

figure 6.1). Thus, it is output when there is a higher priority interrupt request

than the one in the I3 to I0 bits of the SR.

When the accepted interrupt is sensed by edge, the IRQOUT pin becomes

high level at the point when the CPU starts interrupt exception processing

instead of instruction execution (before SR is saved to the stack).

If the interrupt controller has accepted another interrupt with a higher priority

and has output an interrupt request to the CPU, the IRQOUT pin will remain

low level.

Figure 6.3 Interrupt Sequence Flowchart

114

6.4.2 Stack after Interrupt Exception Processing

Figure 6.4 shows the stack after interrupt exception processing.

32 bits

PC*1

Address

4n–8

4n–4

SP*2

Notes: *1

PC: Start address of the next instruction (return destination instruction)

after the executing instruction

Always be certain that SP is a multiple of 4

Figure 6.4 Stack after Interrupt Exception Processing

6.5 Interrupt Response Time

Table 6.5 indicates the interrupt response time, which is the time from the occurrence of an

interrupt request until the interrupt exception processing starts and fetching of the first instruction

of the interrupt service routine begins. Figure 6.5 shows the pipeline when an IRQ interrupt is

accepted.

115

Table 6.5 Interrupt Response Time

Number of States

Item NMI, Peripheral

Module IRQ Notes

DMAC/DTC active

judgment 0 or 1 1 1 state required for interrupt

signals for which

DMAC/DTC activation is

possible

Compare identified inter-

rupt priority with SR mask

level

Wait for completion of

sequence currently being

executed by CPU

X (≥ 0) The longest sequence is for

interrupt or address-error

exception processing (X = 4

+ m1 + m2 + m3 + m4). If an

interrupt-masking instruction

follows, however, the time

may be even longer.

Time from start of interrupt

exception processing until

fetch of first instruction of

exception service routine

starts

5 + m1 + m2 + m3 Performs the PC and SR

saves and vector address

fetch.

Interrupt Total: 7 + m1 + m2 + m3 9 + m1 + m2 + m3

response Minimum: 10 12 0.35–0.42 µs at 28.7 MHz

time Maximum: 12 + 2 (m1 + m2 +

m3) + m4 13 + 2 (m1 + m2 +

m3) + m4 0.67–0.70 µs at 28.7 MHz*

Note: *When m1 = m2 = m3 = m4 = 1

m1–m4 are the number of states needed for the following memory accesses.

m1: SR save (longword write)

m2: PC save (longword write)

m3: Vector address read (longword read)

m4: Fetch first instruction of interrupt service routine

116

FDE

MEEMMEEEFD

Interrupt acceptance

IRQ

m1 m2 1 m3 1

5 + m1 + m2 + m3

Instruction (instruction

replaced by interrupt

exception processing)

Overrun fetch

Interrupt service routine

start instruction

F:

D:

E:

Instruction fetch (instruction fetched from memory where program is stored).

Instruction decoding (fetched instruction is decoded).

Instruction execution (data operation and address calculation is performed

according to the results of decoding).

Memory access (data in memory is accessed).

Figure 6.5 Pipeline when an IRQ Interrupt is Accepted

6.6 Data Transfer with Interrupt Request Signals

The following data transfers can be done using interrupt request signals:

• Activate DMAC only, without generating CPU interrupt

• Activate DTC only, CPU interrupts according to DTC settings

Among interrupt sources, those designated as DMAC activating sources are masked and not input

to the INTC. The masking condition is listed below:

Mask condition = DME • (DE0 • source selection 0 + DE1 × source selection 1 + DE2 •

source selection 2 + DE3 • source selection 3)

The INTC masks CPU interrupts when the corresponding DTE bit is a 1. The DTE clear condition

and interrupt source flag clear condition are listed below.

DTE clear condition = DTC transfer end • DTECLR

Interrupt source flag clear condition = DTC transfer end • DTECLR + DMAC transfer end

Where: DTECLR = DISEL + counter 0.

Figure 6.6 shows a control block diagram.

117

Interrupt source

Interrupt source

flag clear 

(by DMAC) Interrupt source

(those not designated as DMAC activating sources)

CPU interrupt request

DTC activation

request

DTECLR

Transfer end

DTE clear

Interrupt source

flag clear (by DTC)

DTER

DMAC

Figure 6.6 Interrupt Control Block Diagram

6.6.1 Handling DTC Activating and CPU Interrupt Sources, but Not DMAC Activating

Sources

1. Either do not select the DMAC as a source, or clear the DME bit to 0.

2. For DTC, set the corresponding DTE bits and DISEL bits to 1.

3. Activating sources are applied to the DTC when interrupts occur.

4. When the DTC performs a data transfer, it clears the DTE bit to 0 and sends an interrupt

request to the CPU. The activating source does not clear.

5. The CPU clears interrupt sources with its interrupt processing routine. It then confirms the

transfer counter value. When the transfer counter value ≠ 0, it sets the DTE bit to 1 and allows

the next data transfer. If the transfer counter value = 0, it performs the necessary end

processing in the interrupt processing routine.

118

6.6.2 Handling DMAC Activating Sources but Not CPU Interrupt or DTC Activating

Sources

1. Select the DMAC as a source and set the DME bit to 1. CPU interrupt sources and DTC

activating sources are masked regardless of the interrupt priority level register settings or DTC

2. Activating sources are applied to the DMAC when interrupts occur.

3. The DMAC clears activating sources at the time of data transfer.

6.6.3 Handling DTC Activating Sources but Not CPU Interrupt or DMAC Activating

Sources

1. Either do not select the DMAC as a source, or clear the DME bit to 0.

2. For DTC, set the corresponding DTE bits to 1 and clear the DISEL bits to 0.

3. Activating sources are applied to the DTC when interrupts occur.

4. When the DTC performs a data transfer, it clears the activating source. An interrupt request is

not sent to the CPU, because the DTE bit is maintained as a 1.

5. However, when the transfer counter value = 0 the DTE bit is cleared to 0 and an interrupt

request is sent to the CPU.

6. The CPU performs the necessary end processing in the interrupt processing routine.

6.6.4 Treating CPU Interrupt Sources but Not DTC or DMAC Activating Sources

1. Either do not select the DMAC as a source, or clear the DME bit to 0.

2. For DTC, clear the corresponding DTE bits to 0.

3. When interrupts occur, interrupt requests are sent to the CPU.

4. The CPU clears the interrupt source and performs the necessary processing in the interrupt

processing routine.

119

Section 7 User Break Controller (UBC)

7.1 Overview

The user break controller (UBC) provides functions that simplify program debugging. Break

conditions are set in the UBC and a user break interrupt is generated according to the conditions of

the bus cycle generated by the CPU, DMAC, or DTC. This function makes it easy to design an

effective self-monitoring debugger, enabling the chip to easily debug programs without using a

large in-circuit emulator.

7.1.1 Features

The features of the user break controller are:

• Break compare conditions can be set:

 Address

 CPU cycle or DMA/DTC cycle

 Instruction fetch or data access

 Read or write

 Operand size: byte/word/longword

• User break interrupt generated upon satisfying break conditions. A user-designed user break

interrupt exception processing routine can be run.

• Select either to break in the CPU instruction fetch cycle before the instruction is executed or

after.

7.1.2 Block Diagram

Figure 7.1 shows a block diagram of the UBC.

120

Internal bus

Bus

interface

Break condition comparator

Module bus

UBBR UBAMRH UBARH

UBAMRL UBARL

Interrupt request

Interrupt controller

User break

interrupt

generating

circuit

UBC

UBARH, UBARL:

UBAMRH, UBAMRL:

UBBR:

User break address registers H, L

User break address mask registers H, L

User break bus cycle register

Figure 7.1 User Break Controller Block Diagram

7.1.3 Register Configuration

The UBC has the five registers shown in table 7.1. Break conditions are established using these

registers.

121

Table 7.1 Register Configuration

Name Abbr. R/W Initial

Value Address Access

Size

User break address register H UBARH R/W H'0000 H'FFFF8600 8, 16, 32

User break address register L UBARL R/W H'0000 H'FFFF8602 8, 16, 32

User break address mask register H UBAMRH R/W H'0000 H'FFFF8604 8, 16, 32

User break address mask register L UBAMRL R/W H'0000 H'FFFF8606 8, 16, 32

User break bus cycle register UBBR R/W H'0000 H'FFFF8608 8, 16, 32

7.2 Register Descriptions

7.2.1 User Break Address Register (UBAR)

The user break address register (UBAR) consists of user break address register H (UBARH) and

user break address register L (UBARL). Both are 16-bit readable/writable registers. UBARH

stores the upper bits (bits 31–16) of the address of the break condition, while UBARL stores the

lower bits (bits 15–0). Resets and hardware standbys initialize both UBARH and UBARL to

H'0000. They are not initialized in manual reset or software standby mode.

UBARH:

Bit: 15 14 13 12 11 10 9 8

UBARH UBA31 UBA30 UBA29 UBA28 UBA27 UBA26 UBA25 UBA24

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

UBARH UBA23 UBA22 UBA21 UBA20 UBA19 UBA18 UBA17 UBA16

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

122

UBARL:

Bit: 15 14 13 12 11 10 9 8

UBARL UBA15 UBA14 UBA13 UBA12 UBA11 UBA10 UBA9 UBA8

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

UBARL UBA7 UBA6 UBA5 UBA4 UBA3 UBA2 UBA1 UBA0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

• UBARH Bits 15–0—User Break Address 31–16 (UBA31–UBA16): These bits store the upper

bit values (bits 31–16) of the address of the break condition.

• UBARL Bits 15–0—User Break Address 15–0 (UBA15–UBA0): These bits store the lower bit

values (bits 15–0) of the address of the break condition.

7.2.2 User Break Address Mask Register (UBAMR)

The user break address mask register (UBAMR) consists of user break address mask register H

(UBAMRH) and user break address mask register L (UBAMRL). Both are 16-bit

readable/writable registers. UBAMRH designates whether to mask any of the break address bits

established in the UBARH, and UBAMRL designates whether to mask any of the break address

bits established in the UBARL. Resets and hardware standbys initialize both UBAMRH and

UBAMRL to H'0000. They are not initialized in manual reset or software standby mode.

UBAMRH:

Bit: 15 14 13 12 11 10 9 8

UBAMRH UBM31 UBM30 UBM29 UBM28 UBM27 UBM26 UBM25 UBM24

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

UBAMRH UBM23 UBM22 UBM21 UBM20 UBM19 UBM18 UBM17 UBM16

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

123

UBAMRL:

Bit: 15 14 13 12 11 10 9 8

UBAMRL UBM15 UBM14 UBM13 UBM12 UBM11 UBM10 UBM9 UBM8

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

UBAMRL UBM7 UBM6 UBM5 UBM4 UBM3 UBM2 UBM1 UBM0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

• UBAMRH Bits 15–0—User Break Address Mask 31–16 (UBM31–UBM16): These bits

designate whether to mask any of the break address 31–16 bits (UBA31–UBA16) established

in the UBARH.

• UBAMRL Bits 15–0—User Break Address Mask 15–0 (UBM15–UBM0): These bits

designate whether to mask any of the break address 15–0 bits (UBA15–UBA0) established in

the UBARL.

Bits 15–0: UBMn Description

0 Break address UBAn is included in the break conditions (initial value)

1 Break address UBAn is not included in the break conditions

Note: n = 31–0

7.2.3 User Break Bus Cycle Register (UBBR)

User break bus cycle register (UBBR) is a 16-bit readable/writable register that selects from

among the following four break conditions:

1. CPU cycle/ DMAC/DTC cycle

2. Instruction fetch/data access

3. Read/write

4. Operand size (byte, word, longword)

Resets and hardware standbys initialize the UBBR to H'0000. It is not initialized in software

standby mode.

124

Bit: 15 14 13 12 11 10 9 8

————————

Initial value: 0 0 0 0 0 0 0 0

R/W: R R R R R R R R

Bit: 7 6 5 4 3 2 1 0

CP1 CP0 ID1 ID0 RW1 RW0 SZ1 SZ0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bits 15–8—Reserved: These bits always read as 0. The write value should always be 0.

• Bits 7 and 6—CPU Cycle/Peripheral Cycle Select (CP1, CP0): These bits designate break

conditions for CPU cycles or peripheral cycles (DMA/DTC cycles).

Bit 7: CP1 Bit 6: CP0 Description

0 0 No user break interrupt occurs (initial value)

1 Break on CPU cycles

1 0 Break on peripheral cycles

1 Break on both CPU and peripheral cycles

• Bits 5 and 4—Instruction Fetch/Data Access Select (ID1, ID0): These bits select whether to

break on instruction fetch and/or data access cycles.

Bit 5: ID1 Bit 4: ID0 Description

0 0 No user break interrupt occurs (initial value)

1 Break on instruction fetch cycles

1 0 Break on data access cycles

1 Break on both instruction fetch and data access cycles

125

• Bits 3 and 2—Read/Write Select (RW1, RW0): These bits select whether to break on read

and/or write cycles.

Bit 3: RW1 Bit 2: RW0 Description

0 0 No user break interrupt occurs (initial value)

1 Break on read cycles

1 0 Break on write cycles

1 Break on both read and write cycles

• Bits 1 and 0—Operand Size Select (SZ1, SZ0): These bits select operand size as a break

condition.

Bit 1: SZ1 Bit 0: SZ0 Description

0 0 Operand size is not a break condition (initial value)

1 Break on byte access

1 0 Break on word access

1 Break on longword access

Note: When breaking on an instruction fetch, set the SZ0 bit to 0. All instructions are considered

to be word-size accesses (even when there are instructions in on-chip memory and 2

instruction fetches are done simultaneously in 1 bus cycle).

Operand size is word for instructions or determined by the operand size specified for the

CPU/DMAC data access. It is not determined by the bus width of the space being

accessed.

126

7.3 Operation

7.3.1 Flow of the User Break Operation

The flow from setting of break conditions to user break interrupt exception processing is described

below:

1. The user break addresses are set in the user break address register (UBAR), the desired masked

bits in the addresses are set in the user break address mask register (UBAMR) and the breaking

bus cycle type is set in the user break bus cycle register (UBBR). If even one of the three

groups of the UBBR’s CPU cycle/peripheral cycle select bits (CP1, CP0), instruction

fetch/data access select bits (ID1, ID0), and read/write select bits (RW1, RW0) is set to 00 (no

user break interrupt is generated), no user break interrupt will be generated even if all other

conditions are in agreement. When using user break interrupts, always be certain to establish

bit conditions for all of these three groups.

2. The UBC uses the method shown in figure 7.2 to judge whether set conditions have been

fulfilled. When the set conditions are satisfied, the UBC sends a user break interrupt request

signal to the interrupt controller (INTC).

3. The interrupt controller checks the accepted user break interrupt request signal’s priority level.

The user break interrupt has priority level 15, so it is accepted only if the interrupt mask level

in bits I3–I0 in the status register (SR) is 14 or lower. When the I3–I0 bit level is 15, the user

break interrupt cannot be accepted but it is held pending until user break interrupt exception

processing can be carried out. Consequently, user break interrupts within NMI exception

service routines cannot be accepted, since the I3–I0 bit level is 15. However, if the I3–I0 bit

level is changed to 14 or lower at the start of the NMI exception service routine, user break

interrupts become acceptable thereafter. Section 6, Interrupt Controller (INTC), describes the

handling of priority levels in greater detail.

4. The INTC sends the user break interrupt request signal to the CPU, which begins user break

interrupt exception processing upon receipt. See Section 6.4, Interrupt Operation, for details on

interrupt exception processing.

127

SZ1 SZ0

User

break

interrupt

RW1 RW0

ID1 ID0

CP1 CP0

UBARH/UBARL UBAMRH/UBAMRL

32 32

Internal address

bits 31–0

CPU cycle

DMA/DTC cycle

Instruction fetch

Data access

Read cycle

Write cycle

Byte size

Word size

Longword size

Figure 7.2 Break Condition Judgment Method

128

7.3.2 Break on On-Chip Memory Instruction Fetch Cycle

On-chip memory (on-chip ROM and/or RAM) is always accessed as 32 bits in 1 bus cycle.

Therefore, 2 instructions can be retrieved in 1 bus cycle when fetching instructions from on-chip

memory. At such times, only 1 bus cycle is generated, but by setting the start addresses of both

instructions in the user break address register (UBAR) it is possible to cause independent breaks.

In other words, when wanting to effect a break using the latter of two addresses retrieved in 1 bus

cycle, set the start address of that instruction in UBAR. The break will occur after execution of the

former instruction.

7.3.3 Program Counter (PC) Values Saved

Break on Instruction Fetch (Before Execution): The program counter (PC) value saved to the

stack in user break interrupt exception processing is the address that matches the break condition.

The user break interrupt is generated before the fetched instruction is executed. If a break

condition is set in an instruction fetch cycle placed immediately after a delayed branch instruction

(delay slot), or on an instruction that follows an interrupt-disabled instruction, however, the user

break interrupt is not accepted immediately, but the break condition establishing instruction is

executed. The user break interrupt is accepted after execution of the instruction that has accepted

the interrupt. In this case, the PC value saved is the start address of the instruction that will be

executed after the instruction that has accepted the interrupt.

Break on Data Access (CPU/Peripheral): The program counter (PC) value is the top address of

the next instruction after the last instruction executed before the user break exception processing

started. When data access (CPU/peripheral) is set as a break condition, the place where the break

will occur cannot be specified exactly. The break will occur at the instruction fetched close to

where the data access that is to receive the break occurs.

7.4 Use Examples

7.4.1 Break on CPU Instruction Fetch Cycle

1. Register settings: UBARH = H'0000

UBARL = H'0404

UBBR = H'0054

Conditions set: Address: H'00000404

Bus cycle: CPU, instruction fetch, read

(operand size not included in conditions)

A user break interrupt will occur before the instruction at address H'00000404. If it is possible for

the instruction at H'00000402 to accept an interrupt, the user break exception processing will be

executed after execution of that instruction. The instruction at H'00000404 is not executed. The

PC value saved is H'00000404.

129

2. Register settings: UBARH = H'0015

UBARL = H'389C

UBBR = H'0058

Conditions set: Address: H'0015389C

Bus cycle: CPU, instruction fetch, write

(operand size not included in conditions)

A user break interrupt does not occur because the instruction fetch cycle is not a write cycle.

3. Register settings: UBARH = H'0003

UBARL = H'0147

UBBR = H'0054

Conditions set: Address: H'00030147

Bus cycle: CPU, instruction fetch, read

(operand size not included in conditions)

A user break interrupt does not occur because the instruction fetch was performed for an even

address. However, if the first instruction fetch address after the branch is an odd address set by

these conditions, user break interrupt exception processing will be done after address error

exception processing.

7.4.2 Break on CPU Data Access Cycle

1. Register settings: UBARH = H'0012

UBARL = H'3456

UBBR = H'006A

Conditions set: Address: H'00123456

Bus cycle: CPU, data access, write, word

A user break interrupt occurs when word data is written into address H'00123456.

2. Register settings: UBARH = H'00A8

UBARL = H'0391

UBBR = H'0066

Conditions set: Address: H'00A80391

Bus cycle: CPU, data access, read, word

A user break interrupt does not occur because the word access was performed on an even address.

130

7.4.3 Break on DMA/DTC Cycle

1. Register settings: UBARH = H'0076

UBARL = H'BCDC

UBBR = H'00A7

Conditions set: Address: H'0076BCDC

Bus cycle: DMA/DTC, data access, read, longword

A user break interrupt occurs when longword data is read from address H'0076BCDC.

2. Register settings: UBARH = H'0023

UBARL = H'45C8

UBBR = H'0094

Conditions set: Address: H'002345C8

Bus cycle: DMA/DTC, instruction fetch, read

(operand size not included in conditions)

A user break interrupt does not occur because no instruction fetch is performed in the DMA/DTC

cycle.

7.5 Cautions on Use

7.5.1 On-Chip Memory Instruction Fetch

Two instructions are simultaneously fetched from on-chip memory. If a break condition is set on

the second of these two instructions but the contents of the UBC break condition registers are

changed so as to alter the break condition immediately after the first of the two instructions is

fetched, a user break interrupt will still occur when the second instruction is fetched.

7.5.2 Instruction Fetch at Branches

When a conditional branch instruction or TRAPA instruction causes a branch, instructions are

fetched and executed as follows:

1. Conditional branch instruction, branch taken: BT, BF

Instruction fetch cycles: Conditional branch instruction fetch → Next-instruction overrun

fetch → Next-instruction overrun fetch → Branch destination instruction fetch

Instruction execution: Conditional branch instruction execution → Branch destination

instruction execution

2. TRAPA instruction, branch taken: TRAPA

Instruction fetch cycles: TRAPA instruction fetch → Next-instruction overrun fetch

→ Next-instruction overrun fetch → Branch destination instruction fetch

131

Instruction execution: TRAPA instruction execution → Branch destination instruction

execution

3. Conditional delay branch instruction, branch taken: BT/S, BF/S

Instruction fetch cycles: Conditional delay branch instruction fetch → Next-instruction

fetch (delay slot) → Next-instruction overrun fetch → Branch destination instruction

fetch

Instruction execution: Conditional delay branch instruction execution → Delay slot

instruction execution → Branch destination instruction execution

When a conditional branch instruction or TRAPA instruction causes a branch, the branch

destination will be fetched after the next instruction or the one after that does an overrun fetch.

However, because the instruction that is the object of the break first breaks after a definite

instruction fetch and execution, the kind of overrun fetch instructions noted above do not

become objects of a break. If data access breaks are also included with instruction fetch breaks

as break conditions, a break occurs because the instruction overrun fetch is also regarded as

becoming a data break.

7.5.3 Contention between User Break and Exception Handling

If a user break is set for the fetch of a particular instruction, and exception handling with higher

priority than a user break is in contention and is accepted in the decode stage for that instruction

(or the next instruction), user break exception handling may not be performed after completion of

the higher-priority exception handling routine (on return by RTE).

Thus, if a user break condition has been set for the fetch of the branch destination instruction

following a branch (BRA, BRAF, BT, BF, BT/S, BF/S, BSR, BSRF, JMP, JSR, RTS, RTE,

exception handling), and exception handling for this branch destination instruction with a higher

priority than a user break interrupt is accepted, user break exception handling will not be

performed after completion of that exception handling routine.

Therefore, a user break condition must not be set for the fetch of the branch destination instruction

following a branch.

7.5.4 Break at Non-Delay Branch Instruction Jump Destination

When a branch instruction with no delay slot (including exception handling) jumps to the jump

destination instruction on execution of the branch, a user break will not be generated even if a user

break condition has been set for the first jump destination instruction fetch.

132

133

Section 8 Data Transfer Controller (DTC)

8.1 Overview

The SH7040 Series has an on-chip data transfer controller (DTC), which is activated either by

interrupts or software and can perform data transfers.

8.1.1 Features

• Arbitrary channel number transfer setting possible

 Transfer information can be established for each interrupt source

 Transfer information stored in memory

 Multiple data transfers possible (chain transfers) for one activating source

• Address space: 32-bit addresses can be designated for both transfer source and destination

• Transfer devices

 Memory: On-chip ROM, on-chip RAM, external ROM, external RAM

 On-chip peripheral modules (excluding DMAC/DTC)

 Memory-mapped external devices

• Abundant transfer modes

 Can select between normal mode/repeat mode/block transfer mode

 Can select between increment/decrement/fixed for source/destination address

• Transfer units can be set as byte/word/longword

• Interrupts activating the DTC can be requested of the CPU

 Interrupt requests can be generated to the CPU after completion of a data transfer

 Interrupt requests generated to the CPU after completion of all designated data transfers

• Transfers can be activated by software

134

8.1.2 Block Diagram

Figure 8.1 shows the DTC block diagram. DTC transfer information is located in memory.

CPU interrupt request

source clear control

Interrupt request

DTC

On-chip

ROM

On-chip

RAM

On-chip

peripheral

module

Peripheral bus

External bus

External

memory

Bus controller

control

Activation

control

Request

priority

control

Bus interface DTC module bus

DTMR

DTCR

DTSAR

DTDAR

DTIAR

DTER

DTCSR

DTBR

Internal bus

DTMR:

DTCR:

DTSAR:

DTDAR:

DTC mode register

DTC count register

DTC source address register

DTC destination address register



DTIAR:

DTER:

DTCSR:

DTBR:

DTC initial address register

DTC enable register

DTC control/status register

DTC information base register



External

device

(memory-

mapped)

Figure 8.1 DTC Block Diagram

135

8.1.3 Register Configuration

The DTC has five registers in memory used for storing transfer data: DTMR, DTCR, DTSAR,

DTDAR, and DTIAR. It is controlled by the three registers DTER (DTEA–DTEE), DTCSR, and

DTBR. The register configurations are listed in table 8.1.

Table 8.1 Register Configuration*1

Name Abbr. R/W Initial Value Address Access Size

DTC mode register DTMR —*2Undefined —*2—*2

DTC source address register DTSAR —*2Undefined —*2—*2

DTC destination address register DTDAR —*2Undefined —*2—*2

DTC initial address register DTIAR —*2Undefined —*2—*2

DTC transfer count register A DTCRA —*2Undefined —*2—*2

DTC transfer count register B DTCRB —*2Undefined —*2—*2

DTC enable register A DTEA R/W H'00 H'FFFF8700 8, 16, 32

DTC enable register B DTEB R/W H'00 H'FFFF8701 8, 16, 32

DTC enable register C DTEC R/W H'00 H'FFFF8702 8, 16, 32

DTC enable register D DTED R/W H'00 H'FFFF8703 8, 16, 32

DTC enable register E DTEE R/W H'00 H'FFFF8704 8, 16, 32

DTC control/status register DTCSR R/(W)*3H'0000 H'FFFF8706 8, 16, 32

DTC information base register DTBR R/W Undefined H'FFFF8708 16, 32

Notes: *1 DTC registers cannot be accessed by DMAC/DTC.

*2 DTC internal registers cannot be directly accessed.

*3 Only a 0 write after a 1 read is possible for the NMIF, AE bits of the DTCSR.

8.2 Register Description

8.2.1 DTC Mode Register (DTMR)

The DTC mode register (DTMR) is a 16-bit register that controls the DTC operation mode. The

contents of this register is located in memory.

136

Bit: 15 14 13 12 11 10 9 8

SM1 SM0 DM1 DM0 MD1 MD0 SZ1 SZ0

Initial value: ********

R/W: — — — — — — — —

Bit: 7 6 5 4 3 2 1 0

Bit name: DTS CHNE DISEL NMIM — — — —

Initial value: ********

R/W: — — — — — — — —

Note: *Initial value undefined.

• Bits 15–14—Source Address Mode 1, 0 (SM1, SM0): These bits designate whether to hold,

increment, or decrement the DTSAR after a data transfer.

Bit 15 (SM1) Bit 14 (SM0) Description

0 — DTSAR remains fixed

1 0 DTSAR is incremented after transfer

(+1 for byte unit transfer, +2 for word, +4 for longword)

1 1 DTSAR is decremented after transfer

(–1 for byte unit transfer, –2 for word, –4 for longword)

• Bits 13–12—Destination Address Mode 1, 0 (DM1, DM0): These bits designate whether to

hold, increment or decrement the DTDAR after a data transfer.

Bit 13 (DM1) Bit 12 (DM0) Description

0 — DTDAR remains fixed

1 0 DTDAR is incremented after transfer

(+1 for byte unit transfer, +2 for word, +4 for longword)

1 1 DTDAR is decremented after transfer

(–1 for byte unit transfer, –2 for word, –4 for longword)

137

• Bits 11–10—DTC Mode 1, 0 (MD1, MD0): These bits designate the DTC transfer mode.

Bit 11 (MD1) Bit 10 (MD0) Description

0 0 Normal mode

0 1 Repeat mode

1 0 Block transfer mode

1 1 Reserved (setting prohibited)

• Bits 9–8—DTC Data Transfer Size 1, 0 (SZ1, SZ0): These bits designate the data size for data

transfers.

Bit 9 (SZ1) Bit 8 (SZ0) Description

0 0 Byte (8 bits)

0 1 Word (16 bits)

1 0 Longword (32 bits)

1 1 Reserved (setting prohibited)

• Bit 7—DTC Transfer Mode Select (DTS): When in repeat mode or block transfer mode, this

bit designates whether the source side or destination side will be the repeat area or block area.

Bit 7 (DTS) Description

0 Destination side is the repeat area or block area

1 Source side is the repeat area or block area

• Bit 6—DTC Chain Enable (CHNE): This bit designates whether to perform continuous DTC

data transfers with the same activating source. Continued transfer information is read after the

16th byte from the start address of the previous transfer information.

Bit 6 (CHNE) Description

0 DTC data transfer end (activation wait state ensues)

1 DTC data transfer continue (read continue register information, execute

transfer)

138

• Bit 5—DTC Interrupt Select (DISEL): This bit designates whether to prohibit or allow

interrupt requests to the CPU after one-time DTC transfers.

Bit 5 (DISEL) Description

0 Prohibit interrupts to the CPU after DTC data transfer completion if the

transfer counter is not 0 (DTC clears the interrupt source flag of the

activating source to 0)

1 Allow interrupts to the CPU after DTC data transfer completion (DTC

clears the DTER bit for the interrupt of the activating source to 0)

• Bit 4—DTC NMI Mode (NMIM): This bit designates whether to terminate transfers when an

NMI is input during DTC transfers.

Bit 4 (NMIM) Description

0 Terminate DTC transfer upon an NMI

1 Continue DTC transfer until end of transfer being executed

• Bits 3–0—Reserved: They have no effect on DTC operation.

8.2.2 DTC Source Address Register (DTSAR)

The DTC source address register (DTSAR) is a 32-bit register that specifies the DTC transfer

source address. An even address indicates that the transfer size is word; a multiple-of-four address

means it is longword. The contents of this register is located in memory.

Bit: 31 30 29 28 27 … 43210

…

Initial value: *****…*****

R/W: — — — — — … — — — — —

Note: * Initial value is undefined.

8.2.3 DTC Destination Address Register (DTDAR)

The DTC destination address register (DTDAR) is a 32-bit register that specifies the DTC transfer

destination address. An even address indicates that the transfer size is word; a multiple-of-four

address means it is longword. The contents of this register are located in memory.

139

Bit: 31 30 29 28 27 … 43210

…

Initial value: *****…*****

R/W: — — — — — … — — — — —

Note: *Initial value is undefined.

8.2.4 DTC Initial Address Register (DTIAR)

The DTC initial address register (DTIAR) specifies the initial transfer source/transfer destination

address in repeat mode. In repeat mode, when the DTS bit is set to 1, specify the initial transfer

source address in the repeat area, and when the DTS bit is cleared to 0, specify the initial transfer

destination address in the repeat area.

The contents of this register are located in memory.

Bit: 31 30 29 28 27 … 43210

…

Initial value: *****…*****

R/W: — — — — — … — — — — —

Note: *Initial value is undefined.

8.2.5 DTC Transfer Count Register A (DTCRA)

DTCRA is a 16-bit register that specifies the number of DTC transfers. The contents of this

In normal mode it functions as a 16-bit transfer counter. The number of transfers is 1 when the set

value is H'0001, 65535 when it is H'FFFF, and 65536 when it is H'0000.

In repeat mode, DTCRAH maintains the transfer count and DTCRAL functions as an 8-bit

transfer counter. The number of transfers is 1 when the set value is DTCRAH = DTCRAL = H'01,

255 when they are H'FF, and 256 when it is H'00.

In block transfer mode it functions as a 16-bit transfer counter. The number of transfers is 1 when

the set value is H'0001, 65535 when it is H'FFFF, and 65536 when it is H'0000.

140

Bit: 15 14 8

DTCRAH

Initial value: ********

R/W: — — — — — — — —

Bit: 7 6 0

DTCRAL

Initial value: ********

R/W: — — — — — — — —

Note: * Initial value is undefined.

8.2.6 DTC Transfer Count Register B (DTCRB)

The DTCRB is a 16-bit register that designates the block length in block transfer mode. The

contents of this register is located in memory. The block length is 1 when the set value is H'0001,

65535 when it is H'FFFF, and 65536 when it is H'0000.

Bit: 15 14 13 12 11 10 9 8

Initial value: ********

R/W: — — — — — — — —

Bit: 7 6 5 4 3 2 1 0

Initial value: ********

R/W: — — — — — — — —

Note: *Initial value is undefined.

8.2.7 DTC Enable Registers (DTER)

The DTER (DTEA–DTEE) are five 8-bit readable/writable registers with bits allocated to each

interrupt source that activates the DTC. They set disable/enable for DTC activation for each

interrupt source. When a bit is 1, DTC activation by the corresponding interrupt source is enabled.

Interrupt sources for each of the DTEA–DTEE registers are indicated in table 8.2.

The DTER are initialized to H'00 by a power-on reset or in standby mode. Manual reset does not

initialize DTER.

141

For the A mask, overwrite this register as follows:

When clearing bit to 0: read the 1 bit to clear and write 0.

When setting bit to 1: read the 0 bit to set and write 1.

Bit: 7 6 5 4 3 2 1 0

DTE7 DTE6 DTE5 DTE4 DTE3 DTE2 DTE1 DTE0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W*R/W*R/W*R/W*R/W*R/W*R/W*R/W*

Note: *DTER bits can only be modified by writing 1 after reading 0, or writing 0 after reading 1.

8.2.8 DTC Control/Status Register (DTCSR)

The DTCSR is a 16-bit readable/writable register that sets disable/enable for DTC activation by

software, as well as the DTC vector addresses for software activation. It also indicates the DTC

transfer status.

The DTCSR is initialized to H'0000 by power-on resets and in standby mode. Manual reset does

not initialize DTCSR.

Bit: 15 14 13 12 11 10 9 8

— — — — — NMIF AE SWDTE

Initial value: 0 0 0 0 0 0 0 0

R/W: R R R R R R/W*1R/W*1R/W*2

Bit: 7 6 5 4 3 2 1 0

Bit name: DTVEC7 DTVEC6 DTVEC5 DTVEC4 DTVEC3 DTVEC2 DTVEC1 DTVEC0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W*3R/W*3R/W*3R/W*3R/W*3R/W*3R/W*3R/W*3 *4

Notes: *1 For the NMIF and AE bits, only a 0 write after a 1 read is possible.

*2 For the SWDTE bit, a 1 write is always possible, but a 0 write is possible only after a 1

is read.

*3 For the DTVEC7–DTVEC0 bits, writes are possible only when SWDTE = 0.

*4 Be sure to write 0 to the DTVEC0 bit.

Bits 15–11—Reserved: These bits always read as 0. The write value should always be 0.

142

• Bit 10—NMI Flag Bit (NMIF): Indicates that an NMI interrupt has occurred. When the NMIF

bit is set, DTC transfers are not allowed even if the DTER bit is set to 1. If, however, a transfer

has already started with the NMIM bit of the DTMR set to 1, execution will continue until that

transfer ends. To clear the NMIF bit, read the 1 from it, then write a 0.

The NMIF bit is initialized to 0 by power-on resets and in standby mode.

Bit 10 (NMIF) Description

0 No NMI interrupts (initial value)

(Clear condition) Write a 0 after reading the NMIF bit

1 NMI interrupt has been generated

• Bit 9—Address Error Flag (AE): Indicates that an address error by the DTC has occurred.

When the AE bit is set, DTC transfers are not allowed even if the DTER bit is set to 1. To clear

the AE bit, read the 1 from it, then write a 0.

The AE bit is initialized to 0 by power-on resets and in standby mode.

Bit 9 (AE) Description

0 No address error by the DTC (initial value)

(Clear condition) Write a 0 after reading the AE bit

1 An address error by the DTC occurred

• Bit 8—DTC Software Activation Enable Bit (SWDTE): This bit enables/disables DTC

activation by software.

The AE bit is initialized to 0 by resets and standby mode. For details, see section 8.3.2,

Activating Sources.

Bit 8 (SWDTE) Description

0 DTC activation by software disabled (initial value)

1 DTC activation by software enabled

• Bits 7–0—Software Activation Vectors 7–0 (DTVEC7–DTVEC0): These bits set the DTC

vector addresses for DTC activation by software. A vector address is calculated as H'0400 +

DTVEC[7:0]. Always specify 0 for DTVEC0. 8 bits are available, so you can specify values

H'00 (0)–H'FE (254).

143

8.2.9 DTC Information Base Register (DTBR)

The DTBR is a 16-bit readable/writable register that specifies the upper 16 bits of the memory

address containing DTC transfer information. Always access the DTBR in word or longword

units. If it is accessed in byte units the register contents will become undefined at the time of a

write, and undefined values will be read out upon reads.

The DTBR is not initialized either by resets or in standby mode.

Bit: 15 14 13 12 11 10 9 8

Initial value: ********

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

Initial value: ********

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Note: *Initial value is undefined.

8.3 Operation

The DTC stores transfer information in memory. When there are DTC transfer requests, it reads

that transfer information and performs data transfers based on it. It rewrites the transfer

information to memory after data transfers. Storing transfer information in memory makes it

possible to perform data transfers for an arbitrary number of channels. Further, setting the CHNE

bit to 1 makes it possible to perform multiple transfers continuously through one DTC transfer

request.

There are three DTC transfer modes: normal mode, repeat mode, and block transfer mode. After a

DTC transfer, the transfer source address and transfer destination address are incremented,

decremented, or kept the same, according to the respective setting.

8.3.1 Overview of Operation

Figure 8.2 shows a flowchart of DTC operation.

144

Yes

Start



Initial settings

DTMR, DTCR, DTIAR, DTSAR, DTDAR



Transfer request

generated?



NMIF = AE = 0?

DTC vector read

Transfer information read



DTCRA = DTCRA – 1 (normal/block transfer mode)

DTCRAL = DTCRAL – 1 (repeat mode)

DTSAR, DTDAR update

DTCRB = DTCRB – 1 (block transfer mode)

Transfer (1 transfer unit)

Block

transfer mode and

DTCRB ≠ 0?

Transfer information write



NMI or address error



End

Transfer information write



CHNE = 0?

NMIF • NMIM

+ AE = 1?

When DISEL = 1 or DTCRA = 0 (normal/block transfer mode)

When DISEL = 1 (repeat transfer mode)



CPU interrupt request

Figure 8.2 DTC Operation Flowchart

145

8.3.2 Activating Sources

The DTC performs write operations to the DTCSR with either interrupt sources or software as its

activating sources. Each interrupt source is designated by specific DTER bits to determine whether

it becomes an interrupt request to the CPU or a DTC activating source.

When the DISEL bit is 1, an interrupt, established as the DTC activating source, is requested of

the CPU after each data transfer in DRC. When the DISEL bit is a 0, a request is made only after

the completion of a designated number of data transfers. When the activating source interrupt is

requested of the CPU, the corresponding DTER bit is automatically cleared.

In the case of software activation also, when the DISEL bit is a 1, a software DTC activation

interrupt (SWDTCE) is requested of the CPU after each data transfer. When the DISEL bit is a 0,

a request is made only after the completion of a designated number of data transfers. When no

SWDTCE interrupt is requested of the CPU, the SWDTE bit of the DTCSR is automatically

cleared. When a request is made of the CPU, the SWDTE bit is maintained as a 1.

When multiple DTC activating sources occur simultaneously, they are accepted and the DTC is

activated in accordance with the default priority rankings shown in table 8.2.

Figure 8.3 shows a block diagram of activating source control.

IRQ

On-chip 

peripheral



Interrupt 

requests



Source

flag clear

Source flag clear



Interrupt requests 

(those not designated as 

DMAC activating sources)



CPU Interrupt requests 

(those not designated as



DTC activating sources)



Clear

DTC activation request



DTC 

control



DTER

DTC

INTC

DMAC

Figure 8.3 Activating Source Control Block Diagram

8.3.3 DTC Vector Table

Figure 8.4 shows the correspondence between DTC vector addresses and register information

placement. For each DTC activating source there are 2 bytes in the DTC vector table, which

contain the register information start address.

Table 8.2 shows the correspondence between activating sources and vector addresses. When

activating with software, the vector address is calculated as H'0400 + DTVEC[7:0].

146

Through DTC activation, a register information start address is read from the vector table, then

Always designate register information start addresses in multiples of four.

start address

DTBR

(upper 16 bits)



Memory space



DTC vector table

Register

information

DTC vector address

information

start address

(lower 16 bits)

Figure 8.4 Correspondence between DTC Vector Address and Register Information

147

Table 8.2 Interrupt Sources and DTC Vector Addresses

Source

Generator Activating

Source DTC Vector Address DTE

Bit Transfer

Source Transfer

Destination Priority

MTU TGI4A H'00000400–H'00000401 DTEA7 Arbitrary*1Arbitrary*1High

(CH4) TGI4B H'00000402–H'00000403 DTEA6 Arbitrary*1Arbitrary*1

TGI4C H'00000404–H'00000405 DTEA5 Arbitrary*1Arbitrary*1

TGI4D H'00000406–H'00000407 DTEA4 Arbitrary*1Arbitrary*1

TCI4V H'00000408–H'00000409 DTEA3 Arbitrary*1Arbitrary*1

MTU TGI3A H'0000040A–H'0000040B DTEA2 Arbitrary*1Arbitrary*1

(CH3) TGI3B H'0000040C–H'0000040D DTEA1 Arbitrary*1Arbitrary*1

TGI3C H'0000040E–H'0000040F DTEA0 Arbitrary*1Arbitrary*1

TGI3D H'00000410–H'00000411 DTEB7 Arbitrary*1Arbitrary*1

MTU TGI2A H'00000412–H'00000413 DTEB6 Arbitrary*1Arbitrary*1

(CH2) TGI2B H'00000414–H'00000415 DTEB5 Arbitrary*1Arbitrary*1

MTU TGI1A H'00000416–H'00000417 DTEB4 Arbitrary*1Arbitrary*1

(CH1) TGI1B H'00000418–H'00000419 DTEB3 Arbitrary*1Arbitrary*1

MTU TGI0A H'0000041A–H'0000041B DTEB2 Arbitrary*1Arbitrary*1

(CH0) TGI0B H'0000041C–H'0000041D DTEB1 Arbitrary*1Arbitrary*1

TGI0C H'0000041E–H'0000041F DTEB0 Arbitrary*1Arbitrary*1

TGI0D H'00000420–H'00000421 DTEC7 Arbitrary*1Arbitrary*1

A/D ADI(ADI0)*2H'00000422–H'00000423 DTEC6 ADDR Arbitrary*1

IRQ0 pin IRQ0 H'00000424–H'00000425 DTEC5 Arbitrary*1Arbitrary*1

IRQ1 pin IRQ1 H'00000426–H'00000427 DTEC4 Arbitrary*1Arbitrary*1

IRQ2 pin IRQ2 H'00000428–H'00000429 DTEC3 Arbitrary*1Arbitrary*1

IRQ3 pin IRQ3 H'0000042A–H'0000042B DTEC2 Arbitrary*1Arbitrary*1

IRQ4 pin IRQ4 H'0000042C–H'0000042D DTEC1 Arbitrary*1Arbitrary*1

IRQ5 pin IRQ5 H'0000042E–H'0000042F DTEC0 Arbitrary*1Arbitrary*1

IRQ6 pin IRQ6 H'00000430–H'00000431 DTED7 Arbitrary*1Arbitrary*1

IRQ7 pin IRQ7 H'00000432–H'00000433 DTED6 Arbitrary*1Arbitrary*1

CMT (CH0) CMI0 H'00000434–H'00000435 DTED5 Arbitrary*1Arbitrary*1

CMT (CH1) CMI1 H'00000436–H'00000437 DTED4 Arbitrary*1Arbitrary*1Low

148

Table 8.2 Interrupt Sources and DTC Vector Addresses (cont)

Source

Generator Activating

Source DTC Vector Address DTE

Bit Transfer

Source Transfer

Destination Priority

SCI0 RXI0 H'00000438–H'00000439 DTED3 RDR0 Arbitrary*1High

TXI0 H'0000043A–H'0000043B DTED2 Arbitrary*1TDR0

SCI1 RXI1 H'0000043C–H'0000043D DTED1 RDR1 Arbitrary*1

TXI1 H'0000043E–H'0000043F DTED0 Arbitrary*1TDR1

BSC CMI H'00000440–H'00000441 DTEE7 Arbitrary*1Arbitrary*1

Software Write to

DTCSR H'00000400 + DTVEC[7:0] to

H'00000401 + DTVEC[7:0] — Arbitrary*1Arbitrary*1

Low

Notes: *1 External memory, memory-mapped external devices, on-chip memory, on-chip

peripheral modules (excluding DMAC and DTC)

*2 Excluding A mask products are ADI, A mask products are ADI0.

8.3.4 Register Information Placement

Figure 8.5 shows the placement of register information in memory space. The register information

start addresses are designated by DTBR for the upper 16 bits, and the DTC vector table for the

lower 16 bits.

The placement in order from the register information start address in normal mode is DTMR,

DTCRA, 4 bytes empty (no effect on DTC operation), DTSAR, then DTDAR. In repeat mode it is

DTMR, DTCRA, DTIAR, DTSAR, and DTDAR. In block transfer mode, it is DTMR, DTCRA, 2

bytes empty (no effect on DTC operation), DTCRB, DTSAR, then DTDAR.

Fundamentally, certain RAM areas are designated for addresses storing register information.

149

information

start address

Memory space Memory space Memory space

information



Normal mode Repeat mode

Block transfer mode



DTMR

DTCRA

DTSAR

DTDAR

DTMR

DTCRA

DTSAR

DTDAR

DTIAR

DTMR

DTCRA

DTSAR

DTDAR

DTCRB

Figure 8.5 DTC Register Information Placement in Memory Space

8.3.5 Normal Mode

Performs the transfer of one byte, one word, or one longword for each activation. The total

transfer count is 1 to 65536. An interrupt request is generated to the CPU when the transfer with

DTCRA = 1 ends. Transfers of a number of bytes specified by the SCI are possible.

Table 8.3 shows the register functions for normal mode.

Table 8.3 Normal Mode Register Functions

Values Written Back upon a

Transfer Information Write

is other than 1 When DTCRA is 1

DTMR Operation mode

control DTMR DTMR

DTCRA Transfer count DTCRA – 1 DTCRA – 1 (= H'0000)

DTSAR Transfer source

address Increment/decrement/

fixed Increment/decrement/

fixed

DTDAR Transfer destination

address Increment/decrement/

fixed Increment/decrement/

fixed

8.3.6 Repeat Mode

Performs the transfer of one byte, one word, or one longword for each activation. Either the

transfer source or transfer destination is designated as the repeat area.

150

The total transfer count is specified between 1 and 256. When the specified number of transfers

ends, the address register of the designated repeat area is returned to its initial state and the transfer

is repeated. Other address registers are consecutively incremented, decremented, or remain fixed.

While DISEL = 0, no interrupt request is made to the CPU, even if the transfer with DTCRAL = 1

ends.

Pulses for driving the stepping motor can be output. Table 8.4 shows the register functions for

repeat mode.

Table 8.4 Repeat Mode Register Functions

Values Written Back upon a

Transfer Information Write

other than 1 When DTCRA is 1

DTMR Operation mode

control DTMR DTMR

DTCRAH Transfer count

maintenance DTCRAH DTCRAH

DTCRAL Transfer count DTCRAL – 1 DTCRAH

DTIAR Initial address (Not written back) (Not written back)

DTSAR Transfer source

address Increment/decrement/

fixed (DTS = 0) Increment/

decrement/ fixed

(DTS = 1) DTIAR

DTDAR Transfer destination

address Increment/decrement/

fixed (DTS = 0) DTIAR

(DTS = 1) Increment/

decrement/ fixed

8.3.7 Block Transfer Mode

Performs the transfer of one block for each one activation. Either the transfer source or transfer

destination is designated as the block area.

The block length is specified between 1 and 65536. When a 1-block transfers ends, the address

consecutively incremented, decremented, or remain fixed. The block transfer count is 1 to 65536.

An interrupt request is generated to the CPU when the transfer with DTCRA = 1 ends.

A/D converter group mode transfers and phase compensation PWM data transfers are possible.

Table 8.5 shows the register functions for block transfer mode.

151

Table 8.5 Block Transfer Mode Register Functions

Transfer Information Write

DTMR Operation mode

control DTMR

DTCRA Transfer count DTCRA – 1

DTCRB Block length (Not written back)

DTSAR Transfer source

address (DTS = 0) Increment/ decrement/ fixed

(DTS = 1) DTSAR initial value

DTDAR Transfer destination

address (DTS = 0) DTDAR initial value

(DTS = 1) Increment/ decrement/ fixed

8.3.8 Operation Timing

Figure 8.6 shows a DTC operation timing example.

Activating

source

DTC

request

Address Vector

read



Data

transfer



Transfer

information

read

Transfer

information

write



Figure 8.6 DTC Operation Timing Example (Normal Mode)

When register information is located in on-chip RAM, each mode requires 4 cycles for transfer

information reads, and 3 cycles for writes.

8.3.9 DTC Execution State Counts

Table 8.6 shows the execution state for one DTC data transfer. Furthermore, table 8.7 shows the

state counts needed for execution state.

152

Table 8.6 Execution State of DTC

Mode Vector Read I

Information

Read/Write J Data Read K Data Write L Internal

Operation M

Normal 1 7 1 1 1

Repeat 1 7 1 1 1

Block transfer 1 7 N N 1

Note: N: block size (default set values of DTCRB)

Table 8.7 State Counts Needed for Execution State

Access Objective

On-

chip

RAM

On-

chip

ROM Internal I/O

Bus width 32 32 32 8 16 32

Access

state 112

*13*2222

Execution Vector read SI—1 — 4 2 2

state Register information

read/write SJ11— 842

Byte data read SK1123222

Word data read SK1123422

Long word data read SK1146842

Byte data write SL1123222

Word data write SL1123422

Long word write SL1146842

Internal operation SM1

Notes: *1 Two state access module : port, INT, CMT, SCI, etc.

*2 Three state access module : WDT, CACHE, UBC, etc.

The execution state count is calculated using the following formula. ∑ indicates the number of

transfers by one activating source (count + 1 when CHNE bit is 1).

Execution state count = I · SI + ∑ (J · SJ + K · SK + L · SL) + M · SM

153

8.3.10 DTC Usage Procedure

The procedure for DTC interrupt activation is as follows:

1. Transfer data (DTMR, DTCRA, DTSAR, DTDAR, DTCRB, and DTIAR) is located in

memory space.

2. Establish the register information start address with DTBR and the DTC vector table.

3. Set the corresponding DTER bit to 1.

4. The DTC is activated when an interrupt source occurs.

5. When interrupt requests are not made to the CPU, the interrupt source is cleared, but the DTER

is not. When interrupts are requested, the interrupt source is not cleared, but the DTER is.

6. Interrupt sources are cleared within the CPU interrupt routine. When doing continuous DTC

data transfers, set the DTER to 1.

The procedure for DTC software activation is as follows:

1. Transfer data (DTMR, DTCRA, DTSAR, DTDAR, DTCRB, and DTIAR) is located in

memory space.

2. Establish the register information start address with DTBR and the DTC vector table.

3. Confirm that the SWDTE bit of the DTCSR is 0. When the SWDTE bit is 1, the DTC is

already being driven by software.

4. Write a 1 to the SWDTE bit and a vector number to the DTVEC (byte data).

5. When SWDTCE interrupt requests are not made to the CPU, the SWDTE bit is cleared. When

interrupts are requested, the SWDTE bit is maintained as a 1.

6. The SWDTE bit is cleared to 0 within the CPU interrupt routine. For continuous DTC data

transfers, set the SWDTE to 1.

8.3.11 DTC Use Example

The following is a DTC use example of a 128-byte data reception by the SCI:

1. The settings are: DTMR source address fixed (SM1 = 0), destination address incremented

(DM1 = 1, DM0 = 0), normal mode (MD1 = MD0 = 0), byte size (SZ1 = SZ0 = 0), one

transfer per activating source (CHNE = 0), and a CPU interrupt request after the designated

number of data transfers (DISEL = 0). 128 (H'0080) is set in DTCRA, the RDR address of the

SCI is set in DTSAR, and the start address of the RAM storing the receive data is set in

DTDAR.

2. Establish the register information start address with DTBR and the DTC vector table.

3. Set the corresponding DTER bit to 1.

4. Set the SCI to a specific receive mode and enable RxI interrupts.

154

5. The RDRF flag of the SSR is set to 1 by each completion of a 1-byte data reception by the SCI,

an RxI interrupt is generated, and the DTC is activated. The received data is transferred from

RDR to RAM by the DTC, and the RDRF flag is 0 cleared.

6. After completion of 128 data transfers (DTCRA = 0), the DTER is cleared while the RDRF is

maintained as 1, and an RxI interrupt request is made to the CPU. The interrupt processing

routine clears the RDRF, and performs the other completion processing.

8.4 Cautions on Use

• DMAC and DTC register access by the DTC is prohibited.

• DTC register access by the DMAC is prohibited.

• When setting a bit in DTER, first ensure that all transfers on the DTC channel corresponding to

that DTER have ended, or disable the transfer source for each channel so that DTC transfer

corresponding to that DTER will not occur. The above restrictions do not apply for A mask

due to change in the access method of DTER. However, take caution when changing LSI to A

mask, since modification of the program is required.

155

Section 9 Cache Memory (CAC)

9.1 Overview

The LSI has an on-chip cache memory (CAC) with 1 kbyte of cache data and a 256-entry cache

tag. The cache data and cache tag space can be used as on-chip RAM space when the cache is not

being used.

9.1.1 Features

The CAC has the following features. The cache tag and cache data configuration is shown in

figure 9.1.

• 1-kbyte capacity

• External memory (CS space and DRAM space) instruction code and PC relative data caching

• 256 entry cache tag (tag address 15 bits)

• 4-byte line length

• Direct map replacement algorithm

• Valid flag (1 bit) included for purges

Cache tag



256 entries

Data (32 bits)



Tag address (15 bits)



Cache data



Data bus



Hit signal

CPU 

address Tag 

address Entry 

address Offset

Valid bit (1 bit)

CMP

15 82

Figure 9.1 Cache Tag and Cache Data Configuration

156

9.1.2 Block Diagram

Figure 9.2 shows a block diagram of the cache.

CCR: Cache control register



Cache tag



Cache

controller



Cache data



Internal address bus



Internal data bus



Bus state

controller



External bus

interface



CCR

Cache



Figure 9.2 Cache Block Diagram

9.1.3 Register Configuration

The cache has one register, which can be used to control the enabling or disabling of each cache

space. The register configuration is shown in table 9.1.

157

Table 9.1 Register Configuration

Name Abbreviation R/W Initial

Value Address Access Size

(Bits)

Cache control register CCR R/W H'0000*H'FFFF8740 8, 16, 32

Note: *Bits 15–5 are undefined.

9.2 Register Explanation

9.2.1 Cache Control Register (CCR)

The cache control register (CCR) selects the cache enable/disable of each space.

The CCR is a 16-bit readable/writable register. It is initialized to H'0000 by power on resets, but is

not initialized by manual resets or standby mode.

Bit: 15 14 13 12 11 10 9 8

————————

Initial value: ********

R/W: R R R R R R R R

Bit: 7 6 5 4 3 2 1 0

———CE

DRAM CE

CS3 CE

CS2 CE

CS1 CE

CS0

Initial value: ***00000

R/W: R R R R/W R/W R/W R/W R/W

Note: *Bits 15–5 are undefined.

• Bits 15–5—Reserved: Reading these bits gives undefined values. The write value should

always be 0.

• Bit 4—DRAM Space Cache Enable (CEDRAM): Selects whether to use DRAM space as a

cache object (enable) or to exclude it (disable). A 0 disables, and a 1 enables such use.

Bit 4 (CEDRAM) Description

0 DRAM space cache disabled (initial value)

1 DRAM space cache enabled

158

• Bit 3—CS3 Space Cache Enable (CECS3): Selects whether to use CS3 space as a cache object

(enable) or to exclude it (disable). A 0 disables, and a 1 enables such use.

Bit 3 (CECS3) Description

0 CS3 space cache disabled (initial value)

1 CS3 space cache enabled

• Bit 2—CS2 Space Cache Enable (CECS2): Selects whether to use CS2 space as a cache object

(enable) or to exclude it (disable). A 0 disables, and a 1 enables such use.

Bit 2 (CECS2) Description

0 CS2 space cache disabled (initial value)

1 CS2 space cache enabled

• Bit 1—CS1 Space Cache Enable (CECS1): Selects whether to use CS1 space as a cache object

(enable) or to exclude it (disable). A 0 disables, and a 1 enables such use.

Bit 1 (CECS1) Description

0 CS1 space cache disabled (initial value)

1 CS1 space cache enabled

• Bit 0—CS0 Space Cache Enable (CECS0): Selects whether to use CS0 space as a cache object

(enable) or to exclude it (disable). A 0 disables, and a 1 enables such use.

Bit 0 (CECS0) Description

0 CS0 space cache disabled (initial value)

1 CS0 space cache enabled

9.3 Address Array and Data Array

There is a special cache space for controlling the cache. This space is divided into an address array

and a data array, where addresses (tag address, including valid bit) and data (4-byte line length) for

cache control are recorded. The special cache space is shown in table 9.2. It can be used as on-chip

RAM space when the cache is not being used.

159

Table 9.2 Special Cache Space

Space Classification Address Size Bus Width

Address array H'FFFFF000–H'FFFFF3FF 1 kbyte 32 bit

Data array H'FFFFF400–H'FFFFF7FF 1 kbyte 32 bit

9.3.1 Cache Address Array Read/Write Space

The cache address array has a compulsory read/write (figure 9.3).

Address Upper 22 bits of the address array space address

(22 bits) –

(2 bits)

Entry address

(8 bits)

31 02110 9

Data –

(6 bits) –

(10 bits)

Tag address

(15 bits)

Valid bit (1 bit)

31 010 926 25 24

Figure 9.3 Cache Address Array

Address Array Read: Designates entry address and reads out the corresponding tag address

value/valid bit value.

Address Array Write: Designates entry address and writes the designated tag address value/valid

bit value.

9.3.2 Cache Data Array Read/Write Space

The cache data array has a compulsory read/write (figure 9.4).

Address Upper 22 bits of the data array space address

(22 bits) –

(2 bits)

Entry address

(8 bits)

31 02110 9

Data Data

(32 bits)

31 0

Figure 9.4 Cache Data Array

Data Array Read: Designates entry address and reads out the corresponding line of data.

Data Array Write: Designates entry address and writes designated data to the corresponding line.

160

9.4 Cautions on Use

9.4.1 Cache Initialization

Always initialize the cache before enabling it. Specifically, use an address array write to write 0 to

all valid bits for all entries (256 times), that is,those in the address range H'FFFFF000–

H'FFFFF3FF.

Writes to the address array or data array by the CPU, DMAC, or DTC are not possible while the

cache is enabled. For reads, undefined values will be read out.

9.4.2 Forced Access to Address Array and Data Array

While the cache is enabled, it is not possible to write to the address array or data array via the

CPU, DMAC, or DTC, and a read will return an undefined value. The cache must be disabled

before making a forced access to the address array or data array.

9.4.3 Cache Miss Penalty and Cache Fill Timing

When a cache miss occurs, a single idle cycle is generated as a penalty immediately before the

cache fill (access from external memory in the event of a cache miss), as shown in figure 9.5.

However, in the case of consecutive cache misses, idle cycles are not generated for the second and

subsequent cache misses, as shown in figure 9.6.

As the timing for a cache fill from normal space, the CS assert period immediately before the end

of the bus cycle (or the last bus cycle when two or four bus cycles are generated, such as in a word

access to 8-bit space) is extended by an additional cycle, as shown in figures 9.5 and 9.6.

Similarly, as the timing for a cache fill from DRAM space, the RAS assert period immediately

before the end of the bus cycle is extended by an additional cycle. In RAS down mode, the next

bus cycle is delayed by one cycle as shown in figure 9.8.

161

Miss-hit

Internal

address

Address

CSn

Data

Idle cycle

CS assert extension

Figure 9.5 Cache Fill Timing in Case of Non-Consecutive Cache Miss from Normal Space

(No Wait, No CS Assert Extension)

Miss-hit

Internal

address

Address

CSn

Data

CS assert additional extension

Figure 9.6 Cache Fill Timing in Case of Consecutive Cache Misses from Normal Space

(No Wait, CS Assert Extension)

162

Idle cycle

Internal

address

Address

RAS

CASxx

Data

ROW COLUMN

Miss-hit

RAS assert extension

Figure 9.7 Cache Fill Timing in Case of Non-Consecutive Cache Miss from DRAM Space

(Normal Mode, TPC = 0, RCD = 0, No Wait)

Miss-hit

ROW COLUMN CS space

Wait COLUMN

RAS assert extension

Internal

address

Address

RAS

CASxx

Data

DRAM access CS space

access DRAM access

Miss-hit

Figure 9.8 Cache Fill Timing in Case of Consecutive Cache Misses from DRAM Space

(RAS Down Mode, TPC = 0, RCD = 0, No Wait)

9.4.4 Cache Hit after Cache Miss

The first cache hit after a cache miss is regarded as a cache miss, and a cache fill without idle

cycle generation is performed. The next hit operates as a cache hit.

163

Section 10 Bus State Controller (BSC)

10.1 Overview

The bus state controller (BSC) divides up the address spaces and outputs control for various types

of memory. This enables memories like DRAM, SRAM, and ROM to be linked directly to the LSI

without external circuitry.

10.1.1 Features

The BSC has the following features:

• Address space is divided into five spaces

 A maximum linear 2 Mbytes for on-chip ROM effective mode, and a maximum linear

4-Mbyte for on-chip ROM ineffective mode for address space CS0

 A maximum linear 4 Mbytes for each of the address spaces CS1–CS3

 A maximum linear 16 Mbytes for DRAM dedicated space

 Bus width can be selected for each space (8, 16, or 32 bits)

 Wait states can be inserted by software for each space

 Wait states can be inserted via the WAIT pin in external memory spce accesses.

 Outputs control signals for each space according to the type of memory connected

• On-chip ROM and RAM interfaces

 On-chip RAM access of 32 bits in 1 state

 On-chip ROM access of 32 bits in 1 state

• Direct interface to DRAM

 Multiplexes row/column addresses according to DRAM capacity

 Supports high-speed page mode and RAS down mode

• Access control for each type of memory, peripheral LSI

 Address/data multiplex function

• Refresh

 Supports CAS-before-RAS refresh (auto-refresh) and self-refresh

• Refresh counter can be used as an interval timer

 Interrupt request generated upon compare match (CMI interrupt request signal)

164

10.1.2 Block Diagram

Figure 10.1 shows the BSC block diagram.

WCR1

WCR2

BCR1

BCR2

DCR

CMI interrupt request

WAIT

RTCSR

RTCNT

RTCOR

Internal bus

Interrupt

controller

Bus

interface

Area

control

unit

Comparator

Module bus

CS0 to CS3

RDWR

Wait

control

unit

Memory

control

unit

Peripheral bus

WRHH, WRHL

WRH, WRL

CASHH, CASHL

CASH, CASL

RAS

BSC

WCR1:

WCR2:

BCR1:

BCR2:

Wait control register 1

Wait control register 2

Bus control register 1

Bus control register 2

DCR:

RTCNT:

RTCOR:

RTSCR:

DRAM area control register

Refresh timer counter

Refresh timer constant register

Refresh timer control/status register

Figure 10.1 BSC Block Diagram

165

10.1.3 Pin Configuration

Table 10.1 shows the bus state controller pin configuration.

Table 10.1 Pin Configuration

Signal I/O Description

A21–A0 O Address output (A21–A18 will become input ports with power-on reset)

D31–D0 I/O 32-bit data bus. D15-D0 are address output and data I/O during address/data

multiplex I/O.

CS0–

CS3 O Chip select

RD O Strobe that indicates the read cycle for ordinary space/multiplex I/O. Also

output during DRAM access.

WRHH O Strobe that indicates a write cycle to the most significant byte (D31–D24) for

ordinary space/multiplex I/O. Also output during DRAM access.

WRHL O Strobe that indicates a write cycle to the 2nd byte (D23–D16) for ordinary

space/multiplex I/O. Also output during DRAM access.

WRH O Strobe that indicates a write cycle to the 3rd byte (D15–D8) for ordinary

space/multiplex I/O. Also output during DRAM access.

WRL O Strobe that indicates a write cycle to the least significant byte (D7–D0) for

ordinary space/multiplex I/O. Also output during DRAM access.

RDWR O Strobe indicating a write cycle to DRAM (used for DRAM space)

RAS O RAS signal for DRAM (used for DRAM space)

CASHH O CAS signal when accessing the most significant byte (D31–D24) of DRAM

(used for DRAM space)

CASHL O CAS signal when accessing the 2nd byte (D23–D16) of DRAM (used for DRAM

space)

CASH O CAS signal when accessing the 3rd byte (D15–D8) of DRAM (used for DRAM

space)

CASL O CAS signal when accessing the least significant byte (D7–D0) of DRAM (used

for DRAM space)

AH O Signal to hold the address during address/data multiplex

WAIT I Wait state request signal

BREQ I Bus release request input

BACK O Bus use enable output

166

10.1.4 Register Configuration

The BSC has eight registers. These registers are used to control wait states, bus width, and

interfaces with memories like DRAM, ROM, and SRAM, as well as refresh control. The register

configurations are listed in table 10.2.

All registers are 16 bits. Do not access DRAM space before completing the memory interface

settings. All BSC registers are all initialized by a power-on reset, but are not by a manual reset.

Values are maintained in standby mode.

Table 10.2 Register Configuration

Name Abbr. R/W Initial Value Address Access Size

Bus control register 1 BCR1 R/W H'200F H'FFFF8620 8, 16, 32

Bus control register 2 BCR2 R/W H'FFFF H'FFFF8622 8, 16, 32

Wait state control register 1 WCR1 R/W H'FFFF H'FFFF8624 8, 16, 32

Wait state control register 2 WCR2 R/W H'000F H'FFFF8626 8, 16, 32

DRAM area control register DCR R/W H'0000 H'FFFF862A 8, 16, 32

Refresh timer control/status register RTCSR R/W H'0000 H'FFFF862C 8, 16, 32

Refresh timer counter RTCNT R/W H'0000 H'FFFF862E 8, 16, 32

Refresh time constant register RTCOR R/W H'0000 H'FFFF8630 8, 16, 32

167

10.1.5 Address Map

Figure 10.2 shows the address format used by the SH7040 Series.

A31–A24 A23, A22 A21

Output address:

Output from the address pins

Space selection:

Not output externally; used to select the type of space

On-chip ROM space or CS space when 00000000 (H'00)

DRAM space when 00000001 (H'01)

Reserved (do not access) when 00000010 to 11111110 (H'02 to H'FE)

On-chip peripheral module space or on-chip RAM space when 11111111 (H'FF)

CS space selection:

Decoded, outputs CS0 to CS3 when A31 to A24 = 00000000

Figure 10.2 Address Format

This LSI uses 32-bit addresses:

• A31–A24 are used to select the type of space and are not output externally.

• Bits A23 and A22 are decoded and output as chip select signals (CS0–CS3) for the

corresponding areas when bits A31–A24 are 00000000.

• A21–A0 are output externally.

Table 10.3 shows an address map for on-chip ROM effective mode. Table 10.4 shows an address

map for on-chip ROM ineffective mode.

168

Table 10.3 Address Map for On-Chip ROM Effective Mode

Address Space Memory Size Bus Width

H'00000000–H'0003FFFF*1On-chip ROM On-chip ROM memory 256 kbytes 32 bits

H'00040000–H'001FFFFF Reserved Reserved

H'00200000–H'003FFFFF CS0 space Ordinary space 2 Mbytes 8/16/32 bits*2

H'00400000–H'007FFFFF CS1 space Ordinary space 4 Mbytes 8/16/32 bits*2

H'00800000–H'00BFFFFF CS2 space Ordinary space 4 Mbytes 8/16/32 bits*2

H'00C00000–H'00FFFFFF CS3 space Ordinary space or

multiplex I/O space 4 Mbytes 8/16/32 bits*3

H'01000000–H'01FFFFFF DRAM space DRAM 16 Mbytes 8/16/32 bits*2

H'02000000–H'FFFF7FFF Reserved Reserved

H'FFFF8000–H'FFFF87FF On-chip

peripheral

module

On-chip peripheral

module 2 kbytes 8/16 bits

H'FFFF8800–H'FFFFEFFF Reserved Reserved

H'FFFFF000–H'FFFFFFFF On-chip RAM On-chip RAM 4 kbytes 32 bits

Notes: Do not access reserved spaces. Operation cannot be guaranteed if they are accessed.

*1 With the 64-kbyte version of on-chip ROM, the ROM address is H'0000000–

H'0000FFFF, and address H'00010000–H'0003FFFF is reserved space.

With the 128-kbyte version of on-chip ROM, the ROM address is H'00000000–

H'0001FFFF, and address H'00020000–H'0003FFFF is reserved space.

*2 Selected by on-chip register settings.

*3 Ordinary space: selected by on-chip register settings.

Multiplex I/O space: 8/16 bit selected by the A14 bit.

169

Table 10.4 Address Map for On-Chip ROM Ineffective Mode

Address Space Memory Size Bus Width

H'00000000–H'003FFFFF CS0 space Ordinary space 4 Mbytes 8/16/32 bist*1

H'00400000–H'007FFFFF CS1 space Ordinary space 4 Mbytes 8/16/32 bits*2

H'00800000–H'00BFFFFF CS2 space Ordinary space 4 Mbytes 8/16/32 bits*2

H'00C00000–H'00FFFFFF CS3 space Ordinary space or multiplex

I/O space 4 Mbytes 8/16/32 bits*3

H'01000000–H'01FFFFFF DRAM space DRAM 16 Mbytes 8/16/32 bits*2

H'02000000–H'FFFF7FFF Reserved Reserved

H'FFFF8000–H'FFFF87FF On-chip

peripheral

module

On-chip peripheral module 2 kbytes 8/16 bits

H'FFFF8800–H'FFFFEFFF Reserved Reserved

H'FFFFF000–H'FFFFFFFF On-chip RAM On-chip RAM 4 kbytes 32 bits

Notes: 1. Do not access reserved spaces. Operation cannot be guaranteed if they are accessed.

2. In the single-chip mode, spaces other than on-chip ROM, on-chip RAM and on-chip

peripheral modules are unavailable.

*1 Selected by the mode pin:

8/16 bit when 112 pin and 120 pin.

16/32 bit when 144 pin.

*2 Selected by on-chip register settings.

*3 Ordinary space: selected by on-chip register settings.

Multiplex I/O space: 8/16 bit selected by the A14 bit.

10.2 Description of Registers

10.2.1 Bus Control Register 1 (BCR1)

BCR1 is a 16-bit read/write register that enables access to the MTU control register, selects

multiplex I/O, and specifies the bus size of the CS spaces. With the 112-pin version

(SH7040/SH7042/SH7044), and the 120-pin version (SH7040/SH7042), specify the bus width as

word (16 bits) or less.

Write bits 8–0 of BCR1 during the initialization stage after a power-on reset, and do not change

the values thereafter. In on-chip ROM effective mode, do not access any of the CS spaces until

after completion of register initialization. In on-chip ROM ineffective mode, do not access any CS

space other than CS0 until after completion of register initialization.

BCR1 is initialized by power-on resets to H'200F, but is not initialized by manual resets or

software standbys.

170

Bit: 15 14 13 12 11 10 9 8

— — MTU

RWE ————IOE

Initial value: 0 0 1 0 0 0 0 0

R/W: R R R/W R R R R R/W

Bit: 7 6 5 4 3 2 1 0

A3LG A2LG A1LG A0LG A3SZ A2SZ A1SZ A0SZ

Initial value: 0 0 0 0 1 1 1 1

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

• Bits 15, 14, 12–9—Reserved: These bits always read as 0. The write value should always be 0.

• Bit 13—MTU Read/Write Enable (MTURWE): When this bit is 1, MTU control register

access is enabled. See section 12, Multifunction Timer Pulse Unit (MTU), for details.

Bit 13 (MTURWE) Description

0 MTU control register access is disabled

1 MTU control register access is enabled (initial value)

• Bit 8—Multiplex I/O Enable (IOE): Selects the use of CS3 space as ordinary space or

address/data multiplex I/O space. A 0 selects ordinary space and a 1 selects address/data

multiplex I/O space. When address/data multiplex I/O space is selected, the address and data

are multiplexed and output from the data bus. When CS3 space is an address/data multiplex

I/O space, bus size is decided by the A14 bit (A14 = 0: 8 bit, A14 = 1: 16 bit).

Bit 8 (IOE) Description

0 CS3 space is ordinary space (initial value)

1 CS3 space is address/data multiplex I/O space

• Bit 7—CS3 Space Long Size Specification (A3LG): Specifies the CS3 space bus size. This is

effective only when CS3 space is ordinary space. When CS3 space is an address/data multiplex

I/O space, bus size is decided by the A14 bit.

Bit 7 (A3LG) Description

0 According to the A3SZ bit specified value (initial value)

1 Longword (32 bit) size

171

• Bit 6—CS2 Space Long Size Specification (A2LG): Specifies the CS2 space bus size.

Bit 6 (A2LG) Description

0 According to the A2SZ bit value (initial value)

1 Longword (32 bit) size

• Bit 5—CS1 Space Long Size Specification (A1LG): Specifies the CS1 space bus size.

Bit 5 (A1LG) Description

0 According to the A1SZ bit value (initial value)

1 Longword (32 bit) size

• Bit 4—CS0 Space Long Size Specification (A0LG): Specifies the CS0 space bus size.

Bit 4 (A0LG) Description

0 According to the A0SZ bit value (initial value)

1 Longword (32 bit) size

Note: A0LG is effective only in on-chip ROM effective mode. When in on-chip ROM ineffective

mode, the CS0 space bus size is specified by the mode pin.

• Bit 3—CS3 Space Size Specification (A3SZ): Specifies the CS3 space bus size when A3LG =

0. This is effective only when CS3 space is ordinary space. When CS3 space is an address/data

multiplex I/O space, bus size is decided by the A14 bit.

Bit 3 (A3SZ) Description

0 Byte (8 bit) size

1 Word (16 bit) size (initial value)

Note: This bit is ignored when A3LG = 1; CS3 space bus size becomes longword (32 bit) (for

ordinary space).

• Bit 2—CS2 Space Size Specification (A2SZ): Specifies the CS2 space bus size when A2LG =

Bit 2 (A2SZ) Description

0 Byte (8 bit) size

1 Word (16 bit) size (initial value)

Note: This bit is ignored when A2LG = 1; CS2 space bus size becomes longword (32 bit).

172

• Bit 1—CS1 Space Size Specification (A1SZ): Specifies the CS1 space bus size when A1LG =

Bit 1 (A1SZ) Description

0 Byte (8 bit) size

1 Word (16 bit) size (initial value)

Note: This bit is ignored when A1LG = 1; CS1 space bus size becomes longword (32 bit).

• Bit 0—CS0 Space Size Specification (A0SZ): Specifies the CS0 space bus size when A0LG =

Bit 0 (A0SZ) Description

0 Byte (8 bit) size

1 Word (16 bit) size (initial value)

Note: A0SZ is effective only in on-chip ROM effective mode. In on-chip ROM ineffective mode,

the CS0 space bus size is specified by the mode pin. However, even in on-chip ROM

effective mode, this bit is ignored when A0LG = 1; CS0 space bus size becomes longword

(32 bit).

10.2.2 Bus Control Register 2 (BCR2)

BCR2 is a 16-bit read/write register that specifies the number of idle cycles and CS signal assert

extension of each CS space.

BCR2 is initialized by power-on resets to H'FFFF, but is not initialized by manual resets or

software standbys.

Bit: 15 14 13 12 11 10 9 8

IW31 IW30 IW21 IW20 IW11 IW10 IW01 IW00

Initial value: 1 1 1 1 1 1 1 1

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

CW3 CW2 CW1 CW0 SW3 SW2 SW1 SW0

Initial value: 1 1 1 1 1 1 1 1

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

173

• Bits 15–8—Idles between Cycles (IW31, IW30, IW21, IW20, IW11, IW10, IW01, IW00):

These bits specify idle cycles inserted between consecutive accesses when the second one is to

a different CS area after a read. Idles are used to prevent data conflict between ROM (and

other memories, which are slow to turn the read data buffer off), fast memories, and I/O

interfaces. Even when access is to the same area, idle cycles must be inserted when a read

access is followed immediately by a write access. The idle cycles to be inserted comply with

the area specification of the previous access. Refer to section 10.6, Waits between Access

Cycles, for details.

IW31, IW30 specify the idle between cycles for CS3 space; IW21, IW20 specify the idle

between cycles for CS2 space; IW11, IW10 specify the idle between cycles for CS1 space and

IW01, IW00 specify the idle between cycles for CS0 space.

Bit 15 (IW31) Bit 14 (IW30) Description

0 0 No idle cycle after accessing CS3 space

1 Inserts one idle cycle after accessing CS3

space

1 0 Inserts two idle cycles after accessing CS3

space

1 Inserts three idle cycles after accessing CS3

space (initial value)

Bit 13 (IW21) Bit 12 (IW20) Description

0 0 No idle cycle after accessing CS2 space

1 Inserts one idle cycle

1 0 Inserts two idle cycles

1 Inserts three idle cycles (initial value)

Bit 11 (IW11) Bit 10 (IW10) Description

0 0 No idle cycle after accessing CS1 space

1 Inserts one idle cycle

1 0 Inserts two idle cycles

1 Inserts three idle cycles (initial value)

174

Bit 9 (IW01) Bit 8 (IW00) Description

0 0 No idle cycle after accessing CS0 space

1 Inserts one idle cycle

1 0 Inserts two idle cycles

1 Inserts three idle cycles (initial value)

• Bits 7–4—Idle Specification for Continuous Access (CW3, CW2, CW1, CW0): The

continuous access idle specification makes insertions to clearly delineate the bus intervals by

once negating the CSn signal when doing consecutive accesses of the same CS space. When a

write immediately follows a read, the number of idle cycles inserted is the larger of the two

values specified by IW and CW. Refer to section 10.6, Waits between Access Cycles, for

details.

CW3 specifies the continuous access idles for CS3 space; CW2 specifies the continuous access

idles for CS2 space; CW1 specifies the continuous access idles for CS1 space and CW0

specifies the continuous access idles for CS0 space.

Bit 7 (CW3) Description

0 No CS3 space continuous access idle cycles

1 One CS3 space continuous access idle cycle (initial value)

Bit 6 (CW2) Description

0 No CS2 space continuous access idle cycles

1 One CS2 space continuous access idle cycle (initial value)

Bit 5 (CW1) Description

0 No CS1 space continuous access idle cycles

1 One CS1 space continuous access idle cycle (initial value)

Bit 4 (CW0) Description

0 No CS0 space continuous access idle cycles

1 One CS0 space continuous access idle cycle (initial value)

175

• Bits 3–0—CS Assert Extension Specification (SW3, SW2, SW1, SW0): The CS assert cycle

extension specification is for making insertions to prevent extension of the RD signal or WRx

signal assert period beyond the length of the CSn signal assert period. Extended cycles insert

one cycle before and after each bus cycle, which simplifies interfaces with external devices and

also has the effect of extending write data hold time. Refer to section 10.3.3, CS Assert Period

Extension, for details.

SW3 specifies the CS assert extension for CS3 space access; SW2 specifies the CS assert

extension for CS2 space access; SW1 specifies the CS assert extension for CS1 space access

and SW0 specifies the CS assert extension for CS0 space access.

Bit 3 (SW3) Description

0 No CS3 space CS assert extension

1 CS3 space CS assert extension (initial value)

Bit 2 (SW2) Description

0 No CS2 space CS assert extension

1 CS2 space CS assert extension (initial value)

Bit 1 (SW1) Description

0 No CS1 space CS assert extension

1 CS1 space CS assert extension (initial value)

Bit 0 (SW0) Description

0 No CS0 space CS assert extension

1 CS0 space CS assert extension (initial value)

10.2.3 Wait Control Register 1 (WCR1)

WCR1 is a 16-bit read/write register that specifies the number of wait cycles (0–15) for each CS

space.

WCR1 is initialized by power-on resets to H'FFFF, but is not initialized by manual resets or

software standbys.

176

Bit: 15 14 13 12 11 10 9 8

W33 W32 W31 W30 W23 W22 W21 W20

Initial value: 1 1 1 1 1 1 1 1

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

W13 W12 W11 W10 W03 W02 W01 W00

Initial value: 1 1 1 1 1 1 1 1

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

• Bits 15–12—CS3 Space Wait Specification (W33, W32, W31, W30): Specifies the number of

waits for CS3 space access.

Bit 15

(W33) Bit 14

(W32) Bit 13

(W31) Bit 12

(W30) Description

0000No wait (external wait input disabled)

00011 wait external wait input enabled

⋅⋅⋅

111115 wait external wait input enabled (initial value)

• Bits 11–8—CS2 Space Wait Specification (W23, W22, W21, W20): Specifies the number of

waits for CS2 space access.

Bit 11

(W23) Bit 10

(W22) Bit 9

(W21) Bit 8

(W20) Description

0000No wait (external wait input disabled)

00011 wait external wait input enabled

⋅⋅⋅

111115 wait external wait input enabled (initial value)

177

• Bits 7–4—CS1 Space Wait Specification (W13, W12, W11, W10): Specifies the number of

waits for CS1 space access.

Bit 7

(W13) Bit 6

(W12) Bit 5

(W11) Bit 4

(W10) Description

0000No wait (external wait input disabled)

00011 wait external wait input enabled

⋅⋅⋅

111115 wait external wait input enabled (initial value)

• Bits 3–0—CS0 Space Wait Specification (W03, W02, W01, W00): Specifies the number of

waits for CS0 space access.

Bit 3

(W03) Bit 2

(W02) Bit 1

(W01) Bit 0

(W00) Description

0000No wait (external wait input disabled)

00011 wait external wait input enabled

⋅⋅⋅

111115 wait external wait input enabled (initial value)

10.2.4 Wait Control Register 2 (WCR2)

WCR2 is a 16-bit read/write register that specifies the number of access cycles for DRAM space

and CS space for DMA single address mode transfers.

Do not perform any DMA single address transfers before WCR2 is set.

WCR2 is initialized by power-on resets to H'000F, but is not initialized by manual resets or

software standbys.

Bit: 15 14 13 12 11 10 9 8

————————

Initial value: 0 0 0 0 0 0 0 0

R/W: R R R R R R R R

Bit: 7 6 5 4 3 2 1 0

— — DDW1 DDW0 DSW3 DSW2 DSW1 DSW0

Initial value: 0 0 0 0 1 1 1 1

R/W: R R R/W R/W R/W R/W R/W R/W

178

• Bits 15–6—Reserved: These bits always read as 0. The write value should always be 0.

• Bits 5–4—DRAM Space DMA Single Address Mode Access Wait Specification (DDW1,

DDW0): Specifies the number of waits for DRAM space access during DMA single address

mode accesses. These bits are independent of the DWW and DWR bits of the DCR.

Bit 5 (DDW1) Bit 4 (DDW0) Description

0 0 2-cycle (no wait) external wait disabled

(initial value)

1 3-cycle (1 wait) external wait disabled

1 0 4-cycle (2 wait) external wait enabled

1 5-cycle (3 wait) external wait enabled

• Bits 3–0—CS Space DMA Single Address Mode Access Wait Specification (DSW3, DSW2,

DSW1, DSW0): Specifies the number of waits for CS space access (0–15) during DMA single

address mode accesses. These bits are independent of the W bits of the WCR1.

Bit 3

(DSW3) Bit 2

(DSW2) Bit 1

(DSW1) Bit 0

(DSW0) Description

0000No wait (external wait input disabled)

00011 wait (external wait input enabled)

⋅⋅⋅

111115 wait (external wait input enabled) (initial value)

10.2.5 DRAM Area Control Register (DCR)

DCR is a 16-bit read/write register that selects the number of waits, operation mode, number of

address multiplex shifts and the like for DRAM control.

Do not perform any DRAM space accesses before DCR initial settings are completed.

DCR is initialized by power-on resets to H'0000, but is not initialized by manual resets or software

standbys.

179

Bit: 15 14 13 12 11 10 9 8

TPC RCD TRAS1 TRAS0 DWW1 DWW0 DWR1 DWR0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

DIW — BE RASD SZ1 SZ0 AMX1 AMX0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R R/W R/W R/W R/W R/W R/W

• Bit 15—RAS Precharge Cycle Count (TPC): Specifies the minimum number of cycles after

RAS is negated before next assert.

Bit 15 (TPC) Description

0 1.5 cycles (initial value)

1 2.5 cycles

• Bit 14—RAS-CAS Delay Cycle Count (RCD): Specifies the number of row address output

cycles.

Bit 14 (RCD) Description

0 1 cycle (initial value)

1 2 cycles

• Bits 13–12—CAS-Before-RAS Refresh RAS Assert Cycle Count (TRAS1–TRAS0): Specify

the number of RAS assert cycles for CAS before RAS refreshes.

Bit 13 (TRAS1) Bit 12 (TRAS0) Description

0 0 2.5 cycles (initial value)

1 3.5 cycles

1 0 4.5 cycles

1 5.5 cycles

180

• Bits 11–10—DRAM Write Cycle Wait Count (DWW1–DWW0): Specifies the number of

DRAM write cycle column address output cycles.

Bit 11 (DWW1) Bit 10 (DWW0) Description

0 0 2-cycle (no wait) external wait disabled (initial value)

1 3-cycle (1 wait) external wait disabled

1 0 4-cycle (2 wait) external wait enabled

1 5-cycle (3 wait) external wait enabled

• Bits 9–8—DRAM Read Cycle Wait Count (DWR1–DWR0): Specifies the number of DRAM

read cycle column address output cycles.

Bit 9 (DWR1) Bit 8 (DWR0) Description

0 0 2-cycle (no wait) external wait disabled (initial value)

1 3-cycle (1 wait) external wait disabled

1 0 4-cycle (2 wait) external wait enabled

1 5-cycle (3 wait) external wait enabled

• Bit 7—DRAM Idle Cycle Count (DIW): Specifies whether to insert idle cycles, either when

accessing a different external space (CS space) or when doing a DRAM write, after DRAM

reads.

Bit 7 (DIW) Description

0 No idle cycles (initial value)

1 1 idle cycle

• Bit 6—Reserved: This bit always reads as 0. The write value should always be 0.

• Bit 5—Burst Enable (BE): Specifies the DRAM operation mode.

Bit 5 (BE) Description

0 Burst disabled (initial value)

1 DRAM high-speed page mode enabled.

• Bit 4—RAS Down Mode (RASD): Specifies the DRAM operation mode.

Bit 4 (RASD) Description

0 Access DRAM by RAS up mode (initial value)

1 Access DRAM by RAS down mode

181

• Bits 3–2—DRAM Bus Width Specification (SZ1, SZ0): Specifies the DRAM space bus width.

Bit 3 (SZ1) Bit 2 (SZ0) Description

0 0 Byte (8 bits) (initial value)

1 Word (16 bits)

1 Don’t care Longword (32 bits)

• Bits 1–0—DRAM Address Multiplex (AMX1–AMX0): Specifies the DRAM address

multiplex count.

Bit 1 (AMX1) Bit 0 (AMX0) Description

0 0 9 bit (initial value)

1 10 bit

1 0 11 bit

1 12 bit

10.2.6 Refresh Timer Control/Status Register (RTCSR)

RTCSR is a 16-bit read/write register that selects the refresh mode and the clock input to the

refresh timer counter (RTCNT), and controls compare match interrupts (CMI).

RTCSR is initialized by power-on resets and hardware standbys to H'0000, but is not initialized by

manual resets or software standbys.

Bit: 15 14 13 12 11 10 9 8

————————

Initial value: 0 0 0 0 0 0 0 0

R/W: R R R R R R R R

Bit: 7 6 5 4 3 2 1 0

— CMF CMIE CKS2 CKS1 CKS0 RFSH RMD

Initial value: 0 0 0 0 0 0 0 0

R/W: R R/W R/W R/W R/W R/W R/W R/W

• Bits 15–7—Reserved: These bits always read as 0. The write value should always be 0.

182

• Bit 6—Compare Match Flag (CMF): This status flag, which indicates that the values of

RTCNT and RTCOR match, is set/cleared under the following conditions:

Bit 6 (CMF) Description

0 Clear condition: After RTCSR is read when CMF is 1, 0 is written in

CMF. In some cases it will clear when DTC is activated by a compare

match interrupt; refer to section 8, Data Transfer Controller (DTC), for

details. (initial value)

1 Set condition: RTCNT = RTCOR. When both RTCNT and RTCOR are

in an initialized state (when values have not been rewritten since

initialization, and RTCNT has not had its value changed due to a count-

up), RTCNT and RTCOR match, as both are H'0000, but in this case

CMF is not set.

• Bit 5—Compare Match Interrupt Enable (CMIE): Enables or disables an interrupt request

caused by the CMF bit of the RTCSR when CMF is set to 1.

Bit 5 (CMIE) Description

0 Disables an interrupt request caused by CMF (initial value)

1 Enables an interrupt request caused by CMF

• Bits 4–2—Clock Select (CKS2–CKS0): Select the clock to input to RTCNT from among the

seven types of internal clock obtained from dividing the system clock (φ).

Bit 4 (CKS2) Bit 3 (CKS1) Bit 2 (CKS0) Description

0 0 0 Stops count-up (initial value)

1φ/2

10φ/8

1φ/32

100φ/128

1φ/512

10φ/2048

1φ/4096

• Bit 1—Refresh Control (RFSH): Selects whether to use refresh control for DRAM.

Bit 1 (RFSH) Description

0 Do not refresh DRAM (initial value)

1 Refresh DRAM

183

• Bit 0—Refresh Mode (RMD): When the RFSH bit is 1, this bit selects normal refresh or self-

refresh. When the RFSH bit is 1, self-refresh mode is entered immediately after the RMD bit is

set to 1. When RMD is cleared to 0, a CAS-before-RAS refresh is performed at the interval set

in the refresh time constant register (RTCNT).

When set for self-refresh, the SH7040 Series enters self-refresh mode immediately unless it is

in the middle of a DRAM access. If it is, it enters self-refresh mode when the access ends.

Refresh requests from the interval timer are ignored in self-refresh mode.

Bit 0 (RMD) Description

0 CAS-before-RAS refresh (initial value)

1 Self-refresh

10.2.7 Refresh Timer Counter (RTCNT)

RTCNT is a 16-bit read/write register that is used as an 8-bit up counter for refreshes or generating

interrupt requests.

RTCNT counts up with the clock selected by the CKS2–CKS0 bits of the RTCSR. RTCNT values

can always be read/written by the CPU. When RTCNT matches RTCOR, RTCNT is cleared to

H'0000 and the CMF flag of the RTCSR is set to 1. If the RFSH bit of RTCSR is 1 and the RMD

bit is 0 at this time, a CAS-before-RAS refresh is performed. Additionally, if the CMIE bit of

RTCSR is a 1, a compare match interrupt (CMI) is generated.

Bits 15–8 are reserved and play no part in counter operation. They are always read as 0.

RTCNT is initialized by power-on resets H'0000, but is not initialized by manual resets or

software standbys.

Bit: 15 14 13 12 11 10 9 8

————————

Initial value: 0 0 0 0 0 0 0 0

R/W: R R R R R R R R

Bit: 7 6 5 4 3 2 1 0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

184

10.2.8 Refresh Time Constant Register (RTCOR)

RTCOR is a 16-bit read/write register that establishes the compare match period with RTCNT.

The values of RTCOR and RTCNT are constantly compared. When the values correspond, the

compare match flag of RTCSR is set and RTCNT is cleared to 0.

When the refresh bit (RFSH) of the RTCSR is set to 1 and the RMD bit is 0, a refresh request

signal is produced by this match. The refresh request signal is held until a refresh operation is

performed. If the refresh request is not processed before the next match, the previous request

becomes ineffective.

When the CMIE bit of the RTSCR is set to 1, an interrupt request is sent to the interrupt controller

by this match signal. The interrupt request is output continuously until the CMF bit of the RTSCR

is cleared.

Bits 15–8 are reserved and cannot be used in setting the period. They always read 0.

RTCOR is initialized by power-on resets to H'0000, but is not initialized by manual resets or

software standbys.

Bit: 15 14 13 12 11 10 9 8

————————

Initial value: 0 0 0 0 0 0 0 0

R/W: R R R R R R R R

Bit: 7 6 5 4 3 2 1 0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

185

10.3 Accessing Ordinary Space

A strobe signal is output by ordinary space accesses to provide primarily for SRAM or ROM

direct connections.

10.3.1 Basic Timing

Figure 10.3 shows the basic timing of ordinary space accesses. Ordinary access bus cycles are

performed in 2 states.

Address

CSn

Read

Write

Data

WRx

Data

Figure 10.3 Basic Timing of Ordinary Space Access

During a read, irrespective of operand size, all bits in the data bus width for the access space

(address) are fetched by the LSI on RD, using the required byte locations.

During a write, the following signals are associated with transfer of these actual byte locations:

WRHH (bits 31–24), WRHL (bits 23–16), WRH (bits 15–8), and WRL (bits 7–0).

186

10.3.2 Wait State Control

The number of wait states inserted into ordinary space access states can be controlled using the

WCR settings (figure 10.4).

T1TW

Read

Write

Address

CSn

Data

WRx

Data

Figure 10.4 Wait Timing of Ordinary Space Access (Software Wait Only)

187

When the wait is specified by software using WCR, the wait input WAIT signal from outside is

sampled. Figure 10.5 shows the WAIT signal sampling. The WAIT signal is sampled at the clock

rise one cycle before the clock rise when Tw state shifts to T2 state.

T1TW

Read

Write

Address

CSn

WAIT

Data

WRx

Data

TWTW0T2

Figure 10.5 Wait State Timing of Ordinary Space Access (Wait States from Software Wait

2 State + WAIT Signal)

188

10.3.3 CS Assert Period Extension

Idle cycles can be inserted to prevent extension of the RD signal or WRx signal assert period

beyond the length of the CSn signal assert period by setting the SW3–SW0 bits of BCR2. This

allows for flexible interfaces with external circuitry. The timing is shown in figure 10.6. Th and Tf

cycles are added respectively before and after the ordinary cycle. Only CSn is asserted in these

cycles; RD and WRx signals are not. Further, data is extended up to the Tf cycle, which is

effective for gate arrays and the like, which have slower write operations.

ThT1

Read

Write

Address

CSn

Data

WRx

Data

T2Tf

DACK

Figure 10.6 CS Assert Period Extension Function

189

10.4 DRAM Access

10.4.1 DRAM Direct Connection

When address space A31–A24 = H'01 has been accessed, the corresponding space becomes a 16-

Mbyte DRAM space, and the DRAM interface function can be used to directly connect the

SH7040 Series to DRAM.

Row address and column address are always multiplexed for DRAM space. The amount of row

address multiplexing can be selected as from 9 to 12 bits by setting the AMX1 and AMX0 bits of

the DCR.

Table 10.5 AMX Bits and Address Multiplex Output

Row Address Column Address

AMX1 AMX0 Shift

Amount Output Pins Output

Address Output

Pins

0 0 9 bit A21–A15 A21–A15 A21–A0 A21–A0

A14–A0 A23–A9

0 1 10 bit A21–A14 A21–A14 A21–A0 A21–A0

A13–A0 A23–A10

1 0 11 bit A21–A13 A21–A13 A21–A0 A21–A0

A12–A0 A23–A11

1 1 12 bit A21–A12 A21–A12 A21–A0 A21–A0

A11–A0 A23–A12

In addition to ordinary read and write accesses, burst mode access using high speed page mode is

supported.

190

10.4.2 Basic Timing

The SH7040 Series supports 2 CAS format DRAM access. The DRAM access basic timing is a

minimum of 3 cycles for normal mode. Figure 10.7 shows the basic DRAM access timing. DRAM

space access is controlled by RAS, CASx, and RDWR signals. The following signals are

associated with transfer of these actual byte locations: CASHH (bits 31–24), CASHL (bits 23–16),

CASH (bits 15–8), and CASL (bits 7–0). However, the signals for ordinary space, WRx and RD,

are also output during the DMAC single transfer column address cycle period. Tp is the precharge

cycle, Tr is the RAS assert cycle, Tc is the CAS assert cycle and Tc2 is the read data fetch cycle.

TpTrTc1 Tc2

Write

Read

Address

Data

RAS

CASx

RDWR

Data

RDWR

CASx

RAS

Row Column

Figure 10.7 DRAM Bus Cycle (Normal Mode, TPC = 0, RCD = 0, No Waits)

191

10.4.3 Wait State Control

Wait state insertion during DRAM space access is controlled by setting the TPC, RCD, DWW1,

DWW0, DWR1, and DWR0 bits of the DCR. TPC and RCD are common to both reads and

writes. The timing with waits inserted is shown in figures 10.8 through 10.11. External waits can

be inserted at the time of software waits 2, 3. The sampling location is the same as that of ordinary

space: at one cycle before the Tc2 cycle clock rise. Wait cycles are extended by external waits.

TpTrTc1 Tcw1 Tc2

Write

Read

Address

Data

RAS

CASx

RDWR

Data

RDWR

CASx

RAS

Row Column

Figure 10.8 DRAM Bus Cycle (Normal Mode, TPC = 0, RCD = 0, One Wait)

192

TpTrTrw Tc1 Tcw1 Tcw2 Tcw2

Tpw

Write

Read

Address

Data

RAS

CASx

RDWR

Data

RDWR

CASx

RAS

Row Column

Figure 10.9 DRAM Bus Cycle (Normal Mode, TPC = 1, RCD = 1, Two Waits)

193

TpTc1 Tcw1 Tcw2 Tcw3 Tc2

Write

Read

Address

Data

RAS

CASx

RDWR

Data

RDWR

CASx

RAS

Row Column

Figure 10.10 DRAM Bus Cycle (Normal Mode, TPC = 0, RCD = 0, Three Waits)

194

TpTc1 Tcw1 Tcw2 Tcw0 Tc2

Write

Read

Address

Data

RAS

CASx

RDWR

Data

RDWR

CASx

RAS

Row Column

WAIT

Figure 10.11 DRAM Bus Cycle (Normal Mode, TPC = 0, RCD= 0, Two Waits + Wait Due

to WAIT Signal)

195

10.4.4 Burst Operation

High-Speed Page Mode: When the burst enable bit (BE) of the DCR is set, burst accesses can be

performed using high speed page mode. The timing is shown in figure 10.12. Wait cycles can be

inserted during burst accesses by using the DCR.

TpTc1 Tc2 Tc1 Tc2

Write

Read

Address

Data

RAS

CASx

RDWR

Data

RDWR

CASx

RAS

Row Column Column

Figure 10.12 DRAM Bus Cycle (High-Speed Page Mode)

RAS Down Mode: There are some instances where even if burst operation is selected, continuous

accesses to DRAM will not occur, but another space will be accessed instead part way through the

access. In such cases, if the RAS signal is maintained at low level during the time the other space

is accessed, it is possible to continue burst operation at the time the next DRAM same row address

is accessed. This is called RAS down mode.

To use RAS down mode, set both the BE and RASD bits of the DCR to 1.

Figures 10.13 and 10.14 show operation in RAS up and down modes.

196

RAS

CASx

DRAM access DRAM access

CS space 

access

Address

Data

CS space

Tp Tr Tc1 Tc2 T1 T2 Tp Tr Tc1 Tc2

Column ColumnRow Row

Figure 10.13 DRAM Access Normal Operation (RAS Up Mode)

RAS

CASx

DRAM access DRAM 

access

CS space 

access

Address

Data

Row Column CS space

Tp Tr Tc1 Tc2 T1 T2 Tc1 Tc2

Column

Figure 10.14 RAS Down Mode

197

10.4.5 Refresh Timing

The bus state controller is equipped with a function to control refreshes of DRAM. CAS-before-

RAS (CBR) refresh or self-refresh can be selected by setting the RTCSR’s RMD bit.

CAS-before-RAS Refresh: For CBR refreshes, set the RCR’s RMD bit to 0 and the RFSH bit to

1. Also write the values in RTCNT and RTCOR necessary to fulfill the refresh interval prescribed

for the DRAM being used. When a clock is selected with the CKS2–CKS0 bits of the RSTCR,

RTCNT starts counting up from the value at that time. The RTCNT value is constantly compared

to the RTCOR value and a CBR refresh is performed when the two match. RTCNT is cleared at

that time and the count starts again. Figure 10.15 shows the timing for the CBR refresh operation.

The number of RAS assert cycles in the refresh cycle is set by the TRAS1, TRAS0 bits of the

DCR.

CASx

RAS

TRp TRr1 TRr2 TRc TRc

Figure 10.15 CAS-Before-RAS Refresh Timing (TRAS1, TRAS0 = 0, 0)

198

Self-Refresh: When both the RMD and RFSH bits of the RTCSR are set to 1, the CAS signal and

RAS signal are output and the DRAM enters self-refresh mode, as shown in figure 10.16. Do not

access DRAM during self-refreshes, in order to preserve DRAM data. When performing DRAM

accesses, first cancel the self-refresh, then access only after doing individual refreshes for all row

addresses within the time prescribed for the particular DRAM.

For external bus right requests during self-refreshes, to preserve DRAM data at the time of

releasing the bus rights, only CASx, RAS, and RDWR are output and the bus rights are released to

the external device with the self-refresh maintained. Consequently, do not perform DRAM

accesses from external devices at such a time.

CASx

RAS

Rr1

Rr2

Figure 10.16 Self-Refresh Timing

199

10.5 Address/Data Multiplex I/O Space Access

When the BCR1 register IOE bit is set to 1, the D15–D0 pins can be used for multiplexed

address/data I/O for the CS3 space. Consequently, peripheral LSIs requiring address/data

multiplexing can be directly connected to this LSI.

Address/data multiplex I/O space bus width is selected by the A14 bit, and is 8 bit when A14 = 0

and 16 bit when A14 = 1.

10.5.1 Basic Timing

When the IOE bit of the BCR1 is set to 1, CS3 space becomes address/data multiplex I/O space.

When this space is accessed, addresses and data are multiplexed. When the A14 address bit is 0,

the bus size becomes 8 bit and addresses and data are input and output through the D7–D0 pins.

When the A14 address bit is 1, the bus size becomes 16 bit and address output and data I/O occur

through the D15–D0 pins. Access for the address/data multiplex I/O space is controlled by the

AH, RD, and WRx signals.

Address/data multiplex I/O space accesses are done after a 3-cycle (fixed) address output, as an

ordinary space type access (figure 10.17).

CS3

Data

WRx

Data

Address

Read

Write

Address output

Address output Data output

Data input

Figure 10.17 Address/Data Multiplex I/O Space Access Timing (No Waits)

200

10.5.2 Wait State Control

Setting the WCR controls waits during address/data multiplex I/O space accesses. Software wait

and external wait insertion timing is the same as during ordinary space accesses. The timing for

one software wait + one external wait inserted is shown in figure 10.18.

CS3

Data

WRx

Data

WAIT

Address

Ta1 Ta2 Ta3 Ta4 T1TWTWo T2

Read

Write

Address output

Address output Data output

Data 

input

Figure 10.18 Address/Data Multiplex I/O Space Access Wait State Timing (One Software

Wait + One External Wait)

201

10.5.3 CS Assertion Extension

The timing diagram when setting CS assertion extension during address/data multiplex I/O space

access is shown in figure 10.19.

CS3

Data

WRxx

Data

Address

Ta1 Ta2 Ta3 Ta4 ThT1T2Tf

Read

Write

Address output

Address output Data output

Data input

Figure 10.19 Wait Timing in Address/Data Multiplex I/O Space when CS Assertion

Extension is Set

10.6 Waits between Access Cycles

When a read from a slow device is completed, data buffers may not go off in time to prevent data

conflicts with the next access. If there is a data conflict during memory access, the problem can be

solved by inserting a wait in the access cycle.

To enable detection of bus cycle starts, waits can be inserted between access cycles during

continuous accesses of the same CS space by negating the CSn signal once.

10.6.1 Prevention of Data Bus Conflicts

For the two cases of write cycles after read cycles, and read cycles for a different area after read

cycles, waits are inserted so that the number of idle cycles specified by the IW31–IW00 bits of the

202

BCR2 and the DIW of the DCR occur. When idle cycles already exist between access cycles, only

the number of empty cycles remaining beyond the specified number of idle cycles are inserted.

Figure 10.20 shows an example of idles between cycles. In this example, 1 idle between CSn

space cycles has been specified, so when a CSm space write immediately follows a CSn space

read cycle, 1 idle cycle is inserted.

CSn

CSm

Data

CSn space read CSm space writeIdle cycle

WRx

Address

T1T2T1T2

Tidle

Figure 10.20 Idle Cycle Insertion Example

IW31 and IW30 specify the number of idle cycles required after a CS3 space read either to read

other external spaces, or for this LSI, to do write accesses. In the same manner, IW21 and IW20

specify the number of idle cycles after a CS2 space read, IW11 and IW10, the number after a CS1

space read, and IW01 and IW00, the number after a CS0 space read.

DIW specifies the number of idle cycles required, after a DRAM space read either to read other

external spaces (CS space), or for this LSI, to do write accesses.

0 to 3 cycles can be specified for CS space, and 0 to 1 cycle for DRAM space.

203

10.6.2 Simplification of Bus Cycle Start Detection

For consecutive accesses of the same CS space, waits are inserted so that the number of idle cycles

designated by the CW3–CW0 bits of the BCR2 occur. However, for write cycles after reads, the

number of idle cycles inserted will be the larger of the two values defined by the IW and CW bits.

When idle cycles already exist between access cycles, waits are not inserted. Figure 10.21 shows

an example. A continuous access idle is specified for CSn space, and CSn space is consecutively

write accessed.

CSn

WRx

Data

CSn space access CSn space accessIdle cycle

Address

T1T2T1T2

Tidle

Figure 10.21 Same Space Consecutive Access Idle Cycle Insertion Example

10.7 Bus Arbitration

The SH7040 series has a bus arbitration function that, when a bus release request is received from

an external device, releases the bus to that device. It also has two internal bus masters, the CPU

and the DMAC, DTC. The priority ranking for determining bus right transfer between these bus

masters is:

Bus right request from external device > refresh > DTC > DMAC > CPU

However, during a read or write in DMAC dual address mode, a burst transfer, or indirect address

transfer mode operation, the DMAC continues operating even if a DTC request is received.

Through port register settings, IRQOUT is asserted to indicate that a CAS-before-RAS refresh

request for DRAM has been generated during release of bus rights to an external device. Use this

204

to cause the external device to negate the BREQ and return the bus rights to the SH7040 Series.

Please note that if the external device does not return the bus rights within the time prescribed for

the DRAM refresh interval, this LSI will not be able to perform the refresh operation and the

DRAM contents cannot be guaranteed.

Figure 10.22 shows the bus right release procedure.

BREQ = Low

SH704X

BREQ accepted

Strobe pin:

high-level output

Address, data,

strobe pin:

high impedance

Bus right release

response

Bus right release status

External device

Bus right request

BACK confirmation

Bus right acquisition

BACK = Low

Figure 10.22 Bus Right Release Procedure

205

10.8 Memory Connection Examples

Figures 10.23–10.31 show examples of the memory connections.

As A21–A18 become input ports in power-on reset, they should be handled (e.g.

pulled down) as necessary.

SH704x 32k × 8 bits



CSn

A0–A14

D0–D7

A0–A14

I/O0–I/O7

ROM

Figure 10.23 8-Bit Data Bus Width ROM Connection

SH704x 256k × 16 bits



ROM

CSn

A1–A18

D0–D15

A0–A17

I/O0–I/O15

Figure 10.24 16-Bit Data Bus Width ROM Connection

206

SH704x

CSn

A2–A19

D16–D31

D0–D15

A0–A17

I/O0–I/O15

256k × 16 bits

ROM

Figure 10.25 32-Bit Data Bus Width ROM Connection

SH704x

CSn

WRL WE

A0–A16 A0–A16

D0–D7 I/O0–I/O7

123k × 8 bits



SRAM

Figure 10.26 8-Bit Data Bus Width SRAM Connection

207

SH704x 128k × 8 bits

SRAM

CSn

A1–A17 A0–A16



WRH WE

D8–D15 I/O0–I/O7

WRL

D0–D7 CS

A0–A16

I/O0–I/O7

Figure 10.27 16-Bit Data Bus Width SRAM Connection

208

SH704x

CSCSn

RD OE

A2–A18 A0–A16

WRHH WE

D24–D31 I/O0–I/O7

WRHL

D16–D23

D0–D7

WRL

WRH

D8–D15

A0–A16

I/O0–I/O7

A0–A16

I/O0–I/O7

A0–A16

128k × 8 bits



SRAM

Figure 10.28 32-Bit Data Bus Width SRAM Connection

209

SH704x

RAS

RDWR

A0–A9

CASL

AD0–AD7

RAS

A0–A9

CAS

I/O0–I/O7

512k × 8 bits



DRAM

Figure 10.29 8-Bit Data Bus Width DRAM Connection

RAS RAS

RDWR WE

A0 OE

A1–A9

CASH UCAS

CASL LCAS

AD0–AD15 I/O0–I/O15

SH704x 256k × 16 bits

DRAM

A0–A8

Figure 10.30 16-Bit Data Bus Width DRAM Connection

210

SH704x 256k × 16 bits

DRAM

RAS

RDWR

A2–A10

CASHH

CASHL

AD16–AD31

RAS

A0–A8

UCAS

LCAS

I/O0–I/O15

CASH

CASL

AD0–AD15 RAS

A0–A8

UCAS

LCAS

Figure 10.31 32-Bit Data Bus Width DRAM Connection

10.9 On-Chip Peripheral I/O Register Access

On-chip peripheral I/O registers are accessed from the bus state controller, as shown in table 10.6.

Table 10.6 On-Chip Peripheral I/O Register Access

On-chip

Peripheral Module SCI MTU,

POE INTC PFC,

PORT CMT A/D*UBC WDT DMAC DTC CACHE

Connected bus

width 8bit 16bit 16bit 16bit 16bit 16bit 16bit 16bit 16bit 16bit 16bit

Access cycle 2cyc 2cyc 2cyc 2cyc 2cyc 2cyc 3cyc 3cyc 3cyc 3cyc 3cyc

Note: *A/D of A mask products are accessed in 8-bit width, 3 cyc.

211

Cycles in which Bus is not Released

(a) One bus cycle:

The bus is never released during a single bus cycle. For example, in the case of a longword read

(or write) in 8-bit normal space, the four memory accesses to the 8-bit normal space constitute a

single bus cycle, and the bus is never released during this period. Assuming that one memory

access requires two states, the bus is not released during an 8-state period.

8 bit 8 bit 8 bit 8 bit

Cycles in which

Bus is not Released

Figure 10.32 One Bus Cycle

10.10 CPU Operation when Program is in External Memory

In the SH7040 Series, two words (equivalent to two instructions) are normally fetched in a single

instruction fetch. This is also true when the program is located in external memory, irrespective of

whether the external memory bus width is 8 or 16 bits.

If the program counter value immediately after the program branches is an odd-word (2n + 1)

address, or if the program counter value immediately before the program branches is an even-word

(2n) address, the CPU will always fetch 32 bits (equivalent to two instructions) that include the

respective word instruction.

212

213

Section 11 Direct Memory Access Controller (DMAC)

11.1 Overview

The SH7040 Series includes an on-chip four-channel direct memory access controller (DMAC).

The DMAC can be used in place of the CPU to perform high-speed data transfers among external

devices equipped with DACK (transfer request acknowledge signal), external memories, memory-

mapped external devices, and on-chip peripheral modules (except for the DMAC, DTC, BSC, and

UBC). Using the DMAC reduces the burden on the CPU and increases operating efficiency of the

LSI as a whole.

11.1.1 Features

The DMAC has the following features:

• Four channels

• Four Gbytes of address space in the architecture

• Byte, word, or longword selectable data transfer unit

• 16 Mbytes (16,777,216 transfers, maximum)

• Single or dual address mode. Dual address mode can be direct or indirect address transfer.

 Single address mode: Either the transfer source or transfer destination (peripheral device) is

accessed by a DACK signal while the other is accessed by address. One transfer unit of

data is transferred in each bus cycle.

 Dual address mode: Both the transfer source and transfer destination are accessed by

address. Dual address mode can be direct or indirect address transfer.

• Direct access: Values set in a DMAC internal register indicate the accessed address for

both the transfer source and transfer destination. Two bus cycles are required for one

data transfer.

• Indirect access: The value stored at the location pointed to by the address set in the

DMAC internal transfer source register is used as the address. Operation is otherwise

the same as direct access. This function can only be set for channel 3. Four bus cycles

are required for one data transfer.

• Channel function: Transfer modes that can be set are different for each channel. (Dual address

mode indirect access can only be set for channel 1. Only direct access is possible for the other

channels.)

 Channel 0: Single or dual address mode. External requests are accepted.

 Channel 1: Single or dual address mode. External requests are accepted.

 Channel 2: Dual address mode only. Source address reload function operates every fourth

transfer.

214

 Channel 3: Dual address mode only. Direct address transfer mode and indirect address

transfer mode selectable.

• Reload function: Enables automatic reloading of the value set in the first source address

• Transfer requests: There are three DMAC transfer activation requests, as indicated below.

 External request: From two DREQ pins. DREQ can be detected either by falling edge or by

low level. External requests can only be received on channels 0 or 1.

 Requests from on-chip peripheral modules: Transfer requests from on-chip modules such as

SCI or A/D. These can be received by all channels.

 Auto-request: The transfer request is generated automatically within the DMAC.

• Selectable bus modes: Cycle-steal mode or burst mode

• Two types of DMAC channel priority ranking:

 Fixed priority mode: Always fixed

 Round robin mode: Sets the lowest priority level for the channel that received the execution

request last

• CPU can be interrupted when the specified number of data transfers are complete.

215

11.1.2 Block Diagram

Figure 11.1 is a block diagram of the DMAC.

On-chip ROM

Peripheral bus

Internal bus

On-chip RAM

DREQ0, DREQ1

Circuit

control SARn

DMAC module

control

Activation

control

Request

priority

control

Bus interface

Bus state

controller

On-chip

peripheral

module

DARn

DMATCRn

CHCRn

DMAOR

MTU

SCI0, SCI1

A/D converter*

DEIn

External

ROM

External

RAM

External I/O

(memory

mapped)

External I/O

(with

acknowledge)

DACK0, DACK1

DRAK0, DRAK1

SARn:

DARn:

DMATCRn:

CHCRn:

DMAOR:

DMAC source address register

DMAC destination address register

DMAC transfer count register

DMAC channel control register

DMAC operation register

0, 1, 2, 3

Note: * A/D1 for A mask and A/D for others

Figure 11.1 DMAC Block Diagram

216

11.1.3 Pin Configuration

Table 11.1 shows the DMAC pins.

Table 11.1 DMAC Pin Configuration

Channel Name Symbol I/O Function

0 DMA transfer request DREQ0 I DMA transfer request input from

external device to channel 0

DMA transfer request

acknowledge DACK0 O DMA transfer strobe output from

channel 0 to external device

DREQ0 acceptance

confirmation DRAK0 O Sampling receive acknowledge output

for DMA transfer request input from

external source

1 DMA transfer request DREQ1 I DMA transfer request input from

external device to channel 1

DMA transfer request

acknowledge DACK1 O DMA transfer strobe output from

channel 1 to external device

DREQ1 acceptance

confirmation DRAK1 O Sampling receive acknowledge output

for DMA transfer request input from

external source

217

11.1.4 Register Configuration

Table 11.2 summarizes the DMAC registers. DMAC has a total of 17 registers. Each channel has

four control registers. One other control register is shared by all channels

Table 11.2 DMAC Registers

Chan-

nel Name Abbrevi-

ation R/W Initial

Value Address Register

Size Access

Size

0 DMA source address

DMA destination

address register 0 DAR0 R/W Undefined H'FFFF86C4 32 bit 16, 32*2

DMA transfer count

DMA channel control

1 DMA source address

DMA destination

address register 1 DAR1 R/W Undefined H'FFFF86D4 32 bit 16, 32*2

DMA transfer count

DMA channel control

2 DMA source address

DMA destination

address register 2 DAR2 R/W Undefined H'FFFF86E4 32 bit 16, 32*2

218

Table 11.2 DMAC Registers (cont)

Chan-

nel Name Abbrevi-

ation R/W Initial

Value Address Register

Size Access

Size

(cont) DMA transfer count

DMA channel control

3 DMA source address

DMA destination

address register 3 DAR3 R/W Undefined H'FFFF86F4 32 bit 16, 32*2

DMA transfer count

DMA channel control

SharedDMA operation

Notes: Do not attempt to access an empty address. If an access is attemped, the system

operation is not guarenteed.

*1 Write 0 after reading 1 in bit 1 of CHCR0–CHCR3 and in bits 1 and 2 of the DMAOR to

clear flags. No other writes are allowed.

*2 For 16-bit access of SAR0–SAR3, DAR0–DAR3, and CHCR0–CHCR3, the 16-bit value

on the side not accessed is held.

*3 DMATCR has a 24-bit configuration: bits 0–23. Writing to the upper 8 bits (bits 24–31)

is invalid, and these bits always read 0.

*4 Do not make 32-bit access for DMAOR.

11.2 Register Descriptions

11.2.1 DMA Source Address Registers 0–3 (SAR0–SAR3)

DMA source address registers 0–3 (SAR0–SAR3) are 32-bit read/write registers that specify the

source address of a DMA transfer. These registers have a count function, and during a DMA

transfer, they indicate the next source address. In single-address mode, SAR values are ignored

when a device with DACK has been specified as the transfer source.

Specify a 16-bit or 32-bit boundary address when doing 16-bit or 32-bit data transfers. Operation

cannot be guaranteed on any other addresses.

The initial value after power-on resets or in software standby mode is undefined. These registers

are not initialized with manual reset.

219

Bit: 31 30 29 28 27 26 25 24

Initial value: — — — — — — — —

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 23 22 21 … … 2 1 0

……

Initial value: — — — … … — — —

R/W: R/W R/W R/W … … R/W R/W R/W

11.2.2 DMA Destination Address Registers 0–3 (DAR0–DAR3)

DMA destination address registers 0–3 (DAR0–DAR3) are 32-bit read/write registers that specify

the destination address of a DMA transfer. These registers have a count function, and during a

DMA transfer, they indicate the next destination address. In single-address mode, DAR values are

ignored when a device with DACK has been specified as the transfer destination.

Specify a 16-bit or 32-bit boundary address when doing 16-bit or 32-bit data transfers. Operation

cannot be guaranteed on any other address. The initial value after power-on resets or in software

standby mode, is undefined. These registers are not initialized with manual reset.

Bit: 31 30 29 28 27 26 25 24

Initial value: — — — — — — — —

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 23 22 21 … … 2 1 0

……

Initial value: — — — … … — — —

R/W: R/W R/W R/W … … R/W R/W R/W

220

11.2.3 DMA Transfer Count Registers 0–3 (DMATCR0–DMATCR3)

DMA transfer count registers 0–3 (DMATCR0–DMATCR3) are 24-bit read/write registers that

specify the transfer count for the channel (byte count, word count, or longword count). Specifying

a H'000001 gives a transfer count of 1, while H'000000 gives the maximum setting, 16,777,216

transfers. The data for the upper 8 bits of a DMATCR is 0 when read. Always write 0. The initial

value after power-on resets or in software standby mode is undefined. These registers are not

initialized with manual reset.

Always write 0 to the upper 8 bits of a DMATCR.

Bit: 31 30 29 28 27 26 25 24

————————

Initial value: — — — — — — — —

R/W: R R R R R R R R

Bit: 23 22 21 20 19 18 17 16

Initial value: — — — — — — — —

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 15 14 13 12 11 10 9 8

Initial value: — — — — — — — —

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

Initial value: — — — — — — — —

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

221

11.2.4 DMA Channel Control Registers 0–3 (CHCR0–CHCR3)

DMA channel control registers 0–3 (CHCR0–CHCR3) is a 32-bit read/write register where the

operation and transmission of each channel is designated. They are initialized by a power-on reset

and in software standby mode. There is no initializing with manual reset.

Bit: 31 30 29 28 27 26 25 24

————————

Initial value: — — — — — — — —

R/W: R R R R R R R R

Bit: 23 22 21 20 19 18 17 16

———DI

*2RO*2RL*2AM*2AL*2

Initial value: — — — 0 0 0 0 0

R R R (R/W) (R/W) (R/W) (R/W) (R/W)

Bit: 15 14 13 12 11 10 9 8

DM1 DM0 SM1 SM0 RS3 RS2 RS1 RS0

Initial value: 0 0 0 0 0 0 0 0

R/W: R/W R/W R/W R/W R/W R/W R/W R/W

Bit: 7 6 5 4 3 2 1 0

—DS

*2TM TS1 TS0 IE TE DE

Initial value: — 0 0 0 0 0 0 0

R/W: R (R/W) R/W R/W R/W R/W R/(W) *1R/W

Notes: *1 TE bit: Allows only 0 write after reading 1.

*2 The DI, RO, RL, AM, AL, or DS bit may be absent, depending on the channel.

• Bits 31–21—Reserved bits: Data are 0 when read. The write value always be 0.

• Bit 20—Direct/Indirect (DI): Specifies either direct address mode operation or indirect address

mode operation for channel 3 source address. This bit is valid only in CHCR3. It always reads

0 for CHCR0–CHCR2, and cannot be modified.

Bit 20: DI Description

0 Direct access mode operation for channel 3 (initial value)

1 Indirect access mode operation for channel 3

222

• Bit 19—Source Address Reload (RO): Selects whether to reload the source address initial

value during channel 2 transfer. This bit is valid only for channel 2. It always reads 0 for

CHCR0, CHCR1, and CHCR3, and cannot be modified.

Bit 19: RO Description

0 Does not reload source address (initial value)

1 Reloads source address

• Bit 18—Request Check Level (RL): Selects whether to output DRAK notifying external

device of DREQ received, with active high or active low. This bit is valid only for CHCR0 and

CHCR1. It always reads 0 for CHCR2 and CHCR3, and cannot be modified.

Bit 18: RL Description

0 Output DRAK with active high (initial value)

1 Output DRAK with active low

• Bit 17—Acknowledge Mode (AM): In dual address mode, selects whether to output DACK in

the data write cycle or data read cycle. In single address mode, DACK is always output

irrespective of the setting of this bit. This bit is valid only for CHCR0 and CHCR1. It always

reads as 0 for CHCR2 and CHCR3, and cannot be modified.

Bit 17: AM Description

0 Outputs DACK during read cycle (initial value)

1 Outputs DACK during write cycle

• Bit 16—Acknowledge Level (AL): Specifies whether to set DACK (acknowledge) signal

output to active high or active low. This bit is valid only with CHCR0 and CHCR1. It always

reads as 0 for CHCR2 and CHCR3, and cannot be modified.

Bit 16: AL Description

0 Active high output (initial value)

1 Active low output

223

• Bits 15 and 14—Destination Address Mode 1, 0 (DM1 and DM0): These bits specify

increment/decrement of the DMA transfer destination address. These bit specifications are

ignored when transferring data from an external device to address space in single address

mode.

Bit 15: DM1 Bit 14: DM0 Description

0 0 Destination address fixed (initial value)

0 1 Destination address incremented (+1 during 8-bit transfer, +2

during 16-bit transfer, +4 during 32-bit transfer)

1 0 Destination address decremented (–1 during 8-bit transfer, –2

during 16-bit transfer, –4 during 32-bit transfer)

1 1 Setting prohibited

• Bits 13 and 12—Source Address Mode 1, 0 (SM1 and SM0): These bits specify

increment/decrement of the DMA transfer source address. These bit specifications are ignored

when transferring data from an external device to address space in single address mode.

Bit 13: SM1 Bit 12: SM0 Description

0 0 Source address fixed (initial value)

0 1 Source address incremented (+1 during 8-bit transfer, +2

during 16-bit transfer, +4 during 32-bit transfer)

1 0 Source address decremented (–1 during 8-bit transfer, –2

during 16-bit transfer, –4 during 32-bit transfer)

1 1 Setting prohibited

When the transfer source is specified at an indirect address, specify in source address register 3

(SAR3) the actual storage address of the data you want to transfer as the data storage address

(indirect address).

During indirect address mode, SAR3 obeys the SM1/SM0 setting for increment/decrement. In this

case, SAR3’s increment/decrement is fixed at +4/–4 or 0, irrespective of the transfer data size

specified by TS1 and TS0.

224

• Bits 11–8—Resource Select 3–0 (RS3–RS0): These bits specify the transfer request source.

Bit 11:

RS3 Bit 10:

RS2 Bit 9:

RS1 Bit 8:

RS0 Description

0 0 0 0 External request, dual address mode (initial value)

0 0 0 1 Prohibited

0 0 1 0 External request, single address mode. External address

space → external device.

0 0 1 1 External request, single address mode. External device →

external address space.

0 1 0 0 Auto-request

0 1 0 1 Prohibited

0 1 1 0 MTU TGI0A

0 1 1 1 MTU TGI1A

1 0 0 0 MTU TGI2A

1 0 0 1 MTU TGI3A

1 0 1 0 MTU TGI4A

1 0 1 1 A/D ADI*

1 1 0 0 SCI0 TXI0

1 1 0 1 SCI0 RXI0

1 1 1 0 SCI1 TXI1

1 1 1 1 SCI1 RXI1

Notes: External request designations are valid only for channels 0 and 1. No transfer request

sources can be set for channels 2 or 3.

* ADI1 for A mask.

• Bit 7—Reserved bits: Data is 0 when read. The write value always be 0.

• Bit 6—DREQ Select (DS): Sets the sampling method for the DREQ pin in external request

mode to either low-level detection or falling-edge detection. This bit is valid only with CHCR0

and CHCR1. For CHCR2 and CHCR3, this bit always reads as 0 and cannot be modified.

Even with channels 0 and 1, when specifying an on-chip peripheral module or auto-request as

the transfer request source, this bit setting is ignored. The sampling method is fixed at falling-

edge detection in cases other than auto-request.

Bit 6: DS Description

0 Low-level detection (initial value)

1 Falling-edge detection

225

• Bit 5—Transfer Mode (TM): Specifies the bus mode for data transfer.

Bit 5: TM Description

0 Cycle steal mode (initial value)

1 Burst mode

• Bits 4 and 3—Transfer Size 1, 0 (TS1, TS0): Specifies size of data for transfer.

Bit 4: TS1 Bit 3: TS0 Description

0 0 Specifies byte size (8 bits) (initial value)

0 1 Specifies word size (16 bits)

1 0 Specifies longword size (32 bits)

1 1 Prohibited

• Bit 2—Interrupt Enable (IE): When this bit is set to 1, interrupt requests are generated after the

number of data transfers specified in the DMATCR (when TE = 1).

Bit 2: IE Description

0 Interrupt request not generated after DMATCR-specified transfer count

(initial value)

1 Interrupt request enabled on completion of DMATCR specified number

of transfers

• Bit 1—Transfer End Flag (TE): This bit is set to 1 after the number of data transfers specified

by the DMATCR. At this time, if the IE bit is set to 1, an interrupt request is generated.

If data transfer ends before TE is set to 1 (for example, due to an NMI or address error, or

clearing of the DE bit or DME bit of the DMAOR) the TE is not set to 1. With this bit set to 1,

data transfer is disabled even if the DE bit is set to 1.

Bit 1: TE Description

0 DMATCR-specified transfer count not ended (initial value)

Clear condition: 0 write after TE = 1 read, Power-on reset, standby

mode

1 DMATCR specified number of transfers completed

226

• Bit 0—DMAC Enable (DE): DE enables operation in the corresponding channel.

Bit 0: DE Description

0 Operation of the corresponding channel disabled (initial value)

1 Operation of the corresponding channel enabled

Transfer mode is entered if this bit is set to 1 when auto-request is specified (RS3–RS0 settings).

With an external request or on-chip module request, when a transfer request occurs after this bit is

set to 1, transfer is enabled. If this bit is cleared during a data transfer, transfer is suspended.

If the DE bit has been set, but TE = 1, then if the DME bit of the DMAOR is 0, and the NMI or

AE bit of the DMAOR is 1, transfer enable mode is not entered.

11.2.5 DMAC Operation Register (DMAOR)

The DMAOR is a 16-bit read/write register that specifies the transfer mode of the DMAC

reset does not initialize DMAOR.

Bit: 15 14 13 12 11 10 9 8

— — — — — — PR1 PR0

Initial value: — — — — — — 0 0

R/W: R R R R R R R/W R/W

Bit: 7 6 5 4 3 2 1 0

— — — — — AE NMIF DME

Initial value: — — — — — — 0 0

R/W: R R R R R R/(W)*R/(W)*R

Note: *0 write only is valid after 1 is read at the AE and NMIF bits.

• Bits 15–10—Reserved bits: Data are 0 when read. The write value always be 0.

227

• Bits 9–8—Priority Mode 1 and 0 (PR1 and PR0): These bits determine the priority level of

channels for execution when transfer requests are made for several channels simultaneously.

Bit 9: PR1 Bit 8: PR0 Description

0 0 CH0 > CH1 > CH2 > CH3 (initial value)

0 1 CH0 > CH2 > CH3 > CH1

1 0 CH2 > CH0 > CH1 > CH3

1 1 Round robin mode

• Bits 7–3—Reserved bits: Data are 0 when read. The write value always be 0.

• Bit 2—Address Error Flag (AE): Indicates that an address error has occurred during DMA

transfer. If this bit is set during a data transfer, transfers on all channels are suspended. The

CPU cannot write a 1 to the AE bit. Clearing is effected by 0 write after 1 read.

Bit 2: AE Description

0 No address error, DMA transfer enabled (initial value)

Clearing condition: Write AE = 0 after reading AE = 1

1 Address error, DMA transfer disabled

Setting condition: Address error due to DMAC

• Bit 1—NMI Flag (NMIF): Indicates input of an NMI. This bit is set irrespective of whether the

DMAC is operating or suspended. If this bit is set during a data transfer, transfers on all

channels are suspended. The CPU is unable to write a 1 to the NMIF. Clearing is effected by a

0 write after 1 read.

Bit 1: NMIF Description

0 No NMI interrupt, DMA transfer enabled (initial value)

Clearing condition: Write NMIF = 0 after reading NMIF = 1

1 NMI has occurred, DMC transfer prohibited

Set condition: NMI interrupt occurrence

228

• Bit 0—DMAC Master Enable (DME): This bit enables activation of the entire DMAC. When

the DME bit and DE bit of the CHCR for the corresponding channel are set to 1, that channel

is transfer-enabled. If this bit is cleared during a data transfer, transfers on all channels are

suspended.

Even when the DME bit is set, when the TE bit of the CHCR is 1, or its DE bit is 0, transfer is

disabled in the case of an NMI of the DMAOR or when AE = 1.

Bit 0: DME Description

0 Disable operation on all channels (initial value)

1 Enable operation on all channels

11.3 Operation

When there is a DMA transfer request, the DMAC starts the transfer according to the

predetermined channel priority order; when the transfer end conditions are satisfied, it ends the

transfer. Transfers can be requested in three modes: auto-request, external request, and on-chip

peripheral module request. Transfer can be in either the single address mode or the dual address

mode, and dual address mode can be either direct or indirect address transfer mode. The bus mode

can be either burst or cycle steal.

11.3.1 DMA Transfer Flow

After the DMA source address registers (SAR), DMA destination address registers (DAR), DMA

transfer count register (DMATCR), DMA channel control registers (CHCR), and DMA operation

to the following procedure:

1. The DMAC checks to see if transfer is enabled (DE = 1, DME = 1, TE = 0, NMIF = 0,

AE = 0).

2. When a transfer request comes and transfer has been enabled, the DMAC transfers 1 transfer

unit of data (determined by TS0 and TS1 setting). For an auto-request, the transfer begins

automatically when the DE bit and DME bit are set to 1. The DMATCR value will be

decremented by 1 upon each transfer. The actual transfer flows vary by address mode and bus

mode.

3. When the specified number of transfers have been completed (when DMATCR reaches 0), the

transfer ends normally. If the IE bit of the CHCR is set to 1 at this time, a DEI interrupt is sent

to the CPU.

4. When an address error occurs in the DMAC or an NMI interrupt is generated, the transfer is

aborted. Transfers are also aborted when the DE bit of the CHCR or the DME bit of the

DMAOR are changed to 0.

229

Figure 11.2 is a flowchart of this procedure.

Normal end

Does

NMIF = 1, AE = 1,

DE = 0, or DME

= 0?

Bus mode,

transfer request mode,

DREQ detection selection

system

Initial settings

(SAR, DAR, TCR, CHCR, DMAOR)

Transfer (1 transfer unit);

DMATCR – 1 → DMATCR, SAR, and DAR

updated

DEI interrupt request (when IE = 1)

Yes

Start

Transfer aborted

Notes: *1

*2

*3

In auto-request mode, transfer begins when NMIF, AE, and TE are all 0,

and the DE and DME bits are set to 1.

DREQ = level detection in burst mode (external request), or cycle-steal

mode.

DREQ = edge detection in burst mode (external request), or auto-request

mode in burst mode.

DMATCR = 0?

Transfer request

occurs?*1

DE, DME = 1 and

NMIF, AE, TE = 0?

Does

NMIF = 1, AE = 1,

DE = 0, or DME

= 0?

Transfer ends

Figure 11.2 DMAC Transfer Flowchart

230

11.3.2 DMA Transfer Requests

DMA transfer requests are usually generated in either the data transfer source or destination, but

they can also be generated by devices and on-chip peripheral modules that are neither the source

nor the destination. Transfers can be requested in three modes: auto-request, external request, and

on-chip peripheral module request. The request mode is selected in the RS3–RS0 bits of the DMA

channel control registers 0–3 (CHCR0–CHCR3).

Auto-Request Mode: When there is no transfer request signal from an external source, as in a

memory-to-memory transfer or a transfer between memory and an on-chip peripheral module

unable to request a transfer, the auto-request mode allows the DMAC to automatically generate a

transfer request signal internally. When the DE bits of CHCR0–CHCR3 and the DME bit of the

DMAOR are set to 1, the transfer begins (so long as the TE bits of CHCR0–CHCR3 and the

NMIF and AE bits of DMAOR are all 0).

External Request Mode: In this mode a transfer is performed at the request signal (DREQ) of an

external device. Choose one of the modes shown in table 11.3 according to the application system.

When this mode is selected, if the DMA transfer is enabled (DE = 1, DME = 1, TE = 0, NMIF = 0,

AE = 0), a transfer is performed upon a request at the DREQ input. Choose to detect DREQ by

either the falling edge or low level of the signal input with the DS bit of CHCR0–CHCR3 (DS = 0

is level detection, DS = 1 is edge detection). The source of the transfer request does not have to be

the data transfer source or destination.

Table 11.3 Selecting External Request Modes with the RS Bits

RS3 RS2 RS1 RS0 Address Mode Source Destination

0000Dual address

mode Any*Any*

0010Single address

mode External memory or

memory-mapped

external device

External device with

DACK

0011Single address

mode External device with

DACK External memory or

memory-mapped

external device

Note: *External memory, memory-mapped external device, on-chip memory, on-chip peripheral

module (excluding DMAC, DTC, BSC, UBC).

On-Chip Peripheral Module Request Mode: In this mode a transfer is performed at the transfer

request signal (interrupt request signal) of an on-chip peripheral module. As indicated in table

11.4, there are ten transfer request signals: five from the multifunction timer pulse unit (MTU),

which are compare match or input capture interrupts; the receive data full interrupts (RxI) and

transmit data empty interrupts (TxI) of the two serial communication interfaces (SCI); and the A/D

conversion end interrupt (ADI1 for A mask, ADI for others) of the A/D converter. When DMA

231

transfers are enabled (DE = 1, DME = 1, TE = 0, NMIF = 0, AE = 0), a transfer is performed upon

the input of a transfer request signal.

The transfer request source need not be the data transfer source or transfer destination. However,

when the transfer request is set by RxI (transfer request because SCI’s receive data is full), the

transfer source must be the SCI’s receive data register (RDR). When the transfer request is set by

TxI (transfer request because SCI’s transmit data is empty), the transfer destination must be the

SCI’s transmit data register (TDR). Also, if the transfer request is set to the A/D converter, the

data transfer destination must be the A/D converter register.

Table 11.4 Selecting On-Chip Peripheral Module Request Modes with the RS Bits

RS3 RS2 RS1 RS0 DMAC Transfer

Request Source DMA Transfer

Request SignalSource Destin-

ation Bus Mode

0110 MTU

*2TGI0A Any*1Any*1Burst/cycle steal

0111 MTU

*2TGI1A Any*1Any*1Burst/cycle steal

1000 MTU

*2TGI2A Any*1Any*1Burst/cycle steal

1001 MTU

*2TGI3A Any*1Any*1Burst/cycle steal

1010 MTU

*2TGI4A Any*1Any*1Burst/cycle steal

1011 A/D ADI

*5ADDR*4Any*1Burst/cycle steal

1100 SCI0*3 transmit block TxI0 Any*1TDR0 Burst/cycle steal

1101 SCI0*3 transmit block RxI0 RDR0 Any*1Burst/cycle steal

1110 SCI1*3 transmit block TxI1 Any*1TDR1 Burst/cycle steal

1111 SCI1*3 transmit block RxI1 RDR1 Any*1Burst/cycle steal

Notes: *1 External memory, memory-mapped external device, on-chip memory, on-chip

peripheral module (excluding DMAC, DTC, BSC, UBC).

*2 MTU: Multifunction timer pulse unit.

*3 SCI0, SCI1: Serial communications interface.

*4 ADDR0, ADDR1: A/D converter’s A/D register.

*5 ADI1 for A mask.

In order to output a transfer request from an on-chip peripheral module, set the relevant interrupt

enable bit for each module, and output an interrupt signal.

When an on-chip peripheral module’s interrupt request signal is used as a DMA transfer request

signal, interrupts for the CPU are not generated.

When a DMA transfer is conducted corresponding with one of the transfer request signals in table

11.4, it is automatically discontinued. In cycle steal mode this occurs in the first transfer, and in

burst mode with the last transfer.

232

11.3.3 Channel Priority

When the DMAC receives simultaneous transfer requests on two or more channels, it selects a

channel according to a predetermined priority order, either in a fixed mode or in round robin

mode. These modes are selected by priority bits PR1 and PR0 in the DMA operation register

(DMAOR).

Fixed Mode: In these modes, the priority levels among the channels remain fixed.

The following priority orders are available for fixed mode:

• CH0 > CH1 > CH2 > CH3

• CH0 > CH2 > CH3 > CH1

• CH2 > CH0 > CH1 > CH3

These are selected by settings of the PR1 and PR0 bits of the DMA operation register (DMAOR).

Round Robin Mode: In round robin mode, each time the transfer of one transfer unit (byte, word

or long word) ends on a given channel, that channel receives the lowest priority level (figure 11.3).

The priority level in round robin mode immediately after a reset is CH0 > CH1 > CH2 > CH3.

233

CH1 > CH2 > CH3 > CH0

CH0 > CH1 > CH2 > CH3

CH2 > CH3 > CH0 > CH1

CH0 > CH1 > CH2 > CH3

CH2 > CH3 > CH0 > CH1

CH0 > CH1 > CH2 > CH3

CH3 > CH0 > CH1 > CH2

CH0 > CH1 > CH2 > CH3

Transfer on channel 0

Initial priority setting

Initial priority setting No change in priority.

When channel 2 receives the

lowest priority, the priorities

of channel 0 and 1, which

were above channel 2, are also

shifted simultaneously. Immedi-

ately thereafter, if there is a transfer

request for channel 1 only, channel

1 is given the lowest priority,

and the priorities of channels 3

and 0 are simultaneously

shifted down.

When channel 1 is given the

lowest priority, the priority

of channel 0, which was

above channel 1, is also shifted

simultaneously.

Channel 0 is given the lowest

priority.

Priority after transfer

due to issue of a transfer

request for channel 1

only.

Transfer on channel 1

Transfer on channel 2

Transfer on channel 3

Figure 11.3 Round Robin Mode

234

Figure 11.4 shows the changes in priority levels when transfer requests are issued simultaneously

for channels 0 and 3, and channel 1 receives a transfer request during a transfer on channel 0. The

DMAC operates in the following manner under these circumstances:

1. Transfer requests are issued simultaneously for channels 0 and 3.

2. Since channel 0 has a higher priority level than channel 3, the channel 0 transfer is conducted

first (channel 3 is on transfer standby).

3. A transfer request is issued for channel 1 during a transfer on channel 0 (channels 1 and 3 are

on transfer standby).

4. At the end of the channel 0 transfer, channel 0 shifts to the lowest priority level.

5. At this point, channel 1 has a higher priority level than channel 3, so the channel 1 transfer

comes first (channel 3 is on transfer standby).

6. When the channel 1 transfer ends, channel 1 shifts to the lowest priority level.

7. Channel 3 transfer begins.

8. When the channel 3 transfer ends, channel 3 and channel 2 priority levels are lowered, giving

channel 3 the lowest priority.

Transfer request Channel waiting DMAC operation Channel priority

Issued for

channels 0 and 3

Issued for channel 1

0 > 1 > 2 > 3Channel 0 

transfer begins

1 > 2 > 3 > 0Channel 0

transfer ends

Channel 1

transfer begins



Channel 3

transfer begins



2 > 3 > 0 > 1Channel 1 

transfer ends

0 > 1 > 2 > 3Channel 3

transfer ends

Change of 

priority

Change of 

priority

Change of 

priority

None

1,3

Figure 11.4 Example of Changes in Priority in Round Robin Mode

235

11.3.4 DMA Transfer Types

The DMAC supports the transfers shown in table 11.5. It can operate in the single address mode,

in which either the transfer source or destination is accessed using an acknowledge signal, or dual

access mode, in which both the transfer source and destination addresses are output. The dual

access mode consists of a direct address mode, in which the output address value is the object of a

direct data transfer, and an indirect address mode, in which the output address value is not the

object of the data transfer, but the value stored at the output address becomes the transfer object

address. The actual transfer operation timing varies with the bus mode. The DMAC has two bus

modes: cycle-steal mode and burst mode.

Table 11.5 Supported DMA Transfers

Destination

Source External Device

with DACK External

Memory

Memory-

Mapped

External

Device On-Chip

Memory

On-Chip

Peripheral

Module

External device with DACK Not available Single Single Not available Not available

External memory Single Dual Dual Dual Dual

Memory-mapped external

device Single Dual Dual Dual Dual

On-chip memory Not available Dual Dual Dual Dual

On-chip peripheral module Not available Dual Dual Dual Dual

Notes: 1. Single: Single address mode

2. Dual: Dual address mode; includes both direct address mode and indirect address

mode.

11.3.5 Address Modes

Single Address Mode: In the single address mode, both the transfer source and destination are

external; one (selectable) is accessed by a DACK signal while the other is accessed by an address.

In this mode, the DMAC performs the DMA transfer in 1 bus cycle by simultaneously outputting a

transfer request acknowledge DACK signal to one external device to access it while outputting an

address to the other end of the transfer. Figure 11.5 shows an example of a transfer between an

external memory and an external device with DACK in which the external device outputs data to

the data bus while that data is written in external memory in the same bus cycle.

236

DMAC

DACK

DREQ

External

memory

External device



with DACK

This LSI

External address bus

: Data flow

External data bus

Figure 11.5 Data Flow in Single Address Mode

Two types of transfers are possible in the single address mode: (a) transfers between external

devices with DACK and memory-mapped external devices, and (b) transfers between external

devices with DACK and external memory. The only transfer requests for either of these is the

external request (DREQ). Figure 11.6 shows the DMA transfer timing for the single address mode.

237

A21–A0

CSn

D15–D0

DACK

WRH

WRL

Address output to external memory space

Data that is output from the external

device with DACK

DACK signal to external devices with

DACK (active low)

WR signal to external memory space

a. External device with DACK to external memory space

A21–A0

CSn

D15–D0

Address output to external memory space

Data that is output from external memory space

RD signal to external memory space

DACK signal to external device with DACK 

(active low)

DACK

b. External memory space to external device with DACK

Figure 11.6 Example of DMA Transfer Timing in the Single Address Mode

11.3.6 Dual Address Mode

Dual address mode is used for access of both the transfer source and destination by address.

Transfer source and destination can be accessed either internally or externally. Dual address mode

is subdivided into two other modes: direct address transfer mode and indirect address transfer

mode.

Direct Address Transfer Mode: Data is read from the transfer source during the data read cycle,

and written to the transfer destination during the write cycle, so transfer is conducted in two bus

cycles. At this time, the transfer data is temporarily stored in the DMAC. With the kind of external

memory transfer shown in figure 11.7, data is read from one of the memories by the DMAC

during a read cycle, then written to the other external memory during the subsequent write cycle.

Figure 11.8 shows the timing for this operation.

238

Data buffer

Address bus

Data bus

Address bus

Data bus

Memory

Transfer source

module

Transfer destination

module

Memory

Transfer source

module

Transfer destination

module

SAR

DAR

Data buffer

SAR

DAR

The SAR value is taken as the address, and data is read from the transfer source



module and stored temporarily in the DMAC.

1st bus cycle

2nd bus cycle

The D AR value is taken as the address, and data stored in the DMAC's data

buffer is written to the transfer destination module.

DMAC

Figure 11.7 Direct Address Operation during Dual Address Mode

239

Data read cycle

Data write cycle



Transfer destination

address

Transfer source 

address



(1st cycle) (2nd cycle)

A21–A0

CSn

D15–D0

WRH, WRL

DACK

Note: Transfer between external memories with DACK are output during read

cycle.

Figure 11.8 Example of Direct Address Transfer Timing in Dual Address Mode

240

Indirect Address Transfer Mode: In this mode the memory address storing the data you actually

want to transfer is specified in DMAC internal transfer source address register (SAR3). Therefore,

in indirect address transfer mode, the DMAC internal transfer source address register value is read

first. This value is stored once in the DMAC. Next, the read value is output as the address, and the

value stored at that address is again stored in the DMAC. Finally, the subsequent read value is

written to the address specified by the transfer destination address register, ending one cycle of

DMA transfer.

In indirect address mode (figure 11.9), transfer destination, transfer source, and indirect address

storage destination are all 16-bit external memory locations, and transfer in this example is

conducted in 16-bit or 8-bit units. Timing for this transfer example is shown in figure 11.10.

In indirect address mode, one NOP cycle (figure 11.10) is required until the data read as the

indirect address is output to the address bus. When transfer data is 32-bit, the third and fourth bus

cycles each need to be doubled, giving a required total of six bus cycles and one NOP cycle for the

whole operation.

241

SAR3

DAR3

Data

buffer

Address bus

Data bus

Memory

Transfer source

module

Transfer destination

module

Temporary

buffer

The SAR3 value is taken as the address, memory data is read, and the value is stored in the



temporary buffer. Since the value read at this time is used as the address, it must be 32 bits.



When external connection data bus is 16 bits, two bus cycles are required.

DMAC

SAR3

DAR3

Data

buffer

Address bus

Data bus

Memory

Transfer source

module

Transfer destination

module

Temporary

buffer

The value in the temporary buff er is taken as the address, and data is read from the 

transfer source module to the data buffer.

SAR3

DAR3

Data

buffer

Address bus

Data bus

Memory

Transfer source

module

Transfer destination

module

Temporary

buffer

The DAR3 value is taken as the address, and the value in the data buffer is written to the

transfer destination module.

Note: Memory, transfer source, and transfer destination modules are shown here.

In practice, connection can be made anywhere there is address space.

DMAC

1st, 2nd bus cycles

3rd bus cycle

4th bus cycle

Figure 11.9 Dual Address Mode and Indirect Address Operation

(When External Memory Space is 16 bits)

242

Transfer

source

address (H)

Transfer

source

address (L) Indirect

address

NOP Transfer

destination

address

Indirect

address (H) Indirect

address (L) Transfer

data

Transfer

data

Transfer

data

Transfer

data

Transfer

data

Transfer source

address *1

Indirect address *2

Indirect

address

NOP

Indirect

address

Address read cycle

(1st) (2nd) (3rd)

NOP

cycle Data

read cycle

(4th)

Data

write cycle

A21–A0

CSn

D15–D0

Internal

address

bus

Internal

data bus

DMAC

indirect

address

buffer

DMAC

data

buffer

WRH,

WRL

Notes: *1

*2The internal address bus is controlled by the port and does not change.

DMAC does not fetch value until 32-bit data is read from the internal data

bus.

External memory space has 16-bit width.

Figure 11.10 Dual Address Mode and Indirect Address Transfer Timing Example 1

(External Memory Space to External Memory Space)

243

Figure 11.11 shows an example of timing in indirect address mode when transfer source and

indirect address storage locations are in internal memory, the transfer destination is an on-chip

peripheral module with 2-cycle access space, and transfer data is 8-bit.

Since the indirect address storage destination and the transfer source are in internal memory, these

can be accessed in one cycle. The transfer destination is 2-cycle access space, so two data write

cycles are required. One NOP cycle is required until the data read as the indirect address is output

to the address bus.

Internal

address

bus

Internal

data

bus

DMAC

indirect 

address

buffer

DMAC

data

buffer

Transfer 

source 

address NOP

NOP

Indirect

address

Transfer

destination

address

Indirect 

address

Indirect 

address

Transfer

data Transfer data

Transfer data

Address

read cycle NOP

cycle Data

read cycle Data write cycle (4th)

(1st) (2nd) (3rd)



Figure 11.11 Dual Address Mode and Indirect Address Transfer Timing Example 2

(On-chip Memory Space to On-chip Memory Space)

244

11.3.7 Bus Modes

Select the appropriate bus mode in the TM bits of CHCR0–CHCR3. There are two bus modes:

cycle steal and burst.

Cycle-Steal Mode: In the cycle steal mode, the bus right is given to another bus master after each

one-transfer-unit (byte, word, or longword) DMAC transfer. When the next transfer request

occurs, the bus rights are obtained from the other bus master and a transfer is performed for one

transfer unit. When that transfer ends, the bus right is passed to the other bus master. This is

repeated until the transfer end conditions are satisfied.

The cycle steal mode can be used with all categories of transfer destination, transfer source and

transfer request. Figure 11.12 shows an example of DMA transfer timing in the cycle steal mode.

Transfer conditions are dual address mode and DREQ level detection.

CPU CPU CPU DMAC DMAC CPU DMAC DMAC CPU CPU

DREQ

Bus cycle

Bus control returned to CPU

Read Write WriteRead

Figure 11.12 DMA Transfer Example in the Cycle-Steal Mode

Burst Mode: Once the bus right is obtained, the transfer is performed continuously until the

transfer end condition is satisfied. In the external request mode with low level detection of the

DREQ pin, however, when the DREQ pin is driven high, the bus passes to the other bus master

after the bus cycle of the DMAC that currently has an acknowledged request ends, even if the

transfer end conditions have not been satisfied.

Figure 11.13 shows an example of DMA transfer timing in the burst mode. Transfer conditions are

single address mode and DREQ level detection.

CPU CPU CPU DMAC DMAC DMAC DMAC DMAC

DREQ

Bus cycle DMAC CPU

Figure 11.13 DMA Transfer Example in the Burst Mode

245

11.3.8 Relationship between Request Modes and Bus Modes by DMA Transfer Category

Table 11.6 shows the relationship between request modes and bus modes by DMA transfer

category.

Table 11.6 Relationship of Request Modes and Bus Modes by DMA Transfer Category

Address

Mode Transfer Category Request

Mode Bus*6

Mode Transfer

Size (Bits) Usable

Channels

Single External device with DACK and

external memory External B/C 8/16/32 0, 1

External device with DACK and

memory-mapped external device External B/C 8/16/32 0, 1

Dual External memory and external memory Any*1B/C 8/16/32 0–3*5

External memory and memory-mapped

external device Any*1B/C 8/16/32 0–3*5

Memory-mapped external device and

memory-mapped external device Any*1B/C 8/16/32 0–3*5

External memory and on-chip memory Any*1B/C 8/16/32 0–3*5

External memory and on-chip

peripheral module Any*2B/C*38/16/32*40–3*5

Memory-mapped external device and

on-chip memory Any*1B/C 8/16/32 0–3*5

Memory-mapped external device and

on-chip peripheral module Any*2B/C*38/16/32*40–3*5

On-chip memory and on-chip memory Any*1B/C 8/16/32 0–3*5

On-chip memory and on-chip

peripheral module Any*2B/C*38/16/32*40–3*5

On-chip peripheral module and on-

chip peripheral module Any*2B/C*38/16/32*40–3*5

Notes: *1 External request, auto-request or on-chip peripheral module request enabled. However,

in the case of on-chip peripheral module request, it is not possible to specify the SCI or

A/D converter for the transfer request source.

*2 External request, auto-request or on-chip peripheral module request possible. However,

if transfer request source is also the SCI or A/D converter (A/D1 for A mask), the

transfer source or transfer destination must be the SCI or A/D converter (A/D1 for A

mask). For A mask, setting A/D0 as the transfer request source is not permitted.

*3 When the transfer request source is the SCI, only cycle steal mode is possible.

*4 Access size permitted by register of on-chip peripheral module that is the transfer

source or transfer destination.

*5 When the transfer request is an external request, channels 0 and 1 only can be used.

*6 B: Burst, C: Cycle steal

246

11.3.9 Bus Mode and Channel Priority Order

When a given channel is transferring in burst mode, and a transfer request is issued to channel 0,

which has a higher priority ranking, transfer on channel 0 begins immediately. If the priority level

setting is fixed mode (CH0 > CH1), channel 1 transfer is continued after transfer on channel 0 are

completely ended, whether the channel 0 setting is cycle steal mode or burst mode.

When the priority level setting is for round robin mode, transfer on channel 1 begins after transfer

of one transfer unit on channel 0, whether channel 0 is set to cycle steal mode or burst mode.

Thereafter, bus right alternates in the order: channel 1 > channel 0 > channel 1 > channel 0.

Whether the priority level setting is for fixed mode or round robin mode, since channel 1 is set to

burst mode, the bus right is not given to the CPU. An example of round robin mode is shown in

figure 11.14.

CPU DMAC

ch1 DMAC

ch0 DMAC

ch1 DMAC

ch0 DMAC

ch1 DMAC

ch1 CPU

ch0 ch1 ch0

DMAC ch0 and ch1

round-robin mode DMAC ch1

burst mode CPUCPU

Priority: Round-robin mode

ch0: Cycle-steal mode 

ch1: Burst mode

DMAC ch1

burst mode

Figure 11.14 Bus Handling when Multiple Channels Are Operating

11.3.10 Number of Bus Cycle States and DREQ Pin Sample Timing

Number of States in Bus Cycle: The number of states in the bus cycle when the DMAC is the

bus master is controlled by the bus state controller (BSC) just as it is when the CPU is the bus

master. For details, see section 10, Bus State Controller (BSC).

DREQ Pin Sampling Timing and DRAK Signal: In external request mode, the DREQ pin is

sampled by either falling edge or low-level detection. When a DREQ input is detected, a DMAC

bus cycle is issued and DMA transfer effected, at the earliest, after three states. However, in burst

mode when single address operation is specified, a dummy cycle is inserted for the first bus cycle.

In this case, the actual data transfer starts from the second bus cycle. Data is transferred

continuously from the second bus cycle. The dummy cycle is not counted in the number of

transfer cycles, so there is no need to recognize the dummy cycle when setting the TCR.

DREQ sampling from the second time begins from the start of the transfer one bus cycle prior to

the DMAC transfer generated by the previous sampling.

247

DRAK is output once for the first DREQ sampling, irrespective of transfer mode or DREQ

detection method. In burst mode, using edge detection, DREQ is sampled for the first cycle only,

so DRAK is also output for the first cycle only. Therefore, the DREQ signal negate timing can be

ascertained, and this facilitates handshake operations of transfer requests with the DMAC.

Cycle Steal Mode Operations: In cycle steal mode, DREQ sampling timing is the same

irrespective of dual or single address mode, or whether edge or low-level DREQ detection is used.

For example, DMAC transfer begins (figure 11.15), at the earliest, three cycles from the first

sampling timing. The second sampling begins at the start of the transfer one bus cycle prior to the

start of the DMAC transfer initiated by the first sampling (i.e., from the start of the CPU(3)

transfer). At this point, if DREQ detection has not occurred, sampling is executed every cycle

thereafter.

As in figure 11.16, whatever cycle the CPU transfer cycle is, the next sampling begins from the

start of the transfer one bus cycle before the DMAC transfer begins.

Figure 11.15 shows an example of output during DACK read and figure 11.16 an example of

output during DACK write.

248

REQ

DRAK

Bus 

cycle

DACK

CPU(3) CPU(4) CPU(5) CPU(2)CPU(1)

1st sampling 2nd sampling

DMAC(R) DMAC(R)DMAC(W) DMAC(W) DMAC(W)DMAC(R)



Figure 11.15 Cycle Steal, Dual Address, and Level Detection (Fastest Operation)

249

DREQ

DRAK

Bus 

cycle

DACK

CPU

CPU CPU CPU DMAC(R) DMAC



(R)



DMAC(W)

1st sampling 2nd sampling

Note: With cycle-steal and dual address operation, sampling timing is the same

whether DREQ detection is by level or by edge.



Figure 11.16 Cycle Steal, Dual Address, and Level Detection (Normal Operation)

250

Figures 11.17 and 11.18 show cycle steal mode and single address mode. In this case, transfer

begins at earliest three cycles after the first DREQ sampling. The second sampling begins from the

start of the transfer one bus cycle before the start of the first DMAC transfer. In single address

mode, the DACK signal is output during the DMAC transfer period.

251

DREQ

DRAK

Bus 

cycle

DACK

CPU CPU CPU CPUCPU DMAC DMAC



DMAC

Figure 11.17 Cycle Steal, Single Address, and Level Detection (Fastest Operation)

252

DREQ

DRAK

Bus 

cycle

DACK

CPUCPU



DMACCPU DMACCPU CPU

Figure 11.18 Cycle Steal, Single Address, and Level Detection (Normal Operation)

253

Burst Mode, Dual Address, and Level Detection: DREQ sampling timing in burst mode with

dual address and level detection is virtually the same as that of cycle steal mode.

For example, DMAC transfer begins (figure 11.19), at the earliest, three cycles after the timing of

the first sampling. The second sampling also begins from the start of the transfer one bus cycle

before the start of the first DMAC transfer. In burst mode, as long as transfer requests are issued,

DMAC transfer continues. Therefore, the “transfer one bus cycle before the start of the DMAC

transfer” may be a DMAC transfer.

In burst mode, the DACK output period is the same as that of cycle steal mode. Figure 11.20

shows the normal operation of this burst mode.

254

DREQ

DRAK

Bus 

cycle

DACK

CPU  CPU CPUCPU DMAC(R) DMAC(W) DMAC(R)DMAC(R)



DMAC(W)DMAC(R) DMAC(W)

Figure 11.19 Burst Mode, Dual Address, and Level Detection (Fastest Operation)

255

DREQ

DRAK

Bus 

cycle

DACK



CPUCPU DMAC(R) DMAC(R)

DMAC(R)



CPU DMAC(W) DMAC(W)

Figure 11.20 Burst Mode, Dual Address, and Level Detection (Normal Operation)

256

Burst Mode, Single Address, and Level Detection: DREQ sampling timing in burst mode with

single address and level detection is shown in figures 11.21 and 11.22.

In burst mode with single address and level detection, a dummy cycle is inserted as one bus cycle,

at the earliest, three cycles after timing of the first sampling. Data during this period is undefined,

and the DACK signal is not output. Nor is the number of DMAC transfers counted. The actual

DMAC transfer begins after one dummy bus cycle output.

The dummy cycle is not counted either at the start of the second sampling (transfer one bus cycle

before the start of the first DMAC transfer). Therefore, the second sampling is not conducted from

the bus cycle starting the dummy cycle, but from the start of the CPU(3) bus cycle.

Thereafter, as long the DREQ is continuously sampled, no dummy cycle is inserted. DREQ

sampling timing during this period begins from the start of the transfer one bus cycle before the

start of DMAC transfer, in the same way as with cycle steal mode.

As with the fourth sampling in figure 11.21, once DMAC transfer is interrupted, a dummy cycle is

again inserted at the start as soon as DMAC transfer is resumed.

The DACK output period in burst mode is the same as in cycle steal mode.

257

DREQ

DRAK

Bus 

cycle

DACK

CPU(4)

CPU(1) CPU(2) CPU(3) Dummy DMAC Dummy



2nd sampling1st sampling 3rd sampling 4th sampling

DMAC DMAC

Figure 11.21 Burst Mode, Single Address, and Level Detection (Fastest Operation)

258

DREQ

DRAK

Bus 

cycle

DACK



CPUCPU Dummy DMAC



CPU DMAC DMAC

Figure 11.22 Burst Mode, Single Address, and Level Detection (Normal Operation)

259

Burst Mode, Dual Address, and Edge Detection: In burst mode with dual address and edge

detection, DREQ sampling is conducted only on the first cycle.

In figure 11.23, DMAC transfer begins, at the earliest, three cycles after the timing of the first

sampling. Thereafter, DMAC transfer continues until the end of the data transfer count set in the

TCR. DREQ sampling is not conducted during this period. Therefore, DRAK is output on the first

cycle only.

When DMAC transfer is resumed after being halted by a NMI or address error, be sure to reinput

an edge request. The remaining transfer restarts after the first DRAK output.

The DACK output period in burst mode is the same as in cycle steal mode.

260

DREQ

DRAK

Bus 

cycle

DACK

CPU  CPUCPU DMAC(R)

DMAC(R) DMAC(R) DMAC(R)DMAC(W) DMAC(W) DMAC(W) DMAC(W)

Figure 11.23 Burst Mode, Dual Address, and Edge Detection

261

Burst Mode, Single Address, and Edge Detection: In burst mode with single address and edge

detection, DREQ sampling is conducted only on the first cycle. In figure 11.24, a dummy cycle is

inserted, at the earliest, three cycles after the timing for the first sampling. During this period, data

is undefined, and DACK is not output. Nor is the number of DMAC transfers counted. Thereafter,

DMAC transfer continues until the data transfer count set in the DMATCR has ended. DREQ

sampling is not conducted during this period. Therefore, DRAK is output on the first cycle only.

When DMAC transfer is resumed after being halted by a NMI or address error, be sure to reinput

an edge request. DRAK is output once, and the remaining transfer restarts after output of one

dummy cycle.

The DACK output period in burst mode is the same as in cycle steal mode.

262

DREQ

DRAK

Bus 

cycle

DACK

CPU DMAC DMAC DMAC DMAC CPUCPU 

Dummy

Figure 11.24 Burst Mode, Single Address and Edge Detection

263

11.3.11 Source Address Reload Function

Channel 2 has a source address reload function. This returns to the first value set in the source

address register (SAR2) every four transfers by setting the RO bit of CHCR2 to 1. Figure 11.25

illustrates this operation. Figure 11.26 is a timing chart for reload ON mode, with burst mode,

autorequest, 16-bit transfer data size, SAR2 increment, and DAR2 fixed mode.

SAR2

(initial value)

DMAC

Transfer

request

DMAC control block

Reload control

4th count

CHCR2

DMATCR2

SAR2

RO bit = 1

Count signal

Reload 

signal

Reload signal

Address bus

Figure 11.25 Source Address Reload Function

Internal

address bus

Internal

data bus

SAR2 DAR2 DAR2 DAR2 DAR2SAR2+2 SAR2+4 SAR2+6 SAR2 DAR2

SAR2 data SAR2+2 data SAR2+4 data SAR2+6 data SAR2 data

1st channel 2

transfer 2nd channel 2

transfer 3rd channel 2

transfer 4th channel 2

transfer 5th channel 2

transfer

SAR2 output

DAR2 output SAR2+2 output

DAR2 output SAR2+4 output

DAR2 output SAR2+6 output

DAR2 output SAR2 output

DAR2 output

After SAR2+6 output, SAR2 is reloaded Bus right is returned one time in four

Figure 11.26 Source Address Reload Function Timing Chart

264

The reload function can be executed whether the transfer data size is 8, 16, or 32 bits.

DMATCR2, which specifies the number of transfers, is decremented by 1 at the end of every

single-transfer-unit transfer, regardless of whether the reload function is on or off. Therefore,

when using the reload function in the on state, a multiple of 4 must be specified in DMATCR2.

Operation will not be guaranteed if any other value is set. Also, the counter which counts the

occurrence of four transfers for address reloading is reset by clearing of the DME bit in DMAOR

or the DE bit in CHCR2, setting of the transfer end flag (the TE bit in CHCR2), NMI input, and

setting of the AE flag (address error generation in DMAC transfer), as well as by a reset and in

software standby mode, but SAR2, DAR2, DMATCR2, and other registers are not reset.

Consequently, when one of these sources occurs, there is a mixture of initialized counters and

uninitialized registers in the DMAC, and incorrect operation may result if a restart is executed in

this state. Therefore, when one of the above sources, other than TE setting, occurs during use of

the address reload function, SAR, DAR2, and DMATCR2 settings must be carried out before re-

execution.

11.3.12 DMA Transfer Ending Conditions

The DMA transfer ending conditions vary for individual channels ending and for all channels

ending together.

Individual Channel Ending Conditions: There are two ending conditions. A transfer ends when

the value of the channel’s DMA transfer count register (DMATCR) is 0, or when the DE bit of the

channel’s CHCR is cleared to 0.

• When DMATCR is 0: When the DMATCR value becomes 0 and the corresponding channel's

DMA transfer ends, the transfer end flag bit (TE) is set in the CHCR. If the IE (interrupt

enable) bit has been set, a DMAC interrupt (DEI) is requested of the CPU.

• When DE of CHCR is 0: Software can halt a DMA transfer by clearing the DE bit in the

channel’s CHCR. The TE bit is not set when this happens.

Conditions for Ending All Channels Simultaneously: Transfers on all channels end when the

NMIF (NMI flag) bit or AE (address error flag) bit is set to 1 in the DMAOR, or when the DME

bit in the DMAOR is cleared to 0.

• When the NMIF or AE bit is set to 1 in DMAOR: When an NMI interrupt or DMAC address

error occurs, the NMIF or AE bit is set to 1 in the DMAOR and all channels stop their

transfers. The DMAC obtains the bus rights, and if these flags are set to 1 during execution of

a transfer, DMAC halts operation when the transfer processing currently being executed ends,

and transfers the bus right to the other bus master. Consequently, even if the NMIF or AE bits

are set to 1 during a transfer, the DMA source address register (SAR), designation address

resume the transfers after NMI interrupt or address error processing, clear the appropriate flag

bit to 0. To avoid restarting a transfer on a particular channel, clear its DE bit to 0.

265

When the processing of a one unit transfer is complete. In a dual address mode direct address

transfer, even if an address error occurs or the NMI flag is set during read processing, the

transfer will not be halted until after completion of the following write processing. In such a

case, SAR, DAR, and TCR values are updated. In the same manner, the transfer is not halted in

dual address mode indirect address transfers until after the final write processing has ended.

• When DME is cleared to 0 in DMAOR: Clearing the DME bit to 0 in the DMAOR aborts the

transfers on all channels. The TE bit is not set.

11.3.13 DMAC Access from CPU

The space addressed by the DMAC is 3-cycle space. Therefore, when the CPU becomes the bus

master and accesses the DMAC, a minimum of three basic clock (CLK) cycles are required for

one bus cycle. Also, since the DMAC is located in word space, while a word-size access to the

DMAC is completed in one bus cycle, a longword-size access is automatically divided into two

word accesses, requiring two bus cycles (six basic clock cycles). These two bus cycles are

executed consecutively; a different bus cycle is never inserted between the two word accesses.

This applies to both write accesses and read accesses.

11.4 Examples of Use

11.4.1 Example of DMA Transfer between On-Chip SCI and External Memory

In this example, on-chip serial communication interface channel 0 (SCI0) received data is

transferred to external memory using the DMAC channel 3.

Table 11.7 indicates the transfer conditions and the setting values of each of the registers.

Table 11.7 Transfer Conditions and Register Set Values for Transfer between On-Chip

SCI and External Memory

Transfer Conditions Register Value

Transfer source: RDR0 of on-chip SCI0 SAR3 H'FFFF81A5

Transfer destination: external memory DAR3 H'00400000

Transfer count: 64 times DMATCR3 H'00000040

Transfer source address: fixed CHCR3 H'00004D05

Transfer destination address: incremented

Transfer request source: SCI0 (RDR0)

Bus mode: cycle steal

Transfer unit: byte

Interrupt request generation at end of transfer

Channel priority ranking: 0 > 1 > 2 > 3 DMAOR H'0001

266

11.4.2 Example of DMA Transfer between External RAM and External Device with

DACK

In this example, an external request, serial address mode transfer with external memory as the

transfer source and an external device with DACK as the transfer destination is executed using

DMAC channel 1.

Table 11.8 indicates the transfer conditions and the setting values of each of the registers.

Table 11.8 Transfer Conditions and Register Set Values for Transfer between External

RAM and External Device with DACK

Transfer Conditions Register Value

Transfer source: external RAM SAR1 H'00400000

Transfer destination: external device with DACK DAR1 (access by DACK)

Transfer count: 32 times DMATCR1 H'00000020

Transfer source address: decremented CHCR1 H'00002269

Transfer destination address: (setting ineffective)

Transfer request source: external pin (DREQ1) edge

detection

Bus mode: burst

Transfer unit: word

No interrupt request generation at end of transfer

Channel priority ranking: 2 > 0 > 1 > 3 DMAOR H'0201

11.4.3 Example of DMA Transfer between A/D Converter and On-Chip Memory

(Address Reload On) (Excluding A Mask)

In this example, the on-chip A/D converter channel 0 is the transfer source and on-chip memory is

the transfer destination, and the address reload function is on.

Table 11.9 indicates the transfer conditions and the setting values of each of the registers.

267

Table 11.9 Transfer Conditions and Register Set Values for Transfer between A/D

Converter and On-Chip Memory

Transfer Conditions Register Value

Transfer source: on-chip A/D converter ch0 SAR2 H'FFFF83F0

Transfer destination: on-chip memory DAR2 H'FFFFF000

Transfer count: 128 times (reload count 32 times) DMATCR2 H'00000080

Transfer source address: incremented CHCR2 H'00085B25

Transfer destination address: incremented

Transfer request source: A/D converter

Bus mode: burst

Transfer unit: byte

Interrupt request generation at end of transfer

Channel priority ranking: 0 > 2 > 3 > 1 DMAOR H'0101

When address reload is on, the SAR value returns to its initially established value every four

transfers. In the above example, when a transfer request is input from the A/D converter, the byte

size data is first read in from the H'FFFF83F0 register of AD0 and that data is written to the on-

chip memory address H'FFFFF001. Because a byte size transfer was performed, the SAR and

DAR values at this point are H'FFFF83F1 and H'FFFFF001, respectively. Also, because this is a

burst transfer, the bus rights remain secured, so continuous data transfer is possible.

When four transfers are completed, if the address reload is off, execution continues with the fifth

and sixth transfers and the SAR value continues to increment from H'FFFF83F3 to H'FFFF83F4 to

H'FFFF83F5 and so on. However, when the address reload is on, the DMAC transfer is halted

upon completion of the fourth one and the bus right request signal to the CPU is cleared. At this

time, the value stored in SAR is not H'FFFF83F3–H'FFFF83F4, but H'FFFF83F3–H'FFFF83F0, a

return to the initially established address. The DAR value always continues to be decremented

regardless of whether the address reload is on or off.

The DMAC internal status, due to the above operation after completion of the fourth transfer, is

indicated in table 11.10 for both address reload on and off.

268

Table 11.10 DMAC Internal Status

Item Address Reload On Address Reload Off

SAR H'FFFF83F0 H'FFFF83F4

DAR H'FFFFF004 H'FFFFF004

DMATCR H'0000007C H'0000007C

Bus rights Released Maintained

DMAC operation Halted Processing continues

Interrupts Not issued Not issued

Transfer request source flag clear Executed Not executed

Notes: 1. Interrupts are executed until the DMATCR value becomes 0, and if the IE bit of the

CHCR is set to 1, are issued regardless of whether the address reload is on or off.

2. If transfer request source flag clears are executed until the DMATCR value becomes 0,

they are executed regardless of whether the address reload is on or off.

3. Designate burst mode when using the address reload function. There are cases where

abnormal operation will result if it is executed in cycle steal mode.

4. Designate a multiple of four for the TCR value when using the address reload function.

There are cases where abnormal operation will result if anything else is designated.

To execute transfers after the fifth one when the address reload is on, make the transfer request

source issue another transfer request signal.

11.4.4 Example of DMA Transfer between A/D Converter and Internal Memory (Address

Reload On) (A Mask)

In this example the on-chip A/D converter (A/D1) is the transfer source and the internal memory is

the transfer destination, and the address reload on.

Table 11.11 indicates the transfer conditions and the setting values of each of the registers.

269

Table 11.11 Transfer Conditions and Register Set Values for Transfer between A/D

Converter (A/D1) and Internal Memory

Transfer Conditions Register Value

Transfer source: on-chip A/D converter (A/D1) SAR2 H'FFFF8408

Transfer destination: internal memory DAR2 H'FFFFF000

Transfer count: 128 times (reload count 32 times) DMATCR2 H'00000080

Transfer source address: incremented CHCR2 H'00085B25

Transfer target address: incremented

Transfer request source: A/D converter (A/D1)

Bus mode: burst

Transfer unit: byte

Interrupt request generated at end of transfer

Channel priority sequence: 0>2>3>1 DMAOR H'0101

When address reload is on, the SAR value returns to its initially established value every four

transfers. In the above example, when a transfer request is input from the A/D converter (A/D1),

the byte size data is first read in from the H'FFFF8408 register and that data is written to the on-

chip memory address H'FFFFF001. Because a byte size transfer was performed, the SAR and

DAR values at this point are H'FFFF8409 and H'FFFFF001, respectively. Also, because this is a

burst transfer, the bus rights remain secured, so continuous data transfer is possible.

When four transfers are completed, if the address reload is off, execution continues with the fifth

and sixth transfers and the SAR value continues to increment from H'FFFF840B to H'FFFF840C

to H'FFFF840D and so on. However, when the address reload is on, the DMAC transfer is halted

upon completion of the fourth transfer and the bus right request signal to the CPU is cleared. At

this time, the values stored in SAR are not H'FFFF840B–H'FFFF840C, but H'FFFF840B–

H'FFFF8408, a return to the initially established address. The DAR value always continues to be

decremented regardless of whether the address reload is on or off.

The DMAC internal status, due to the above operation after completion of the fourth transfer, is

indicated in table 11.12 for both address reload on and off.

270

Table 11.12 DMAC Internal Status

Item Address Reload On Address Reload Off

SAR H'FFFF8408 H'FFFF840C