Intel Computer Hardware 80C186EB User Manual

Intel 186 EB/EC  
Evaluation Board  
User’s Manual  
80C186EC/80C188EC  
80L186EC/80L188EC  
and  
80C186EB/80C188EB  
80L186EB/80L188EB  
March 1997  
Order Number: 272986-001  
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CONTENTS  
CHAPTER 1  
ABOUT THIS MANUAL  
1.1  
1.2  
1.3  
1.4  
1.4.1  
1.4.2  
1.5  
CONTENT OVERVIEW................................................................................................. 1-1  
NOTATION CONVENTIONS......................................................................................... 1-2  
RELATED DOCUMENTS .............................................................................................. 1-3  
ELECTRONIC SUPPORT SYSTEMS ........................................................................... 1-4  
FaxBack Service .......................................................................................................1-4  
World Wide Web .......................................................................................................1-4  
TECHNICAL SUPPORT ................................................................................................ 1-5  
CHAPTER 2  
GETTING STARTED  
2.1  
2.2  
2.3  
2.4  
SYSTEM REQUIREMENTS .......................................................................................... 2-3  
WHAT’S IN YOUR KIT................................................................................................... 2-3  
VIEWING THE BOARD SCHEMATICS......................................................................... 2-4  
SETTING UP THE EVALUATION BOARD AND THE HOST PC.................................. 2-4  
CHAPTER 3  
HARDWARE OVERVIEW  
3.1  
3.2  
JUMPER SUMMARY..................................................................................................... 3-1  
MICROPROCESSOR.................................................................................................... 3-2  
Packaging .................................................................................................................3-2  
MEMORY CONFIGURATION........................................................................................ 3-3  
Flash (Program Memory) ..........................................................................................3-5  
Configuring the Board for Flash Downloading .................................................3-5  
SRAM (Static Memory) .............................................................................................3-7  
PROGRAMMABLE LOGIC............................................................................................ 3-7  
POWER SUPPLY .......................................................................................................... 3-8  
SERIAL INTERFACE..................................................................................................... 3-9  
EXPANSION INTERFACE........................................................................................... 3-12  
LCD INTERFACE ........................................................................................................ 3-15  
LCD Interface Demo ...............................................................................................3-15  
3.2.1  
3.3  
3.3.1  
3.3.1.1  
3.3.2  
3.4  
3.5  
3.6  
3.7  
3.8  
3.8.1  
iii  
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CONTENTS  
CHAPTER 4  
INTRODUCTION TO THE SOFTWARE  
4.1  
4.2  
4.3  
4.4  
4.4.1  
4.4.2  
4.4.3  
SOFTWARE FEATURES .............................................................................................. 4-1  
RESTRICTIONS ............................................................................................................ 4-2  
EMBEDDED CONTROLLER MONITOR (ECM)............................................................ 4-2  
USER INTERFACE........................................................................................................ 4-3  
Numeric Input ............................................................................................................4-3  
Controlling Lengthy Commands ................................................................................4-3  
Aborting from iECM-86 .............................................................................................4-3  
INITIATING AND TERMINATING iECM-86................................................................... 4-3  
ECM86 ......................................................................................................................4-3  
-COM2, -COM1 .........................................................................................................4-4  
-DIAG ........................................................................................................................4-4  
-POLL, -SIGNAL .......................................................................................................4-5  
RESET SYSTEM, RES SYSTEM, RESET, RES ......................................................4-5  
DOS ..........................................................................................................................4-5  
QUIT .........................................................................................................................4-5  
RELATED INFORMATION ............................................................................................ 4-6  
Reserved Functions ..................................................................................................4-6  
Reserved Memory .....................................................................................................4-6  
Reserved I/O .............................................................................................................4-6  
4.5  
4.5.1  
4.5.2  
4.5.3  
4.5.4  
4.5.5  
4.5.6  
4.5.7  
4.6  
4.6.1  
4.6.2  
4.6.3  
CHAPTER 5  
iECM-86 COMMANDS  
5.1  
5.2  
5.2.1  
5.2.2  
5.3  
5.3.1  
5.3.2  
5.3.3  
5.3.4  
ENTERING COMMANDS.............................................................................................. 5-1  
FILE OPERATIONS....................................................................................................... 5-2  
Loading and Saving Object Code .............................................................................5-2  
Other File Operations ................................................................................................5-3  
PROGRAM CONTROL................................................................................................. 5-5  
Resetting the Target .................................................................................................5-5  
Breakpoints ...............................................................................................................5-5  
Program Execution ...................................................................................................5-7  
Program Stepping .....................................................................................................5-8  
DISPLAYING AND MODIFYING PROGRAM VARIABLES......................................... 5-10  
Supported Data Types ............................................................................................5-10  
BYTE Commands ...................................................................................................5-11  
WORD Commands .................................................................................................5-12  
DWORD Commands ...............................................................................................5-13  
STACK Commands .................................................................................................5-14  
STRING Commands ...............................................................................................5-15  
PORT Commands ...................................................................................................5-15  
WPORT Commands ...............................................................................................5-16  
Processor Variables ................................................................................................5-17  
5.4  
5.4.1  
5.4.2  
5.4.3  
5.4.4  
5.4.5  
5.4.6  
5.4.7  
5.4.8  
5.4.9  
iv  
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CONTENTS  
CHAPTER 6  
iRISM-186 COMMANDS  
6.1  
6.1.1  
IRISM VARIABLES........................................................................................................ 6-1  
Other Variables .........................................................................................................6-1  
RISM STRUCTURE....................................................................................................... 6-2  
RECEIVING DATA FROM THE HOST.......................................................................... 6-2  
SENDING DATA TO THE HOST................................................................................... 6-2  
RISM COMMANDS........................................................................................................ 6-2  
SET_DATA_FLAG (Code 00H) .................................................................................6-3  
TRANSMIT (Code 02H) ............................................................................................6-3  
READ_BYTE (Code 04H) .........................................................................................6-3  
READ_WORD (Code 05H) .......................................................................................6-3  
READ_DOUBLE (Code 06H) ....................................................................................6-3  
WRITE_BYTE (Code 07H) ........................................................................................6-3  
WRITE_WORD (Code 08H) ......................................................................................6-3  
WRITE_DOUBLE (Code 09H) ..................................................................................6-4  
LOAD_ADDRESS (Code 0AH) .................................................................................6-4  
6.2  
6.3  
6.4  
6.5  
6.5.1  
6.5.2  
6.5.3  
6.5.4  
6.5.5  
6.5.6  
6.5.7  
6.5.8  
6.5.9  
6.5.10 READ_PC (Code 10H) .............................................................................................6-4  
6.5.11 WRITE_PC (Code 11H) ............................................................................................6-4  
6.5.12 START_USER (Code 12H) .......................................................................................6-4  
6.5.13 STOP_USER (code 13H) .........................................................................................6-4  
6.5.14 TRAP_ISR ................................................................................................................6-5  
6.5.15 REPORT_STATUS (Code 14H) ...............................................................................6-5  
6.5.16 MONITOR_ESCAPE (Code 15H) .............................................................................6-5  
6.5.17 READ_BPORT (Code 16H) ......................................................................................6-5  
6.5.18 WRITE_BPORT (Code 17H) .....................................................................................6-5  
6.5.19 READ_WPORT (Code 18H) .....................................................................................6-5  
6.5.20 WRITE_WPORT (Code 19H) ....................................................................................6-6  
6.5.21 STEP (Code 1AH) .....................................................................................................6-6  
6.5.22 READ_REG (Code 1BH) ..........................................................................................6-6  
6.5.23 WRITE_REG (Code 1CH) .........................................................................................6-6  
6.5.24 Start Up Commands (/ or \) .......................................................................................6-7  
APPENDIX A  
PARTS LIST  
v
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CONTENTS  
FIGURES  
2-1  
2-2  
3-1  
3-2  
3-3  
3-4  
3-5  
3-6  
3-7  
Intel 186 EB Evaluation Board Layout..........................................................................2-1  
Intel 186 EC Evaluation Board Layout .........................................................................2-2  
Physical Memory Map..................................................................................................3-4  
Jumper Assembly for Flash Downloading....................................................................3-6  
E1 Jumper ....................................................................................................................3-8  
J2 Power Connector.....................................................................................................3-8  
25-Pin to 9-Pin Adaptor ..............................................................................................3-11  
186 EC Peripheral Expansion Connector JP2 (40 pin) ..............................................3-12  
186 EB Peripheral Expansion Connector JP2 (24 pin)...............................................3-13  
TABLES  
1-1  
3-1  
3-2  
3-3  
3-4  
5-1  
6-1  
6-2  
A-1  
A-2  
Customer Support Telephone Numbers.......................................................................1-5  
80x186EB/EC Evaluation Board Jumper Settings........................................................3-1  
Logical Memory Map....................................................................................................3-3  
P1 Host Serial Connector.............................................................................................3-9  
P2 Serial Channel 0 ...................................................................................................3-10  
Supported Data Types ...............................................................................................5-10  
iRISM Variables............................................................................................................6-1  
iRISM Registers ...........................................................................................................6-6  
80186 EB Board Manual Parts List ............................................................................. A-1  
80186 EC Board Manual Parts List............................................................................. A-4  
vi  
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A
1
About This Manual  
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CHAPTER 1  
ABOUT THIS MANUAL  
1
This manual describes how to set up and use the Intel 186 EB/EC Evaluation Board. The board  
is used to evaluate hardware and software performance and provide an “emulation-like” feel  
when executing and debugging user-written code. This board operates at either 3.3 volts or 5.0  
volts. It supports the following processors:  
80C186EB/80C188EB  
80L186EB/80L188EB  
80C186EC/80C188EC  
80L186EC/80L188EC.  
The 3.3 V, 16 MHz 80L186EB or 80L186EC processor is installed on the evaluation board. This  
manual covers both processors.  
1.1 CONTENT OVERVIEW  
Chapter 1, About This Manual — This chapter contains an overview of this manual.  
Chapter 2, Getting Started — This chapter describes the Intel 186 EC/EB Evaluation Board, and  
provides setup instructions.  
Chapter 3, Hardware Overview — This chapter describes the evaluation board hardware, such  
as connectors, jumpers, memory configuration, and power supply.  
Chapter 4, Introduction to the Software — This chapter provides an overview of the software  
used on the evaluation board and the host computer.  
Chapter 5, iECM-86 Commands — This chapter describes the iECM-86 software, which runs  
on the host computer.  
Chapter 6, iRISM-186 Commands — This chapter describes the iRISM-186 software, which  
runs on the evaluation board.  
Appendix A, Parts List — This chapter contains a part list for both the EB and EC versions of  
the evaluation board.  
1-1  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
1.2 NOTATION CONVENTIONS  
The following notation conventions are used in this manual.  
#
Pound symbol (#) appended to a signal name indicates that the signal is  
active low.  
italics  
Italics identify variables and indicate new terms.  
In text, identifies commands (instructions).  
bold sans-serif  
typewriter  
font  
This font is used for code examples. All characters are equal width; this is  
useful for maintaining accurate character spacing.  
UPPERCASE  
In text, signal names are shown in uppercase. When several signals share a  
common name, each signal is represented by the signal name followed by a  
number; the group is represented by the signal name followed by a variable  
(n). In code examples, signal names are shown in the case required by the  
software development tool in use.  
Designations for Hexadecimal numbers are represented by a string of hex digits followed by  
hexadecimal and the letter H. A zero prefix is added to numbers that begin with A through F.  
binary numbers (FF is shown as 0FFH.) For binary numbers, the letter B may be appended  
for clarity.  
Units of  
Measure  
mA  
milliamps, milliamperes  
amps, amperes  
kilobits, kilobytes  
kilo-ohms  
A
Kbit, Kbyte  
NOTE:  
KΩ  
Units listed are  
frequently used;  
other units and  
symbolsare used  
as necessary.  
Mbit, Mbyte  
megabits, megabytes  
kilohertz, megahertz  
milliseconds  
KHz, MHz  
ms  
µs  
ns  
µF  
W
V
microseconds  
nanoseconds  
microfarads  
watts  
volts  
1-2  
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ABOUT THIS MANUAL  
1.3 RELATED DOCUMENTS  
You can order Intel product literature from the following Intel literature centers.  
1
1-800-548-4725  
708-296-9333  
U.S. and Canada  
U.S. (from overseas)  
Europe (U.K.)  
Germany  
44(0)1793-431155  
44(0)1793-421333  
44(0)1793-421777  
81(0)120-47-88-32  
France  
Japan (fax only)  
The following documents may be useful for designing applications using this evaluation board.  
Document Name  
Intel Order #  
80C186EB/80C188EB Microprocessor User’s Manual  
80C186EC/80C188EC Microprocessor User’s Manual  
80C186EB/80C188EB and 80L186EB /80L188EB datasheet  
80C186EC/80C188EC and 80L186EC/80L188EC datasheet  
Flash Memory databook  
270830  
272047  
272433  
272434  
210830  
Application Notes  
AP484: Interfacing a Floppy Disk Drive to an 80C186EX Family Processor  
AP730: Interfacing the 82C59A-2 to Intel186 Family Processors  
272339  
272822  
272823  
AP731: Understanding the Interrupt Control Unit of the  
80C186EC/80C188EC  
ApBuilder and Hypertext  
80C186EC/80C188EC Hypertext Manual & Datasheet  
272298  
272216  
ApBuilder Interactive Programming Tool Software Package  
1-3  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
1.4 ELECTRONIC SUPPORT SYSTEMS  
Intel’s FaxBack* service provides up-to-date technical information. Intel also offers a variety of  
information on the World Wide Web. These systems are available 24 hours a day, 7 days a week,  
providing technical information whenever you need it.  
1.4.1 FaxBack Service  
FaxBack is an on-demand publishing system that sends documents to your fax machine. You can  
get product announcements, change notifications, product literature, device characteristics,  
design recommendations, and quality and reliability information.  
1-800-525-3019 (US or Canada)  
+44-1793-496646 (Europe)  
+65-256-5350 (Singapore)  
+852-2-844-4448 (Hong Kong)  
+886-2-514-0815 (Taiwan)  
+822-767-2594 (Korea)  
+61-2-975-3922 (Australia)  
1-503-264-6835 or 1-916-356-3105 (Worldwide)  
1.4.2 World Wide Web  
Intel offers a variety of information through the World Wide Web (http://www.intel.com/).  
1-4  
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ABOUT THIS MANUAL  
1.5 TECHNICAL SUPPORT  
Table 1-1. Customer Support Telephone Numbers  
Customer Support (US and Canada)  
800-628-8686  
1
Australia  
National  
Sydney  
008-257-307  
61-2-975-3300  
61-3-810-2141  
Belgium, Netherlands, and Luxembourg  
010-4071-111  
Canada  
Finland  
France  
Contact local distributor  
358-0-544-644  
33-1-30-57-72-22  
Germany  
Hardware: 49-89-903-8529  
Software: 49-89-903-2025  
Israel  
Italy  
972-3-548-3232  
39-02-89200950  
0120-1-80387  
46-8-7340100  
Japan  
Sweden  
1-5  
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2
Getting Started  
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GETTING STARTED  
This chapter describes the Intel 186 EC/EB Evaluation Board kit, and provides setup instructions.  
Figure 2-1 shows the 80x186 EB Evaluation Board layout, and Figure 2-2 shows the EC board  
layout. Refer to these figures when you are following the instructions in this chapter for setting  
up your evaluation board.  
2
C32  
+5V GND  
5V/3V Select  
C22 R9  
C33  
P1  
C26  
C31  
C25  
R10  
C20  
C21  
U11  
U7  
R11  
C28  
R3  
C27  
D2  
P2  
C9  
U14  
U12  
U6  
R6  
U4  
C24 C23  
C14  
C4  
D1  
S1  
V
V
CC  
CC  
186/188  
SELECT  
FLASH  
PWRDN  
C15  
T1OUT  
T0OUT  
GND  
P2.2  
T0IN  
T1IN  
GND  
INT0  
INT1  
INT2  
INT3  
INT4  
GND  
R4  
P2.3  
Q1  
C30  
R12  
R13  
C10  
C16  
L1  
BCLK0  
P2.6  
R8  
R1  
P2.7  
GND  
+5V  
GCS6#  
GCS7#  
C17  
C18  
+12V  
C19  
Y1  
U1  
C1  
A5289-01  
Figure 2-1. Intel 186 EB Evaluation Board Layout  
2-1  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
C32  
+5V GND  
5V/3V Select  
C21 R11  
C30  
C33  
P1  
C31  
C24  
U11 R12  
R13  
C20  
C22  
U6  
C26  
C25  
P2  
C4  
L1  
C5  
U5  
U3  
U14  
U12  
U8  
C9  
C28 C23  
Y1  
C13  
R8 R7  
T0IN  
T1IN  
CC  
T1OUT  
T0OUT  
U4  
D1  
V
V
CC  
INT0  
INT1  
P3.0  
P3.1  
P3.2  
P3.3  
P3.4  
P3.5  
WDTOUT#  
GND  
BCLK0  
P2.3  
U9  
R9  
R4  
Q1  
186/188  
SELECT  
FLASH  
PWRDN  
INT2  
INT3  
INT4  
INT5  
C7  
R5  
R6  
S1  
INT6  
C17  
R10  
INT7  
U10  
INTA#  
GND  
DRQ0  
DRQ1  
DRQ2  
DRQ3  
GND  
GCS6#  
GCS7#  
RXD1  
TXD1  
P2.6  
CTS1#  
GND  
C18  
U1  
C1  
C14  
+5V  
+12V  
A5288-01  
Figure 2-2. Intel 186 EC Evaluation Board Layout  
2-2  
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GETTING STARTED  
2.1 SYSTEM REQUIREMENTS  
IBM* PC AT, XT or BIOS-compatible computer host system (interfaces via COM1 or  
COM2 at 9600 baud).  
5 V power supply (the connector housing and contact pins are included in the kit).  
2.2 WHAT’S IN YOUR KIT  
2
Evaluation Board  
Your kit includes a board with either a 3.3 volt, 16 MHz  
80L186EB or 80L186EC microprocessor installed. Separately  
packaged components included with the board are 5 VDC ver-  
sions of the microprocessor and SRAM for conversion to a  
5 VDC evaluation platform.  
Monitor Program  
The Embedded Controller Monitor (ECM) program supports  
basic software and hardware evaluation and basic debug facilities  
(LOAD, GO, STEP, etc.) on the evaluation board. The ECM con-  
sists of two programs: RISM-186 executes in the evaluation board  
and ECM-86 executes in an IBM PC or BIOS-compatible com-  
puter, called the host PC. These two programs communicate  
through an asynchronous serial channel using a binary protocol  
defined specifically for this application.  
The source code for the monitor software is provided on a diskette  
included in your kit; this allows you to update the software for  
various operating conditions in your target application.  
Contents on Disk  
In addition to Flash downloading software, a diskette provided in  
the kit contains schematics, a pld file for the programmable logic  
device used on the board, and a sample assembly file for working  
the with LCD display. Compiler software is not included in the  
kit.  
Software Development  
Kit  
The kit provides a software development kit, which includes a  
software debugger, locator, and sample code.  
Flash Loading  
Utility  
Users can download application programs to the on-board Flash  
memory for execution. The Flash loading utility is contained on a  
diskette, and a separate manual, the CQI Flash Loader User’s  
Manual, provides instructions for using this utility.  
Serial Cable  
A serial cable is provided to connect the evaluation board to the  
host PC.  
2-3  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
2.3 VIEWING THE BOARD SCHEMATICS  
The schematics provided on the diskette are in the Adobe* Acrobat .pdf format. You can view  
and print the schematics using the Acrobat Reader. The Reader is available at no charge from the  
(http://www.adobe.com/).  
2.4 SETTING UP THE EVALUATION BOARD AND THE HOST PC  
This section tells you how to set up the board for use with a host PC. This section assumes you  
won’t be using some of the advanced features of the board when you first power it up. For  
additional options, such as selecting 80188 evaluation mode, refer to Chapter 3, “Hardware  
Overview.”  
1. Make sure you are in a static-free environment before removing any components from  
their anti-static packaging. The evaluation board is susceptible to electro-static discharge  
damage; such damage may cause product failure or unpredictable operation.  
2. Inspect the contents of your kit. Make sure that all items are included. Check for damage  
that may have occurred during shipment. Contact your sales representative if any items are  
missing or damaged.  
CAUTION: Many of the connectors on the evaluation board provide power through non-  
standard pins. Connecting the wrong cable or reversing the cable can damage the  
evaluation board and may damage the device being connected. Use extreme  
caution when preparing to connect cables to this product.  
3. Connect the power supply. The Intel 186 EC/EB Evaluation Board operates from a  
5 VDC ± 10% power supply plugged into the J2 power connector (see Figures 2-1  
and 2-2). This 5 volt signal is stepped down to 3.3 volts on the board. The connector  
housing and contact pins provided in your kit match the power supply to the J2 connector.  
To select 5 V, place a jumper on pins B and C of jumper E1. To select 3 V, place a jumper  
on pins A and B of jumper E1. See Figures 2-1 and 2-2 for jumper locations.  
All devices on the board operate at both 3.3 volts and 5.0 volts (except the LCD display,  
which is hardwired to 5 volts). This option allows comparison of current consumption  
when running code at either voltage. Separately packaged 5 V versions of the 80C186  
processor and SRAM must be installed on the board for 5 V operation.  
2-4  
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GETTING STARTED  
4. Apply power to the host PC and the evaluation board.  
When power is applied to the board, the message “i186 Ex 3V/5V EV” should appear  
across the LCD display. This message indicates board initialization is complete. If the  
message does not appear, press the reset button (S1).  
Connect one end of the standard 9-pin AT-type serial connector to header P1 on the  
evaluation board. Connect the other end to the COM1 port of the host computer. (You can  
use COM2 if you need to, but you’ll have to specify COM2 when you run the Monitor  
Software.) The PC and board communicate at 9600 baud.  
2
After connection to the PC, the processor may appear to be held in the reset state. The  
reason this occurs is that one of the host signals is used to reset the board. This signal may  
be active prior to invoking the ECM86 host software on the PC. The PC and board  
communicate at 9600 baud.  
5. Insert the ECM-86 floppy disk provided with your kit in the floppy drive on the host PC.  
You can run the ECM86 program directly from the diskette or copy the contents of the  
diskette to your hard drive.  
6. At the DOS prompt, change to the floppy disk drive (or to the directory to which you  
copied the files in the previous step) and enter this command:  
ECM86  
After a moment, the PC should display the ECM86 monitor screen.  
Complete information on using the monitor software is located in Chapters 4 and 5.  
2-5  
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3
Hardware Overview  
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HARDWARE OVERVIEW  
CHAPTER 3  
HARDWARE OVERVIEW  
The evaluation board comes with a 16 MHz 80L186 EB or EC processor, 512 Kbytes of Flash  
(containing the iRISM-186 monitor and a Flash loader utility in the boot block), and 256 Kbytes  
of SRAM. The expansion connector (JP1) supports up to 1 Mbyte of external memory and  
64 Kbytes of external I/O. Refer to Figures 2-1 and 2-2 for the exact locations of connectors,  
jumpers and headers listed in this chapter.  
3
The board utilizes the high peripheral integration of the 186 product family. The programmable  
chip-selects support on-board memory, expansion memory, and the LCD interface. The  
timer/counter unit controls timing for LCD display accesses. The serial control unit communi-  
cates with the host PC through the iECM-86 software and the Flash loader host software. Finally,  
the I/O port unit controls on-board power management functions (enable/disable serial drivers  
and +12 volts).  
Other on-chip peripherals are made available for hardware expansion via the JP1, JP2, and P2  
connectors. The following sections describe in detail the specific devices used on the board.  
3.1 JUMPER SUMMARY  
Table 3-1. 80x186EB/EC Evaluation Board Jumper Settings  
Jumper  
Name  
Description  
Options  
E1  
5 V/3 V Select  
Selects voltage (5 V or 3.3 V) that  
will be present on VCC power plane.  
A-B = 3.3 V†  
B-C = 5 V  
E2  
LA19/WRT PROT Selects options for Flash WP# pin.  
Includes option to make LA19  
available to Flash pin 2 for upgrading  
to 8-MBIT component  
A-B = Write protect boot block†  
B-C = Unlock boot block  
B-D = Add LA19 for 8- MBIT  
Flash  
(PA28F800BV).  
E3  
E4  
V
PP Select  
Selects 5 V or 12 V programming  
voltage, as well as GND to remove  
all program and erase capabilities.  
A-B = Total WRT protect†  
B-C = 12 V program voltage  
B-D = 5 V program voltage  
Flash Powerdown Selects options for Flash RP# pin.  
A-B = Normal†  
For normal operation, SW-RES# is  
selected. To unlock boot block  
(regardless of WP#), 12 V is  
selected.  
Select  
B-C = Program boot block  
override  
E5  
186/188 Select  
Jumper for appropriate processor  
type.  
A-B = 188 processor installed  
B-C = 186 processor installed†  
Default setting  
3-1  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
3.2 MICROPROCESSOR  
The core of the evaluation board is the 80x186 microprocessor. This processor operates at  
3.3 volts up to 16 MHz in this board. Alternatively, the board can be configured to run at 5 volts  
up to 33 MHz. To vary the CPU clock speed, an appropriate frequency value oscillator must be  
installed at location U3 on the EC board and at location U5 on the EB board. The oscillator  
operates at twice the frequency of the installed processor.  
The 80x186 processor offers the following features:  
16-bit data bus  
1 Mbyte address space  
2 on-chip UARTs  
10 programmable chip-selects  
Interrupt control unit  
3 programmable timer/counters  
Power management unit  
32-bit watchdog timer (EC only)  
4 DMA channels (EC only)  
The 8-bit bus version of the processor (80C188/80L188) may also be used in this board. To  
configure the board to operate with an 8-bit bus, jumper E5 must be in the A–B position. To  
configure the board to operate with a 16-bit bus, jumper E5 must be in the B–C position. Many  
of the processor’s on-chip peripherals can be accessed using the two expansion connectors on the  
board (JP1 and JP2).  
NOTE  
Because host communications use the on-chip serial ports, changing the  
operating frequency of the board requires the processor serial ports to be  
reconfigured. The RISM monitor source code is provided on a floppy diskette  
in your kit and is commented to indicate current register values.  
3.2.1 Packaging  
The 80x186 EC is packaged in a 100 lead PQFP and socket and the 80x186 EB is packaged in an  
84 lead PLCC package and socket. Adaptors are available from Applied Microsystems Corp.*  
and Emulation Technologies, Inc.* to allow for the connection of in-circuit emulators.  
3-2  
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HARDWARE OVERVIEW  
3.3 MEMORY CONFIGURATION  
The memory on the evaluation board can be divided into three types: Flash, SRAM, and  
expansion. Flash memory contains the Flash loader utility, located in the boot block boundary,  
and the RISM monitor program, beginning at F800:0000. Users can execute their test code from  
boot-up using the Flash loader utility. Refer to the CQI Flash Loader Reference Manual for  
instructions on programming the Flash memory. SRAM memory is used for the processor  
interrupt vector table, stack allocation, and RISM data variables, and as a possible destination for  
user-written code downloaded on the host interface. Expansion memory can be accessed through  
the expansion interface, if required.  
3
Table 3-2 shows the logical memory map and Figure 3-1 shows the physical memory map of the  
evaluation board.  
Table 3-2. Logical Memory Map  
Memory Area  
Start (H)  
Stop (H)  
Size  
SRAM  
Flash  
0000:0000  
8000:0000  
FC00:0000  
4000:0000  
0000:0400  
2000:0000  
F000:FFFF  
F000:FFFF  
8000:0000  
0000:0440  
128 Kbytes  
512 Kbytes  
16 Kbytes  
256 Kbytes  
64 bytes  
Flash Boot Block  
Expansion  
LCD (I/O)  
3-3  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
Memory Space  
IO Space  
FFFFFH  
FFFFFH  
FFFFH  
FF00H  
Peripheral  
Control Block  
Flash Loader Utility* (16 K)  
FC000H  
UCS  
Flash  
512 K  
0440H  
0400H  
LCD Control  
80000H  
Expansion  
256 K  
GCS5  
40000H  
LCS  
Unused  
LCS 20000H  
SRAM  
128 K  
00000H  
Interrupt Vector Table at 00000H to 003FFH (1 K)  
UCS — Upper Chip Select  
GCS7 — Expansion I/O  
Start: 80000H  
Stop: FFFFF (Flash 512 K)  
Start: 400H  
Stop: 500H  
• 3 Wait States  
• Zero Wait States  
• Active for Memory Bus Cycles  
• Bus Ready Not Required  
• Ignore Stop Address  
• Active for I/O Bus Cycles  
• Bus Ready Required  
LCS — Lower Chip Select  
Start: 0000H  
Stop: 40000H  
(SRAM 128 K)  
GCS2 — LCD Display I/O  
Start: 400H  
Stop: 440H  
• 2 Wait States  
• Stop Address Required  
• Active for Memory Bus Cycles  
• Bus Ready Ignored  
• 8 Wait States  
• Active for I/O Bus Cycles  
• Bus Ready Ignored  
GCS5 — Expansion Memory  
Start: 40000H  
Stop: 80000H (Expansion 256 K)  
• Zero Wait States  
• Ignore Stop Address  
• Active for Memory Bus Cycles  
• Bus Ready Required  
* As shipped, RISM is located at F800:0000 and pointed to by the Flash loader utility during boot-up.  
Figure 3-1. Physical Memory Map  
3-4  
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HARDWARE OVERVIEW  
3.3.1 Flash (Program Memory)  
Flash memory, as configured in the RISM monitor, is mapped to the upper 512 Kbytes of the  
1 Mbyte 80x186 processor address space. The board includes a single 4 Mbit, 32-pin PSOP Flash  
device at location U9 with 110 ns access time at 3.3 V and 60 ns access time at 5 V. This memory  
runs with one wait state at 5 volts/20 MHz and 3.3 volts/16 MHz.  
The device data bus can be configured to be either 8 or 16 bits wide (corresponding to the  
80x188and the 80x186 processor, respectively). Jumper E5 determines the Flash bus width.  
When E5 is in the A–B position, the bus is 8 bits wide; when E5 is in the B–C position, the bus  
is 16 bits wide. The configurable bus width allows access to all 512 Kbytes of Flash memory.  
3
If a user application requires nonvolatile memory for storage, Flash can be erased and written by  
jumpering E3 for either 5 V or 12 V programming voltage (VPP) and using the proper  
programming algorithm. The SmartVoltage* Flash device can be programmed using either  
voltage. The Flash loader utility is located in the Flash boot block (upper 16 Kbytes, FC000h to  
FFFFFh). Writes to this region are prohibited, regardless of the voltage on VPP, unless the RP#  
input is at +12 volts or jumper E2 is set to unlock the boot block. Jumper E4 controls the voltage  
on RP#. When E4 is in the B–C position, the +12 volt supply is connected to RP#. When E4 is in  
the A–B position, RP# is connected to the board reset signal.  
CAUTION: To access boot block memory, E4 must be in the B–C position and Port Pin 1.1  
must be programmed to a logic 0 (enabling +12 volts). Accessing the boot block is  
not recommended, as the Flash loader utility code could be corrupted.  
3.3.1.1  
Setting Up the Board for Flash Downloading  
You can use the Flash utility host program, FLASHLDR.EXE, provided in the kit to download  
your application program to the Flash memory. Upon reset or power-up, the Flash loader reads  
port pin to determine whether to execute a loaded program, such as RISM, or download new  
software to Flash memory.  
To set up the board for Flash downloading:  
1. Power-off the evaluation board and disconnect the serial cable from the PC.  
2. Port pin P2.6 on the secondary header (JP2) controls which programs execute at start-up.  
Connect P2.6 to the +5 volt pin with jumper wire and 10 kresistor. Figure 3-2 illustrates  
this connection.  
CAUTION: A 10 kresistor is required when jumpering from the P2.6 pin to the 5 volt pin; if  
this configuration is not used, the processor’s port control hardware could be  
damaged.  
3-5  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
V
V
CC  
CC  
T1OUT  
T0OUT  
GND  
T0IN  
T1IN  
GND  
INT0  
INT1  
INT2  
INT3  
INT4  
GND  
GCS6#  
GCS7#  
Jumper Wire  
P2.2  
P2.3  
BCLK0  
P2.6  
P2.7  
10K ohm  
GND  
+5V  
+12V  
Jumper Wire  
186 EB Connector JP2  
T0IN  
T1IN  
T1OUT  
T0OUT  
V
V
CC  
CC  
INT0  
INT1  
P3.0  
P3.1  
INT2  
P3.2  
INT3  
P3.3  
INT4  
P3.4  
INT5  
P3.5  
INT6  
WDTOUT#  
GND  
Jumper Wire  
INT7  
INTA#  
GND  
BCLK0  
P2.3  
DRQ0  
DRQ1  
DRQ2  
DRQ3  
GND  
RXD1  
TXD1  
P2.6  
CTS1#  
GND  
10K ohm  
GCS6#  
GCS7#  
+5V  
+12V  
Jumper Wire  
2  
1
186 EC Connector JP2  
A5420-01  
Figure 3-2. Jumper Assembly for Flash Downloading  
3. Reconnect the serial cable and power-up the board.  
You should notice that the text CQFLASH LOADER now displays on the LED, signaling  
that the board is ready for Flash downloading.  
When the jumper assembly is installed, the Flash target program waits for commands from the  
PC host, allowing you to use the provided Flash loader utility program to download programs to  
the Flash.  
3-6  
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HARDWARE OVERVIEW  
If this text does not display on the LED, indicating a problem with the jumper assembly, the board  
boots as if no Flash loader assembly is installed; that is, the Flash target program immediately  
starts the loaded user application program (for example, the iRISM monitor software).  
You can find complete instructions for using the Flash utility program in the CQI Flash Loader  
User Manual included in your kit.  
3.3.2 SRAM (Static Memory)  
3
SRAM occupies the lower 128 Kbytes of memory starting at location 00000H. This memory is  
used by the processor for interrupt vectors and stack allocation, by the RISM for program  
variables, and by the user for downloaded code. The board includes two 1-Mbit, 32-pin SRAMs  
with 17 ns access time at 3.3 volts. SRAMs are socketed to allow installation of 5 V SRAMs  
(17 ns access time).  
To allow insertion of both the 80x186 processor and the 80x188 processor, the memory is  
configured such that only 128 Kbytes of the SRAM is accessible, even though 256 Kbytes of  
SRAM are installed on the board.  
3.4 PROGRAMMABLE LOGIC  
All glue logic required by the evaluation board is implemented on a GAL 22LV10C-15. The PLD  
file located on the floppy diskette in your kit includes logic equations for this device. The logic  
implemented includes the following:  
Inverting the Port Pin signal controlling VPP (so VPP is disabled at reset)  
Controlling the 8-bit/16-bit configuration for the Flash device  
Decoding the Enable signal for the LCD display  
3-7  
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3.5 POWER SUPPLY  
The power supply connects to J2 on the board schematic. Pin 1 must connect to +5 volts and pin  
2 must connect to ground. The supply is then regulated to 3.3 volts by the on-board circuitry. The  
V
CC for the board is controlled by jumper E1. When E1 is in the A–B position, VCC = 3.3 volts;  
when E1 is in the B–C position, VCC = 5.0 volts. VCC is converted to +12 volts for optional Flash  
programming voltage.  
E1  
A
VCC = 3.3 volts  
VCC = 5.0 volts  
A – B  
B – C  
B
C
A2607-01  
Figure 3-3. E1 Jumper  
The LCD display controller VCC pin connects directly to the 5 volt supply, not the VCC plane,  
allowing 5 volt operation only.  
2
1
+5VDC - VCC  
Ground - VSS  
Figure 3-4. J2 Power Connector  
The Maxim* MAX750 component at U6 (EC) or U7 (EB) is a current-mode DC-DC converter.  
This device takes the 5 volt supply and steps it down to 3.3 volts. This voltage output is always  
supplied to provide VCC for the processor, memory, and logic when selected at E1.  
3-8  
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HARDWARE OVERVIEW  
The Maxim MAX734 located at U11 is also a current-mode DC-DC converter. This device steps  
up the VCC voltage to +12.0 volts. This voltage output is supplied to provide a VPP option for  
Flash memory programming. The SHDN# input (pin 1) connects to a port pin (P1.1) on the  
processor through an inverter. At reset, SHDN# is driven low to disable the +12 volt signal. The  
output remains disabled until Port Pin 1.1 is programmed to a logic 0. When SHDN# is low, the  
output (pin 8) is VCC minus a diode drop. The evaluation board uses SmartVoltage Flash. To  
prevent unintentional writes to Flash, set jumpers E2 and E3 as indicated in Table 3-1.  
3
3.6 SERIAL INTERFACE  
Connector P1 connects to your PC’s serial port. P1 interfaces pin-to-pin with a standard nine-pin  
RS-232 serial connector. Verify that the cable being used provides all signals required.  
Table 3-3. P1 Host Serial Connector  
Pin  
Nos.  
Host RS-232  
Signal Name  
Connection on  
Evaluation Board  
P1 Connector  
1 (CF)  
2 (BB)  
3 (BA)  
4 (CD)  
5 (AB)  
6 (CC)  
7 (CA)  
8 (CB)  
9 (CE)  
DCD Data Carrier Detect  
RxD Receive Data  
DTR P1-pin 4  
TxD of MAX561  
RxD of MAX561  
INIT  
TxD Transmit Data  
1
2
3
4
5
DTR Data Terminal Ready  
SG Signal Ground  
Digital Ground  
DTR P1-pin4  
CTS P1-pin8  
RTS P1-pin7  
Run Indicator  
6
9
7
8
DSR Data Set Ready  
RTS Request To Send  
CTS Clear To Send  
RI Ring Indicator  
Connector P2 is an additional serial port for user applications. Receive, Transmit, and Clear-to-  
Send are connected. Other connector pins are routed to test points on the board.  
3-9  
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Table 3-4. P2 Serial Channel 0  
Pin  
Nos.  
Host RS-232  
Signal Name  
Connection on  
Evaluation Board  
P2 Connector  
1 (CF)  
2 (BB)  
3 (BA)  
DCD Data Carrier Detect  
RxD Receive Data  
Test Point 1  
RxD  
TxD Transmit Data  
TxD  
4 (CD) DTR Data Terminal Ready Test Point 4  
1
2
3
4
5
5 (AB)  
6 (AB)  
SG Signal Ground  
Digital Ground  
Test Point 2  
Test Point 3  
CTS  
DSR Data Set Ready  
6
9
7
8
7 (CD) RTS Request To Send  
8 (BA)  
9 (BB)  
CTS Clear To Send  
RI Ring Indicator  
Test Point 5  
The two serial connectors are connected to the Maxim MAX561, an EIA/TIA-562  
Driver/Receiver. This device operates from a 3.3 volt VCC (or 5 volts, optionally). The EIA/TIA-  
562 standard is a low voltage serial communications protocol. This protocol operates at ±3.7  
volts. The 3.3 volt signals from the board are charge-pumped to ±6.6 volt levels internally,  
conforming to this standard. Signals from the serial connectors, P1 and P2, are translated to a 3.3  
volt level. Output from this device is recognized by EIA/TIA-232-D receivers, and inputs can  
handle EIA/TIA-232-D levels without damaging the device. The MAX561 SHDN pin (pin 25)  
connects to port pin 1.0 on the 80x186 processor. When this pin is programmed to a logic 1, the  
Maxim device will go into shutdown mode, reducing current consumption to leakage. During  
initialization, port pin 1.0 is programmed to a logic 0 to enable communication with the host PC.  
Serial communications on the evaluation board are controlled by the 80x186 processor on-chip  
serial ports. Serial Port 0 on the microprocessor handles PC communications via connector P1.  
Serial Port 1 is available for user applications via connector P2. The 80x186 processor supports  
synchronous serial communications as well as various modes of asynchronous communications.  
The time base for the host interface is a 6.0 MHz oscillator connected to BCLK0, the external  
serial clock input on the 80x186 processor. This allows the user to change the processor operating  
frequency without altering the baud rate.  
NOTE  
The BCLK0 input must be less than half the processor operating frequency  
(which is half the clock input frequency). Operating the processor below  
12.288 MHz requires reprogramming the serial control unit on the 80x186  
processor. The source code for the RISM monitor is provided on a floppy  
diskette included in your kit for this purpose.  
Figure 3-5 on page 3-11 illustrates the adaptor cable needed if your PC has a 25-pin serial port  
connector.  
3-10  
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HARDWARE OVERVIEW  
To Host PC  
Shield Ground  
1
14  
2
TXD  
RXD  
RTS  
CTS  
DSR  
15  
3
16  
4
3
17  
5
To Evaluation Board  
18  
6
1
6
2
7
3
8
4
9
5
DCD  
DSR  
RXD  
RTS  
TXD  
CTS  
DTR  
RI  
19  
7
GND  
DTR  
DCD  
20  
8
21  
9
GND  
RI  
22  
10  
23  
11  
24  
12  
25  
13  
P1  
Note:  
Signal mnemonics are referenced to the host.  
A2343-02  
Figure 3-5. 25-Pin to 9-Pin Adaptor  
3-11  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
3.7 EXPANSION INTERFACE  
There are two expansion connectors on the evaluation board. Refer to the schematics included on  
a floppy diskette in your kit for representation of the connector pinouts. The 60-pin JP1 connector  
(Figure 3-7) provides latched address pins and the address/data bus signals. This connector also  
provides access to all bus-control signals, programmable chip-selects, +3.3 volts, +5 volts, and  
+12 volts. The JP2 connector provides access to on-chip peripherals of the 80x186 processor.  
This connector allows access to interrupt inputs, timer inputs and outputs, port pins, CLKOUT,  
RESOUT, +3.3 volts, +5 volts, and +12 volts. The JP2 connector contains 40 pins for the EC  
processors (see Figure 3-6) and 24 pins for the EB processors (see Figure 3-7).  
NOTE  
3.3 volts is available on the connector only when jumper E1 selects VCC = 3.3  
volts; otherwise, these pins are 5 volts. +12 volts is available on the connector  
only when Port Pin 1.1 is programmed to a logic 0; otherwise, these pins are  
V
CC minus a diode drop.  
V
.............................. 1  
2 - T1OUT  
4 - T0OUT  
SS  
T1IN............................. 3  
.............................. 5  
V
6 - V  
CC  
CC  
INT0............................. 7  
INT1............................. 9  
INT2............................. 11  
INT3............................. 13  
INT4............................. 15  
INT5............................. 17  
INT6............................. 19  
INT7............................. 21  
INTA#........................... 23  
8 - P3.0  
10 - P3.1  
12 - P3.2  
14 - P3.3  
16 - P3.4  
18 - P3.5  
20 - WDTOUT#  
22 - V  
SS  
24 - BCLK0  
26 - P2.3  
V
............................... 25  
SS  
DRQ0........................... 27  
DRQ1........................... 29  
DRQ2........................... 31  
DRQ3........................... 33  
28 - RXD1  
30 - TXD1  
32 - P2.6  
34 - CTS1#  
V
............................... 35  
36 - V  
SS  
SS  
GCS6#.......................... 37  
GCS7#.......................... 39  
38 - +5VDC  
40 - +12VDC  
Figure 3-6. 186 EC Peripheral Expansion Connector JP2 (40 pin)  
3-12  
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HARDWARE OVERVIEW  
V
............  
1
3
5
7
9
2 - V  
CC  
CC  
T1OUT.......  
T0OUT.......  
4 - T0IN  
6 - T1IN  
V
.............  
8 - V  
SS  
SS  
P2.2............  
10 - INT0  
12 - INT1  
14 - INT2  
16 - INT3  
18 - INT4  
P2.3............ 11  
BCLK0........ 13  
P2.6............ 15  
P2.7............ 17  
3
V
............. 19  
20 - V  
SS  
SS  
+5V............. 21  
+12V........... 23  
22 - GCS6#  
24 - GCS7#  
Figure 3-7. 186 EB Peripheral Expansion Connector JP2 (24 pin)  
3-13  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
JP1 Memory - I/O Expansion Connector  
2x30 Pin Molex* 39-51-6004 or Equivalent  
V
.............................. 1  
2 - V  
CC  
CC  
LA0 Output.................. 3  
LA1 Output.................. 5  
LA2 Output.................. 7  
LA3 Output.................. 9  
LA4 Output.................. 11  
LA5 Output.................. 13  
LA6 Output.................. 15  
LA7 Output.................. 17  
4 - D0 Bidirectional  
6 - D1 Bidirectional  
8 - D2 Bidirectional  
10 - D3 Bidirectional  
12 - D4 Bidirectional  
14 - D5 Bidirectional  
16 - D6 Bidirectional  
18 - D7 Bidirectional  
V
.............................. 19  
20 - V  
SS  
SS  
LA8 Output.................. 21  
LA9 Output................. 23  
LA10 Output................ 25  
LA11 Output................ 27  
LA12 Output................ 29  
LA13 Output................ 31  
LA14 Output................ 33  
LA15 Output................ 35  
22 - D8 Bidirectional  
24 - D9 Bidirectional  
26 - D10 Bidirectional  
28 - D11 Bidirectional  
30 - D12 Bidirectional  
32 - D13 Bidirectional  
34 - D14 Bidirectional  
36 - D15 Bidirectional  
V
...............................37  
38 - V  
SS  
SS  
LA16.............................39  
LA17............................ 41  
LA18........................... 43  
LA19........................... 45  
RD#............................ 47  
WR#............................ 49  
BHE#.......................... 51  
RESOUT..................... 53  
DEN#........................... 55  
DT-R#......................... 57  
40 - HLDA  
42 - HOLD  
44 - READY Input  
46 - ALE  
48 - LOCK#  
50 - NMI  
52 - GCS5#  
54 - +12 VDC  
56 - +5 VDC  
58 - CLKOUT  
V
.............................. 59  
60 - V  
SS  
SS  
Figure 3-8. CPU Bus Expansion (EB and EC)  
3-14  
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HARDWARE OVERVIEW  
3.8 LCD INTERFACE  
The evaluation board includes a 16-character by 1-line LCD display. The display has an 8-bit  
interface and is designed to operate at up to 20 MHz. The display includes a Hitachi* 44780 LCD  
display controller that takes care of functions such as character interpretation and display refresh.  
The display is write-only. This is because the display controller operates at 5 volts VCC. A 5-volt  
part driving a 3.3-volt bus can damage parts operating at 3.3 volts VCC. This means that the  
BUSY pin of the processor cannot be monitored to determine when the processor is ready for the  
next command, so a delay loop must be used to allow the display to finish commands.  
3
Signals from the 80x186 processor can be connected directly to the LCD controller inputs,  
regardless of VCC, because 3.3 volt and 5 volt outputs are compatible with 5 volt TTL level  
inputs.  
The LCD display is mapped in I/O space at 400H to 440H. All command and data writes to the  
display are to this address. Port pin 1.4 is used to control which LCD register is accessed. P1.4 = 0  
accesses the command register; P1.4 = 1 accesses the data register.  
3.8.1 LCD Interface Demo  
The diskette provided in your kit includes a file, LCD_DEMO.ASM, that contains source code  
you can assemble and load onto the board (using iECM). You can execute the program for a  
demonstration of the basic principals of operating the LCD display module. This program prints  
a static message to the display. The source code is commented to serve as a tutorial and can be  
adapted as needed for other applications and messages. Note that although the LCD module is  
capable of displaying standard ASCII (characters 32 through 125) or custom characters, this  
demo uses only ASCII characters.  
For more information regarding the operation of the display controller, please refer to the Hitachi  
LCD Controller/Driver LSI Data Book.  
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4
Introduction to the  
Software  
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CHAPTER 4  
INTRODUCTION TO THE SOFTWARE  
The Intel 186 EC/EB Evaluation Board uses an Embedded Controller Monitor (ECM) written for  
the 80x186 family of 16-bit microprocessors. This monitor supports basic debug facilities  
(LOAD, GO, STEP, etc.) in the user’s target system. The ECM is broken into two independent  
programs. One of these (iRISM-186) executes in the evaluation board and the other (iECM-86)  
executes in an IBM PC or BIOS-compatible computer. These two programs communicate via an  
asynchronous serial channel using a binary protocol defined specifically for this application.  
4
The partitioning of the ECM into two separate programs supports a number of goals:  
The system is easy to adapt to a new target because the code that runs in the target is very  
simple and small.  
The feature set of the user interface is not limited by the resources of the target, since the  
user interface is implemented in the host PC.  
Concurrent operation of the ECM and the target system is easily achieved. This allows you  
to interrogate and (carefully) modify the state of the target system while it is running.  
This chapter describes the user interface provided by the iECM-86, the interface between this PC-  
resident software and the target-resident software, and the structure of the software in the target.  
The board uses the internal 80x186 EB/EC serial port for host communications.  
The iECM-86 software was created by Intel to support users of the 80x186 architecture and is  
placed in the public domain with no restrictions or warranties of any kind.  
4.1 SOFTWARE FEATURES  
The iECM-86 software has the following features:  
Sixteen software execution breakpoints  
Concurrent interrogation of target memory and registers  
Supports BYTE, CHARACTER, WORD, STRING, DOUBLE WORD, and REAL variable  
types  
Supports LOAD, SAVE, LIST, LOG, and command INCLUDE files  
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4.2 RESTRICTIONS  
Two words of the user stack are reserved for use by the iRISM-186 software. Other memory  
and/or registers in the target memory are used by the iRISM-186 software. The exact amount and  
location of this memory is implementation-dependent.  
An asynchronous serial port capable of operation at 9600 baud must be available in the target  
system. The RISM described in this document uses the 80x186 EB/EC internal serial port.  
The TRAP instruction is reserved.  
Breakpoints and program stepping will not operate if the user’s code is in Flash or other  
nonchangeable memory.  
4.3 EMBEDDED CONTROLLER MONITOR (ECM)  
An ECM (Embedded Controller Monitor) is installed in your target system to provide basic debug  
capability. Capabilities include loading object files into system RAM, examining and modifying  
variables, executing code, and stepping through code. A personal computer acts as the host for  
program translation and emulates a video display during user interaction with the ECM. The  
ECM developed for the 80x186 family makes the assumption that the user interface is a personal  
computer; no provision is made for interface to a CRT terminal. By making this assumption, it is  
possible to reduce the size and complexity of the code that must be installed in the target system.  
The term coined for this target-resident code is Reduced Instruction Set Monitor (RISM).  
The RISM consists of about 2200 bytes of 80x186 code that provides primitive operations.  
Software running in the host uses the RISM commands to provide a complete user interface to  
the target system. The advantage of this approach is that the ECM can be readily adapted to  
different target systems and requires only a small part of the available target memory space. The  
disadvantage is that the user interface must be provided by a personal computer.  
RISM is structured as a short section of initialization code and an interrupt service routine (ISR).  
The ISR processes interrupts from the host system. The RISM ISR consists of a short prologue  
and a case-jump to one of 20 to 25 command executors. These executors are simple and short;  
the flow though the entire ISR (including the prologue) is 15-20 instructions. The serial commu-  
nication occurs at 9600 baud, which limits the frequency of these interrupts to 1 KHz. In the worst  
case, the board will be slowed by the execution of a fairly short RISM ISR every millisecond  
while executing user code. It is possible to operate the board so that no real time is lost to the  
iECM-86 unless the user is actively interrogating the target. See “Initiating and Terminating  
iECM-86” on page 4-3 and the description of the RISM REPORT_STATUS code (Code 14H)  
on page 6-5 for details.  
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INTRODUCTION TO THE SOFTWARE  
4.4 USER INTERFACE  
The user interface to the iECM-86 supports commands to initiate and configure the ECM-86,  
perform I/O operations involving DOS files, execute user programs, and interrogate variables in  
the target system. Interrogation can be done in a number of formats and in most cases can be done  
concurrently with user code execution.  
4.4.1 Numeric Input  
The command parser used by the iECM-86 software requires that numeric inputs always start  
with the digits 0-9. Hexadecimal numbers that start with A–F must be preceded by a zero. For  
example, enter “0AA55” instead of “AA55.” This requirement is similar to that of ASM86.  
4
4.4.2 Controlling Lengthy Commands  
Most of the commands supported by iECM-86 appear to complete without delay. Some  
commands (for example, displaying or filling a large area of memory) take an appreciable length  
of time to complete. In general, these commands can be aborted by pressing Enter. Those  
commands that display a large amount of information can be paused by pressing the spacebar.  
After you have checked the data on the screen, you can press the spacebar again to resume the  
output.  
4.4.3 Aborting from iECM-86  
Press Ctrl+C to close any open files and return to DOS.  
4.5 INITIATING AND TERMINATING iECM-86  
This section describes the commands for invoking iECM-86 from DOS and exiting back to DOS.  
4.5.1 ECM86  
This command, entered at the DOS prompt, loads the iECM-86 software and executes it. Several  
options are available with this command. Option strings always start with a hyphen (-) and can  
be entered in upper or lower case. The operation of these options is described below. Any or all  
of these options can be entered in any order. If the options are contradictory, the actual option  
accepted is the last one entered.  
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4.5.2 -COM2, -COM1  
These options tell the iECM-86 software which serial communication port is to be used. If neither  
option is entered, COM1 is used as a default. If iECM-86 detects valid CTS (Clear to Send) and  
DSR (Data Set Ready) signals from the appropriate COM port, it signs on and displays a  
command prompt. When the target is stopped, the command prompt is an asterisk (*). When the  
target is already running, the prompt is a greater-than sign (>).  
4.5.3 -DIAG  
If CTS and DSR are not present, iECM-86 displays a warning message. You can choose to  
proceed or exit. It is possible, but not likely, that iECM-86 will operate properly even after the  
warning. It is more likely that there is a problem with the serial port or the cabling that prevents  
proper operation.  
If the problem is not obvious, such as a disconnected cable or no power to the target hardware,  
use the -DIAG invocation option to help isolate the problem. The -DIAG option puts the iECM-  
86 system in a special mode that allows many tests to be used to find interfacing problems or  
target bugs.  
The diagnostic mode is intended to support debugging of boards that use iECM-86 software. It  
also provides a simple routine to check the communications interface between the host and the  
target.  
In the board, a serial port loop-back mode allows debugging the host/board interface. Upon reset,  
the board is in the echo mode. Until it receives an ASCII slash (/) or backslash (\), it increments  
every character it receives from the host and sends the incremented value back to the host. The  
LCD displays the word “DIAGNOSTICS” when the board is in echo mode. If a backslash is  
received by the RISM, the board leaves echo mode and starts normal operation. When a slash is  
received, the board stops echoing incremented received data and starts responding to RISM  
commands with the diagnostic flag set.  
NOTE  
The target hardware has to be reset before using the -DIAG option. When  
executing diagnostic routines from Flash, certain commands such as  
breakpoints and stepping will not work because they need to modify the code  
to work properly.  
When the host software is invoked in the diagnostic mode, it prompts you to enter characters on  
the keyboard. These characters are sent to the target, and the response from the target is displayed  
on screen. This is a simple confidence check on the serial communication channel. You are told  
to enter a slash or backslash to terminate this mode and proceed in either the diagnostic mode or  
the normal user’s mode. If the user interface is invoked without the -DIAG option, the software  
immediately transmits a reverse-slash, which should put the target in the normal mode.  
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INTRODUCTION TO THE SOFTWARE  
4.5.4 -POLL, -SIGNAL  
These two options control how the host software detects whether or not the user’s code is running.  
If poll mode is selected, the host periodically polls the target with a REPORT_STATUS  
command. This takes no additional hardware, but it forces the target to spend instruction cycles  
responding to the poll. The signal mode avoids this overhead, but it requires that the target set the  
Ring Indicator modem line before it issues a REPORT_STATUS command. If neither option is  
selected, the signal mode is selected as a default. On the board, the P1.3 pin of 80x186 processor  
is used to generate this running signal. Therefore, the signal mode is recommended. (The  
REPORT_STATUS command is described on page 6-5.)  
4
4.5.5 RESET SYSTEM, RES SYSTEM, RESET, RES  
This command and its abbreviations reset the entire target hardware system. This command  
operates by dropping the DTR modem control line. This comes into the target as DSR. After  
dropping DTR, the iECM-86 software waits about 1 second to allow the target to complete its  
initialization routines. The iECM-86 warns of this time delay and then ignores input from the host  
PC until it expires. Unless special precautions are taken in the design of a target system, any data  
in RAM (including downloaded object code) may be corrupted by the reset. On the board, the  
RAM contents should not be affected by a reset.  
4.5.6 DOS  
This command enables you to temporarily leave iECM-86 and return to DOS. Once you have  
suspended iECM-86, you may perform other functions in DOS, including using other software  
programs such as ASM86, as long as there is sufficient memory to do so.  
To re-enter iECM-86, type exit at the DOS prompt. iECM-86 returns with all conditions that were  
in effect at the time it was suspended.  
4.5.7 QUIT  
This command closes any files that iECM-86 has opened and exits to DOS. Note that this  
command can be used even if the target is running. iECM-86 sets the selected COM port to 9600  
baud, 8 bits, no parity and one stop bit. The port is left in this state by iECM-86 when control is  
returned to DOS.  
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4.6 RELATED INFORMATION  
All unreserved functions of the processor are available to you, except the Non-Maskable Interrupt  
(NMI), the Breakpoint instruction (INT 3), the Trap Flag (TF), 16 Kbytes of address space, and  
128 bytes of I/O space.  
4.6.1 Reserved Functions  
The Trap Flag and its vector in memory locations 4H–7H are reserved for use by the SSTEP  
command and BREAKPOINTS.  
The NMI pin and its vector in memory locations 8H–0BH are reserved for use by the host  
interface.  
The INT 3 instruction and its vector in memory locations 0CH–0FH are reserved for use by the  
SSTEP command and BREAKPOINTS.  
4.6.2 Reserved Memory  
On-board Flash memory, as shipped, is 32 Kbytes from address 0H to 7FFFH.  
Addresses 0H–3FFH are the interrupt vectors for the processor.  
You must not alter the interrupt vectors from 4H–0FH.  
Memory locations 400H–415H are reserved for use by the RISM monitor code. You must ensure  
that no locations in this partition are used by code that is to operate with the RISM. The easiest  
way of doing this is to generate an ASM-86 module that declares a DATA SEGMENT at 400H  
that is 22 bytes long. This module can then be linked into the final program to prevent the linker  
from assigning these registers to another module.  
Fourteen words of user stack space must be reserved for use by the iRISM-186 software while  
the board is processing a host interrupt. The CS:SP register pair is initialized by RISM to  
0000H:0800H, providing a total stack size of 501 words before RISM data variables are  
overwritten. If this is insufficient for your application, your code should alter the SP to a large  
enough value. Normally, you should write your code to begin at address 800H and download it  
to Flash memory using iECM-86. You should use any space left beneath your code as data  
memory.  
4.6.3 Reserved I/O  
The I/O space from 400H–47FH is reserved for use by the host interface.  
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5
iECM-86 Commands  
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CHAPTER 5  
iECM-86 COMMANDS  
This chapter defines the iECM-86 software commands.  
5.1 ENTERING COMMANDS  
The syntax for iECM commands is shown below:  
COMMAND metasymbol  
iECM-86 command definitions use one or more of the following metasymbols:  
5
addr  
address  
iECM-86 is able to interpret the microprocessor’s address space as  
either a flat 20-bit array or through segmentation. A location  
anywhere within the 1 Mbyte memory range may be specified by its  
complete physical address, such as 0F1AC9H.  
segment:offset  
Memory may also be accessed by segments. Valid segment  
references are the following (where segment and offset are valid  
integers):  
CS:offset  
DS:offset  
ES:offset  
SS:offset  
When using CS, DS, ES or SS, the full address is calculated using the  
actual value of the appropriate target processor segment register.  
In addition to the above registers, iECM-86 maintains four user-  
definable registers that may be used for segment variables:  
CB:offset  
DB:offset  
EB:offset  
SB:offset  
This facility is useful when reading from assembler listings, which  
are typically offset from 0000. These base registers are used, for  
example, as a base pointer to a block of memory for debug purposes.  
CB could be loaded with the base address of a code module, then  
breakpoints could be set using offsets from that base. Using these  
internal iECM registers has no effect on the values of the target  
processor's registers.  
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bp_number  
code_addr  
Sixteen breakpoints are available to the user. This number selects  
which breakpoint to access.  
The code address may be specified by either segment: offset,  
CS:offset, or CB:offset.  
count  
This denotes the number of times a command executes.  
filename  
This is the location (path) and name of the file you want to reference  
(e.g., \progdir\program.obj).  
value  
Data to be entered in the current base notation.  
5.2 FILE OPERATIONS  
iECM-86 uses files in the host system to load and save object code, to enter predefined strings of  
commands, to keep a log of commands that are entered by the user, and to keep a record of an  
entire debug session that includes both the characters entered by the user and the responses  
generated by iECM-86 on the host screen. The commands that operate with files are described in  
the following sections.  
5.2.1 Loading and Saving Object Code  
iECM-86 accepts object files that are generated by Intel’s development tools. iECM-86 will not  
accept files that contain unresolved externals or files that contain re-locatable records. These files  
must be passed through LINK86 and/or LOC86 to resolve the externals and/or absolutely locate  
the re-locatable segments. iECM-86 will also not accept HEX format files. The iECM-86  
commands that operate on object files are the following:  
LOAD filename  
SAVE addr TO addr IN filename  
The metasymbol filename means that a valid MS-DOS file name must be entered in that position  
of the command string.  
LOAD filename  
This command loads the content records of the object  
file filename into the target memory.  
SAVE addr TO addr IN filename  
This command saves a region of memory as an object  
file that can be reloaded into the target memory at  
some later time.  
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iECM-86 COMMANDS  
5.2.2 Other File Operations  
In addition to object files, the iECM-86 makes use of include files, log files, and list files. Include  
files contain commands to be executed by iECM-86. They must contain the exact sequence of  
ASCII characters that you would enter from the keyboard to execute the command. Include files  
can be tedious to create with a text editor, so iECM-86 can generate log files that store characters  
entered by the user. These log files may be used later as include files to recreate command  
sequences. List files keep a running record of commands entered by the user and the responses  
generated by iECM-86. Comments can be included in list and log files to make them easier to  
understand. A comment starts with a semicolon (;) and ends with a carriage return or ESC. The  
semicolon is considered part of the comment, but the carriage return or ESC is not. The command  
parser ignores comments but puts them in the list and log files.  
The list and log file commands allow for default file names and allow either overwriting existing  
data in the file or appending data at the end of the file. This allows you to gather list and log data  
in the default files, which avoids creating and managing a large number of separate files. Log and  
list files are stamped with the date and time whenever they are opened to facilitate using this  
capability, then going back to sort out the data from several debug sessions with a text editor.  
5
The following commands are used in include, log, and list operations.  
INCLUDE filename  
PAUSE  
LIST  
LIST filename  
LOG  
LOG filename  
LISTOFF  
LISTON  
LOGOFF  
LOGON  
Three of these commands require you to supply a valid file name; the rest use the appropriate file  
name that has already been entered.  
INCLUDE filename  
This command attempts to open filename as a read-only file. If the  
file can be opened, the command parser takes commands from that  
file until the end of the file is reached. The INCLUDE file is then  
closed. Only one INCLUDE file is opened at a time.  
PAUSE  
This command is documented in this section because it is intended to  
be used as part of INCLUDE files. It is not really a file-oriented  
command itself. When this command is entered, the iECM-86 stops  
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parsing commands until a space character is entered from the  
keyboard (the space character can’t come from an INCLUDE file).  
This allows the user to pause in the middle of an INCLUDE file  
operation to see what is occurring and then acknowledge the pause  
condition by pressing the space bar.  
LIST  
This command behaves like the LIST filename command described  
below, except that it uses the last file name that was entered as part of  
a LIST filename command. If no such command has been entered,  
the default filename LIST.ECM is used.  
LIST filename  
This command attempts to open filename as a writable file. If  
filename already exists, then iECM-86 asks if the file is to be  
overwritten or if the new data should be appended to the existing file.  
It then opens the file and stamps it with the current date and time  
from the system clock. Subsequent commands entered by the user  
and the responses generated by iECM-86 are recorded in the file.  
LOG  
This command behaves like the LOG filename command described  
below, except that it uses the last file name that was entered as part of  
a LOG filename command. If no such command has been entered,  
the default file name LOG.ECM is used.  
LOG filename  
This command attempts to open filename as a writable file. If  
filename already exists, iECM-86 asks if the file is to be overwritten  
or if the new data should be appended to the file. It then opens the  
file and stamps it with the current date and time. Subsequent  
commands entered by the user are recorded in the file. Note that this  
file may contain nonprintable characters (e.g., ESC).  
LISTOFF  
LISTON  
The LISTOFF command closes a list file that has been specified by  
the LIST command. This stops new list information from being  
recorded. The LISTON command reopens the list file in the append  
mode so that recording can start again. LISTON also stamps the list  
file with the current date and time from the system clock.  
LOGOFF  
LOGON  
The LOGOFF command closes a log file that has been specified by  
the LOG command. This stops new log information from being  
recorded. The LOGON command reopens the log file in the append  
mode so that recording can start again. LOGON also stamps the list  
file with the current date and time from the system clock.  
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iECM-86 COMMANDS  
5.3  
PROGRAM CONTROL  
Commands that control program execution allow you to reset the processor, set execution break-  
points, start execution, stop execution, step, and super step. The commands are grouped by their  
major functions for the sake of discussion.  
5.3.1 Resetting the Target  
The processor can be reset by executing the following iECM-86 command:  
RESET CHIP  
RES CHIP  
This command physically resets the processor by setting the RISM_DATA register to  
0XXXX0001 and issuing a MONITOR_ESC RISM command, which causes the target to  
perform a JMP FFFF:0000H instruction.  
5
RESET SYSTEM  
RES SYSTEM  
RES  
This command resets the entire iECM-86 system, including the target. It operates by bringing the  
DCD line of the serial port low. This, with appropriate circuitry in the target system, resets the  
target processor. During this process, the iECM-86 software must wait about one second to allow  
the main board to complete its initialization routines. The iECM-86 warns of this time delay and  
then ignores the user until it expires. Any user code in the Flash must be reloaded after this  
command.  
5.3.2 Breakpoints  
iECM-86 provides sixteen program execution breakpoints. If a given breakpoint is inactive, it is  
set to zero; if it is active, it is set to the address of the first byte of an instruction. Breakpoints set  
to addresses that are not the first byte of an instruction cause unpredictable errors in the execution  
of the users code. When execution is started, iECM-86 saves the user code byte at any active  
breakpoint and substitutes an INT3 instruction for that byte. Executing an INT3 instruction  
causes the iECM-86 to restore the user code bytes where the INT instructions were substituted  
and then decrement the users program counter so that it points to the original instruction. The  
users program appears to stop execution immediately before executing the instruction with a  
breakpoint set on it. All INT instructions are removed from the users code and the original code  
is restored.  
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NOTE  
Most monitor programs similar to iECM-86 display a message on the console  
when a break occurs (e.g., “Program break at 1234H”). This is not done in  
iECM-86 because the system supports concurrent interrogation of the target on  
which the user's code is running; it is possible that the break will occur while  
you are in the middle of displaying or modifying the state of the target. Any  
special break message would have to interrupt the execution of the command.  
Because of this, the iECM-86 does not output a special break message. You  
have two ways to find out that a break occurred:  
The prompt changes from a greater-than sign (>) to an asterisk (*).  
The status of the processor shown in the “control panel” at the top of the console screen  
changes from “running” to “stopped.”  
Commands which set the breakpoint array are:  
BR  
BR [ bp_number ]  
BR [ bp_number ] = code_addr  
The square brackets in the latter two commands are part of the command syntax and must be  
entered by the user; the angle brackets are part of the “meta” language used to describe the syntax.  
Breakpoints can be displayed while your code is running, but they cannot be modified.  
NOTE  
BR[0] and BR[1] can also be set by the GO command by using the TILL  
clause; all breakpoints are cleared by the GO command if the FOREVER  
clause is used.  
BR  
This command displays all of the active breakpoints (i.e., those not  
set to zero). You are also informed if no breakpoints are active.  
BR [ bp_number]  
This command displays the setting of the selected breakpoint and  
waits for input from you. If you enter a carriage return, the command  
terminates. If you enter an ESC, the next sequential breakpoint is  
displayed. If you enter a numeric value, the selected breakpoint is  
loaded with the value and the iECM-86 again waits for input. At this  
point, you can enter either a carriage return or an ESC. As before, the  
ESC causes the iECM-86 to display the next breakpoint and the  
carriage return terminates the command. This command wraps  
around from the last breakpoint (15t) to the first breakpoint (0).  
BR [bp_number] = code_addr  
This command sets the specific breakpoint specified  
by bp_number to the value code_addr.  
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iECM-86 COMMANDS  
5.3.3 Program Execution  
These commands start and stop execution of user code. The commands provided are:  
GO  
GO FOREVER  
GO FROM code_addr  
GO FROM code_addr FOREVER  
GO FROM code_addr TILL code_addr  
GO FROM code_addr TILL code_addr OR code_addr  
GO TILL code_addr  
GO TILL code_addr OR code_addr  
HALT  
5
If a GO with breakpoint command is entered, the user code bytes at the breakpoints are saved and  
INT3s are substituted. When a breakpoint is reached, the users software stops before the  
instruction that caused the breakpoint and the iECM-86 software restores the original user code.  
Note that this differs from the operation of most ICE modules, which stop just after the  
instruction executes. A problem associated with stopping before the break instruction executes is  
that subsequent GO commands may run into the breakpoint before any user code is executed. The  
iECM-86 avoids this problem by skipping the setting of any breakpoints set on the instruction  
that the current PC points to. If this happens to remove the last breakpoint set, you are warned,  
but the GO still executes with no breakpoints enabled. If this happens, you can use the HALT  
command to stop the program.  
None of the GO commands can be executed while the users code is already running; the HALT  
command cannot be executed if the users code is not running. The GO commands that set  
breakpoints use BR[0] and possibly BR[1]. Any break value already in one of these breakpoints  
is overwritten and destroyed by these GO commands. If possible, the user should reserve the first  
two breakpoints for use by the GO commands, and set the remaining breakpoints (if required)  
explicitly with the BR commands.  
GO  
This command starts execution of the users code using the current  
value of users program counter (PC) and the current breakpoint  
array.  
GO FOREVER  
This command clears the breakpoint array and starts execution at the  
current value of the users PC.  
GO FROM code_addr This command loads the users PC with code_addr and starts  
execution of the users code using the current breakpoint array.  
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GO FROM code_addr FOREVER  
This command loads the users PC with code_addr, clears the  
breakpoint array, and starts execution of the users code.  
GO FROM code_addr TILL code_addr  
This command loads the users PC with the code_addr that follows  
the FROM keyword, sets the first breakpoint (BR[0]) to the  
code_addr that follows the TILL keyword, and starts execution of  
the users code.  
GO FROM code_addr TILL code_addr OR code_addr  
This command acts like the previous command, except that it also  
sets the second breakpoint (BR[1]) to the code_addr that follows the  
OR keyword.  
GO TILL code_addr  
This command sets the first breakpoint (BR[0]) to code_addr and  
starts the execution of user code using the current setting of the users  
PC and the breakpoint array.  
GO TILL code_addr OR code_addr  
This command acts like the previous command, except that it also  
sets the second breakpoint (BR[1]) to the code_addr that follows the  
OR keyword.  
HALT  
This command stops execution of user code by forcing the processor  
to execute a jump to self instruction in a reserved location.  
5.3.4 Program Stepping  
These commands allow stepping through programs one instruction at a time. Between instruc-  
tions, the iECM-86 commands can be used to check the state of the variables changed by the  
instruction, to ensure that the program is operating properly. Stepping through code allows a more  
detailed look at what is going on in the program. The price paid for this detail is that stepping does  
not occur in real time; this makes it difficult, or perhaps impossible, to use on code that is tied to  
real-time events.  
Stepping while interrupts are enabled would be confusing, since interrupt service routines would  
be stepped through as well as sequential code. iECM-86 avoids this problem by artificially  
locking out interrupts while stepping, ignoring the state of the interrupt enable (IF) or interrupt  
mask.  
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iECM-86 COMMANDS  
Super-stepping is similar to stepping, except that the super-step command treats an interrupt  
service routine or a subroutine call (and the body of the subroutine that is called) as one  
indivisible instruction. This allows the user to ignore the details of subroutines and interrupt  
service routines while evaluating code. This may allow limited stepping through code while  
operating in a concurrent environment, but the system will not operate in real time. A better  
approach is to use the GO command to execute to a specified breakpoint and then step through  
the code being tested, looking for proper operation.  
iECM-86 implements the step operation by using the trap flag (TF). To step over a given  
instruction, iECM-86 sets the trap flag to put the processor into single-step mode. In this mode,  
the CPU automatically generates an internal interrupt after each instruction, allowing a program  
to be inspected as it executes. After the processor receives this trap interrupt, it restores all of the  
user flags overwritten by the iECM flags.  
5
Super-stepping is also accomplished by setting the trap flag, except for CALL instructions, which  
are treated as a special case. During a STEP, the iECM-86 sets the trap flag; during a super-step  
an INT3 is placed at the instruction following the CALL. Interrupts are suppressed during STEP  
operations by saving the user’s IF bit, clearing it before the STEP occurs, and then restoring it.  
During a GO or SSTEP command, all instructions are executed by the target.  
The iECM-86 commands that implement step operations are the following:  
STEP  
STEP count  
STEP FROM code_addr  
STEP FROM code_addr count  
SSTEP  
SSTEP count  
SSTEP FROM code_addr  
SSTEP FROM code_addr count  
Aside from the style of the actual step operation, the SSTEP and STEP commands behave the  
same. They are called single-stepping commands are described as follows.  
{STEP | SSTEP}  
This command single-steps one time.  
{STEP | SSTEP} count This command single-steps count times.  
{STEP | SSTEP} FROM code_addr  
This command loads the user's program counter (PC) with  
code_addr and then single-steps one time.  
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{STEP | SSTEP} FROM code_addr count  
This command loads the users program counter (PC) with  
code_addr and then single-steps count times.  
5.4 DISPLAYING AND MODIFYING PROGRAM VARIABLES  
iECM-86 provides commands to display and modify program variables in several formats. In  
addition to simple variables such as bytes and words, more complicated variables such as reals  
and character strings are supported. iECM-86 commands allow variables to be displayed or  
initialized either individually or as regions of memory that contain variables of the given type.  
5.4.1 Supported Data Types  
Table 5-1. Supported Data Types  
Data Type  
Description  
BYTE  
A BYTE is an eight-bit variable. No alignment rules are enforced for BYTE  
variables.  
CHAR  
WORD  
DWORD  
STACK  
A CHAR is a special case of a BYTE. CHAR variables are displayed as  
ASCII characters.  
A WORD is a 16-bit variable. The address of a WORD is the address of its  
least significant byte.  
A DWORD is a 32-bit variable. The address of a DWORD is the address of  
its least significant byte.  
A STACK variable is a 16-bit variable that resides in the system stack. The  
address of a stack variable (stack_addr) is taken to be relative to the current  
stack pointer  
STRING  
A STRING is a sequence of ASCII characters that are terminated by the  
NUL character. The ASCII character NUL has the binary value of zero.  
PORT  
A PORT is an 8-bit I/O port. No alignment rules are enforced for PORTs.  
WPORT  
A WPORT is a 16-bit I/O port. The address of a WPORT is the address of its  
least significant byte. A WPORT must start at an even address.  
In addition to supporting access to variables of the above types, iECM-86 also provides  
commands to access the microprocessor registers and other special program variables such as PC  
(program counter), and SP (stack pointer). These commands include AX, AH, AL, BX, BH, BL,  
CX, CH, and CL.  
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iECM-86 COMMANDS  
5.4.2 BYTE Commands  
There are four forms for the BYTE commands:  
BYTE byte_address  
BYTE byte_address = byte_value  
BYTE byte_address TO byte_address  
BYTE byte_address TO byte_address = byte_value  
All of these commands can be used whether or not the users program is running.  
BYTE byte_address  
This form is used to examine and then possibly change one or more  
sequential BYTE variables. When this command is invoked, iECM-  
86 displays the byte_address in hexadecimal notation and the value  
of the BYTE in the default base, then waits for an input from you.  
You can respond with a carriage return character, an ESC character,  
or a numeric value. A carriage return terminates the command. An  
ESC results in the display of the next sequential BYTE variable. If a  
numeric value is entered, the BYTE variable is set to this value and  
the iECM-86 again waits for input. At this point, you can respond  
only with an ESC or carriage return. As before, the ESC displays the  
next sequential BYTE and the carriage return terminates the  
command.  
5
BYTE byte_address = byte_value  
This form is used to set an individual BYTE variable without first  
checking its current value. When invoked, this command sets the  
BYTE variable at byte_address to byte_value.  
BYTE byte_address TO byte_address  
This form is used to display a region of memory as a sequence of  
BYTE variables. When this command is invoked, iECM-86 starts by  
displaying the current default base and then a series of lines showing  
the contents of the selected memory region. The next line starts with  
a hexadecimal display of the address of the next BYTE variable to be  
displayed, followed by the display of up to 16 bytes of memory as  
BYTE variables in the default base. A new line start whenever 16  
bytes of memory have been displayed on the line. The command  
terminates when all of the BYTE variables in the selected range have  
been displayed. During lengthy displays, you can stop the output to  
the console by pressing the space bar. You can resume the display by  
pressing the space bar a second time. You terminate the command by  
entering a carriage return.  
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BYTE byte_address TO byte_address = byte_value  
This form is used to initialize a region of memory to the given  
byte_value. Note that this command takes a little over a millisecond  
(at 9600 baud) for each BYTE loaded. You can terminate this  
command by entering a carriage return, but terminating the command  
leaves only part of the memory region initialized.  
5.4.3 WORD Commands  
There are four basic forms for the WORD commands:  
WORD word_address  
WORD word_address = word_value  
WORD word_address TO word_address  
WORD word_address TO word_address = word_value  
All of these commands can be used whether or not the users program is running.  
WORD word_address  
This form is used to examine and then possibly change one or more  
sequential WORD variables. When this command is invoked, iECM-  
86 displays the word_address in hexadecimal notation and the value  
of the WORD in the default base, then waits for an input from you.  
You can respond with a carriage return, an ESC, or a numeric value.  
A carriage return terminates the command. An ESC results in the  
display of the next sequential WORD variable. If a numeric value is  
entered, the WORD variable is set to this value and the iECM-86  
again waits for input. At this point you can respond only with an ESC  
or carriage return. As before, the ESC displays the next sequential  
WORD and the carriage return terminates the command.  
WORD word_address = word_value  
This form is used to set an individual WORD variable without first  
checking its current value. When invoked, this command sets the  
WORD variable at word_address to word_value.  
WORD word_address TO word_address  
This form is used to display a region of memory as a sequence of  
WORD variables. When this command is invoked, iECM-86 starts  
by displaying the current default base and then a series of lines  
showing the contents of the selected memory region. The next line  
starts with a hexadecimal display of the address of the next WORD  
variable to be displayed, followed by the display of up to 16 bytes of  
memory as WORD variables in the default base. A new line starts  
whenever 16 bytes of memory have been displayed on the line. The  
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iECM-86 COMMANDS  
command terminates when all of the WORD variables in the selected  
range have been displayed. During lengthy displays, you can stop the  
output to the console by pressing the space bar. You can resume the  
display by pressing the space bar a second time. You terminate the  
command by entering a carriage return.  
WORD word_address TO word_address = word_value  
This form is used to initialize a region of memory to the given  
word_value. Note that this command takes a little over a millisecond  
(at 9600 baud) for each WORD loaded. You can terminate this  
command by entering a carriage return, but terminating the command  
leaves only part of the memory region initialized.  
5
5.4.4 DWORD Commands  
There are four basic forms for the DWORD commands:  
DWORD dword_address  
DWORD dword_address = dword_value  
DWORD dword_address TO dword_address  
DWORD dword_address TO dword_address = dword_value  
All of these commands can be used whether or not the users program is running.  
DWORD dword_address  
This form is used to examine and then possibly change one or more  
sequential DWORD variables. When this command is invoked,  
iECM-86 displays the dword_address in hexadecimal notation and  
the value of the DWORD in the default base, then waits for an input  
from you. You can respond with a carriage return, an ESC, or a  
numeric value. A carriage return terminates the command. An ESC  
results in the display of the next sequential DWORD variable. If a  
numeric value is entered, the DWORD variable is set to this value  
and the iECM-86 again waits for input. At this point you can respond  
only with an ESC or carriage return. As before, the ESC displays the  
next sequential DWORD and the carriage return terminates the  
command.  
DWORD dword_address = dword_value  
This form is used to set an individual DWORD variable without first  
checking its current value. When invoked, this command sets the  
DWORD variable at dword_address to dword_value.  
DWORD dword_address TO dword_address  
This form is used to display a region of memory as a sequence of  
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DWORD variables. When this command is invoked, iECM-86 starts  
by displaying the current default base and then a series of lines  
showing the contents of the selected memory region. The next line  
starts with a hexadecimal display of the address of the next DWORD  
variable to be displayed followed by the display of up to 16 bytes of  
memory as DWORD variables in the default base. A new line starts  
whenever 16 bytes of memory have been displayed on the line. The  
command terminates when all of the DWORD variables in the  
selected range have been displayed. During lengthy displays, you can  
stop the output to the console by pressing the space bar. You can  
resume the display by pressing the space bar a second time. You  
terminate the command by entering a carriage return.  
DWORD dword_address TO dword_address = dword_value  
This form is used to initialize a region of memory to the given  
dword_value. Note that this command takes a little over a  
millisecond (at 9600 baud) for each DWORD loaded. You can  
terminate this command by entering a carriage return, but  
terminating the command leaves only part of the memory region  
initialized.  
5.4.5 STACK Commands  
There are two basic forms for the STACK command:  
STACK stack_address  
STACK stack_address TO stack_address  
Both of these commands can be used whether or not the users program is running.  
STACK stack_address  
This command is useful for accessing a 16-bit variable that is known  
to be a fixed offset in the system stack. When this command is  
invoked, iECM-86 executes a WORD word_address command in  
which the word_address is formed by adding stack_address to the  
current value of the system stack pointer.  
STACK stack_address TO stack_address  
This command is useful for accessing a sequence of 16-bit variables  
that are known to start at a fixed offset in the system stack. When this  
command is invoked, iECM-86 executes a WORD word_address TO  
word_address command in which both word_address fields are  
formed by adding the corresponding stack_address to the current  
value of the system stack pointer. During lengthy displays, you can  
stop the output to the console by pressing the space bar. You can  
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iECM-86 COMMANDS  
resume the display by pressing the space bar a second time. You  
terminate the command by entering a carriage return.  
5.4.6 STRING Commands  
There is only one form of the STRING command:  
STRING byte_address  
The line starts with a hexadecimal display of byte_address followed by the NUL-terminated  
ASCII string starting at that address. For long strings, only the first 60 characters are dis-  
played. When trailing characters are stripped, decimal points (.) are substituted for the first  
three characters stripped.  
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5.4.7 PORT Commands  
There are four forms for the PORT command:  
PORT port_address  
PORT port_address = byte_value  
PORT port_address TO port_address  
PORT port_address TO port_address = byte_value  
All of these commands can be used whether or not the users program is running.  
PORT port_address  
This form is used to examine and then possibly change one or more  
sequential PORT variables. When this command is invoked, iECM-  
86 displays the port_address in hexadecimal notation and the value  
of the PORT in the default base, then waits for an input from you.  
You can respond with a carriage return, an ESC, or a numeric value.  
A carriage return terminates the command. An ESC results in the  
display of the next sequential PORT variable. If a numeric value is  
entered, the PORT variable is set to this value and the iECM-86  
again waits for input. At this point, you can respond only with an  
ESC or carriage return. As before, the ESC displays the next  
sequential PORT and the carriage return terminates the command.  
PORT port_address = byte_value  
This form is used to set an individual PORT variable without first  
checking its current value. When invoked, this command sets the  
PORT variable at port_address to byte_value.  
PORT port_address TO port_address  
This form is used to display a series of PORT variables. When this  
command is invoked, iECM-86 starts by displaying the current  
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default base and then a series of lines showing the contents of the  
selected ports. The next line starts with a hexadecimal display of the  
address of the next PORT variable to be displayed, followed by the  
display of up to 16 PORT variables in the default base. A new line  
starts whenever 16 ports have been displayed on the line. The  
command terminates when all of the PORT variables in the selected  
range have been displayed. During lengthy displays, you can stop the  
output to the console by pressing the space bar. You can resume the  
display by pressing the space bar a second time. You terminate the  
command by entering a carriage return.  
PORT port_address TO port_address = byte_value  
This form is used to initialize a set of ports to byte_value. Note that  
this command takes a little over a millisecond (at 9600 baud) for  
each PORT loaded. You can terminate this command by entering a  
carriage return, but terminating the command leaves only part of the  
memory region initialized.  
5.4.8 WPORT Commands  
There are four basic forms for the WPORT commands:  
WPORT wport_address  
WPORT wport_address = word_value  
WPORT wport_address TO wport_address  
WPORT wport_address TO wport_address = word_value  
All of these commands can be used whether or not the users program is running.  
WPORT wport_address  
This form is used to examine and possibly change one or more  
sequential WPORT variables. When this command is invoked,  
iECM-86 displays the wport_address in hexadecimal notation and  
the value of the WPORT in the default base, then waits for an input  
from you. You can respond with a carriage return, an ESC, or a  
numeric value. A carriage return terminates the command. An ESC  
results in the display of the next sequential WPORT variable. If a  
numeric value is entered, the WPORT variable is set to this value and  
the iECM-86 again waits for input. At this point, you can respond  
only with an ESC or carriage return. As before, the ESC displays the  
next sequential WPORT and the carriage return terminates the  
command.  
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iECM-86 COMMANDS  
WPORT wport_address = word_value  
This form is used to set an individual WPORT variable without first  
checking its current value. When invoked, this command sets the  
WPORT variable at wport_address to word_value.  
WPORT wport_address TO wport_address  
This form is used to display a series of WPORT variables. When this  
command is invoked, iECM-86 starts by displaying the current  
default base and then a series of lines showing the contents of the  
selected ports. The next line starts with a hexadecimal display of the  
address of the next WPORT variable to be displayed, followed by the  
display of up to 16 WPORT variables in the default base. A new line  
starts whenever 16 bytes of memory have been displayed on the line.  
The command terminates when all of the WPORT variables in the  
selected range have been displayed. During lengthy displays, you can  
stop the output to the console by pressing the space bar. You can  
resume the display by pressing the space bar a second time. You  
terminate the command by entering a carriage return.  
5
WPORT wport_address TO wport_address = word_value  
This form is used to initialize a set of ports to word_value. Note that  
this command takes a little over a millisecond (at 9600 baud) for  
each WPORT loaded. You can terminate this command by entering a  
carriage return, but terminating the command leaves only part of the  
memory region initialized.  
5.4.9 Processor Variables  
Several commands are provided to access variables that are associated with the processor rather  
than with the program:  
AX  
AH  
AL  
BX  
BH  
BL  
CX  
CH  
CL  
DX  
DH  
DL  
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CS  
DS  
SP  
BP  
DI  
ES  
FLAGS  
IP  
PC {=<code_address>}  
REGS  
SI  
SP = <word_address>  
SS  
The processor variables can be modified only while the target is stopped. They can be read at any  
time. These commands allow the display and loading of the internal target processor registers.  
Display is in the default base. Addresses are displayed in the last format used (i.e., if PC was  
loaded with the PC=segment:offset command, addresses will be displayed in that format).  
The REGS command displays the register contents of the microprocessor in the current base. The  
80C186EC registers may be individually displayed or changed by referring to them by name. The  
registers with suffixes of ‘H or ‘L are byte-wide; all others are word-wide.  
The PC and SP commands are special cases because they modify both segment and offset (i.e.,  
CS:IP, SS:SP).  
NOTE  
The examination of the SP will be confusing if you don’t understand the  
following paragraph.  
The iECM-86 software uses twenty-eight words in the user’s stack to store all internal CPU  
registers during a host interface interrupt. When the user displays the SP (or uses the STACK  
command), the value shown for SP is adjusted by the correct number of bytes to compensate for  
this overhead so that it becomes invisible to the user (the user must still allow for the extra stack  
space used).  
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6
iRISM-186  
Commands  
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CHAPTER 6  
iRISM-186 COMMANDS  
This chapter describes the elements of iRISM-186 monitor code. This information is common to  
all implementations.  
6.1 iRISM VARIABLES  
The following table lists the RISM variables and provides a description of each.  
Table 6-1. iRISM Variables  
Variable  
Description  
RISM_DATA  
A 32-bit register that acts as the primary data interface between software  
running in the host and the RISM running in the target.  
6
RISM_ADDR  
A 32-bit register that contains the address to be used for reading and writing  
target memory. The base address is contained in the most significant word  
and the offset is in the least significant word.  
RISM_STATUS  
An 8-bit register used to store RISM status and state information. This  
register contains the following boolean flags:  
BOOLEAN FLAGS  
DATA_FLAG  
RUN_FLAG  
TRAP_FLAG  
Indicates that the next character received by the RISM should be treated as a  
data byte, even if its value corresponds to an implemented command.  
Indicates that the target is running user code. It can modify the operation of  
some RISM commands.  
Indicates that the target was running user code, but that a software trap  
suspended its execution. The TRAP_FLAG is cleared whenever RISM starts  
execution of user code.  
DIAG_FLAG  
An optional flag that indicates that the target is operating in a diagnostic  
mode. Details of this flag are implementation-dependent.  
USER_CS /  
USER_IP  
Used to save the user’s program counter while the user’s code is not  
executing.  
USER_FLAGS  
Saves the user’s program status word while the user’s code is not executing.  
6.1.1 Other Variables  
Specific implementations of RISMs will require other variables for temporary storage.  
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6.2 RISM STRUCTURE  
The RISM resides in the target system and provides the interface between the target system and  
the user interface, which resides in the host system. The RISM is compact and simple. This serves  
two purposes:  
1. The RISM can reside in a user’s system with minimal impact on available memory.  
2. The RISM is easy to port into the target’s environment.  
The internal state structure of the RISM was kept as simple as possible. There are only three  
internal flags that can change the way that the RISM deals with a character sent by the host.  
6.3 RECEIVING DATA FROM THE HOST  
When the RISM receives a character from the host, its first task is to determine whether the  
character represents a command or data. When the character is less than 32 (decimal), it is  
assumed to be a command. When the character is more than 32 (decimal), it is assumed to be data.  
When the host needs to send a data byte that has a value less than 32, it first must issue a  
SET_DATA_FLAG command. When the DATA_FLAG is set, the next character received by the  
RISM is interpreted as data (even if it is less than 32), and the DATA_FLAG is cleared. Once the  
RISM determines that the received character is a data byte, it processes it by shifting the 32-bit  
RISM_DATA register left eight places and then placing the data byte in the lower byte of the  
RISM_DATA register. The data shifted out of the upper byte of the RISM_DATA register is  
discarded.  
6.4 SENDING DATA TO THE HOST  
When the host expects data to be returned from the RISM, it sends a TRANSMIT command byte  
and waits for a response. The RISM transmits the lower byte of the 32-bit RISM_DATA register  
and right shifts the RISM_DATA register by eight bits. As part of this command, the RISM  
increments its RISM_ADDR register. The RISM transmits data only in response to a  
TRANSMIT command, never on its own initiative or even in response to other commands from  
the host.  
6.5 RISM COMMANDS  
This section details the operation of each of the commands sent to the RISM.  
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iRISM-186 COMMANDS  
6.5.1 SET_DATA_FLAG (Code 00H)  
This command sets the DATA_FLAG. This forces the next character received by the RISM  
to be treated as data, even if its value corresponds to a RISM command. The code that over-  
rides the normal selection of command or data also clears the DATA_FLAG so that it  
applies only to the first character received after the SET_DATA_FLAG command.  
6.5.2 TRANSMIT (Code 02H)  
This command transmits the lower eight bits of the RISM_DATA register to the host, right  
shifts the data register eight places, and increments the RISM_ADDR register. Sequential  
TRANSMIT commands are used to read the RISM_DATA register; the RISM_ADDR reg-  
ister indicates the address that corresponds to the least-significant byte in the RISM_DATA  
register.  
6.5.3 READ_BYTE (Code 04H)  
6
This command reads the byte of memory pointed to by the RISM_ADDR register and  
places the result in the least-significant byte of the RISM_DATA register.  
6.5.4 READ_WORD (Code 05H)  
This command reads the word of memory pointed to by the RISM_ADDR register and  
places the result in the least-significant word of the RISM_DATA register.  
6.5.5 READ_DOUBLE (Code 06H)  
This command reads the double-word of memory pointed to by the address register and  
places the result in the RISM_DATA register.  
6.5.6 WRITE_BYTE (Code 07H)  
This command stores the least-significant byte of the RISM_DATA register in the byte of  
memory pointed to by the RISM_ADDR register and increments the RISM_ADDR register  
(by one) to point to the next memory byte.  
6.5.7 WRITE_WORD (Code 08H)  
This command stores the least-significant word of the RISM_DATA register in the word of  
memory pointed to by the RISM_ADDR register and increments the RISM_ADDR register  
(by two) to point at the next memory word.  
6-3  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
6.5.8 WRITE_DOUBLE (Code 09H)  
This command stores the RISM_DATA register in the double-word of memory pointed to  
by the RISM_ADDR register and increments the RISM_ADDR register (by four) to point  
at the next memory double-word.  
6.5.9 LOAD_ADDRESS (Code 0AH)  
This command loads the RISM_ADDR register with the least-significant word in the  
RISM_DATA register.  
6.5.10 READ_PC (Code 10H)  
This command loads the RISM_DATA register with the CS (Code Segment) and IP  
(Instruction Pointer) associated with the users code. Most RISM implementations have to  
check RUN_FLAG to determine how to access the users PC.  
6.5.11 WRITE_PC (Code 11H)  
This command loads the CS (Code Segment) and the IP (Instruction Pointer) associated  
with the users code from the RISM_DATA register. The host software will invoke this  
command only while user code is not running.  
6.5.12 START_USER (Code 12H)  
This command starts execution of user code, clears the TRAP_FLAG, and sets the  
RUN_FLAG. The action of this command relies on its being executed as part of an ISR  
(Interrupt Service Routine). At the start of the ISR, the current CS:IP and FLAGS are  
pushed into the stack. If the user code is not running, the CS:IP and FLAGS that are pushed  
into the stack are associated with an idle loop that the RISM runs while it waits for an inter-  
rupt. The START_USER command deletes the CS:IP and FLAGS from the stack and  
replaces them with USER_CS, USER_IP and USER_FLAGS. When control returns from  
the ISR, the users code (rather than the idle loop) executes. The host software will not issue  
a GO command if the user code is already running.  
6.5.13 STOP_USER (code 13H)  
This command stops the execution of user code and clears the RUN_FLAG. The action of  
the HALT command mirrors that of the GO command. In the case of the HALT command,  
the users CS:IP and FLAGS are pushed into the stack upon entry to the ISR. The  
STOP_USER command saves this user information in USER_CS, USER_IP, and  
USER_FLAGS and replaces it with CS:IP and FLAGS values associated with the idle loop.  
When control returns from the ISR, the idle loop (rather than the user’s code) executes. The  
host software will not issue a HALT command unless the user code is running.  
6-4  
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6.5.14 TRAP_ISR  
This is a pseudo-command. It cannot be issued directly by the host software, but is executed  
when an INT3 is executed. The INT3 instruction is used by iECM-86 for implementing  
software breakpoints and for single-stepping. A separate entry point into the STOP_USER  
command is provided for the INT3 vector. Code at this entry point sets the TRAP_FLAG  
and then drops into the code that implements the STOP_USER command.  
6.5.15 REPORT_STATUS (Code 14H)  
This command loads the least-significant word of the RISM_DATA register with status  
information. Valid status values are 0, 1, and 2:  
0—indicates that user code is stopped (RUN_FLAG and TRAP_FLAG are both  
FALSE)  
1—indicates that user code is running (RUN_FLAG is TRUE)  
2—indicates that user code executed a TRAP instruction (TRAP_FLAG is TRUE)  
The host software periodically polls the target system to check on its status, and this polling  
can rob execution time from the users program. This loss of target processor cycles can be  
avoided by setting the Ring Indicator modem status line signal whenever the RUN_FLAG  
is set. The host software assumes that the target is running user code whenever it detects the  
ring indicator and issues REPORT_STATUS commands only if the ring indicator is off.  
6.5.16 MONITOR_ESCAPE (Code 15H)  
This command provides for the addition of RISM commands for special purposes; it uses  
the RISM_DATA register to extend the command set of the RISM. The basic RISM  
requires only one of these “extended” commands; if the lower 16-bits of the RISM_DATA  
register is one (RISM_DATA = 0XXXX0001H), the target processor should execute either  
a RST (ReSeT) instruction or a software initialization routine.  
6.5.17 READ_BPORT (Code 16H)  
This command reads the 8-bit input port pointed to by the RISM_ADDR register and places  
the result in the least-significant byte of the RISM_DATA register.  
6.5.18 WRITE_BPORT (Code 17H)  
This command stores the least-significant byte of the RISM_DATA register in the 8-bit out-  
put port pointed to by the RISM_ADDR register.  
6.5.19 READ_WPORT (Code 18H)  
This command reads the 16-bit input port pointed to by the RISM_ADDR register and  
places the result in the least-significant word of the RISM_DATA register.  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
6.5.20 WRITE_WPORT (Code 19H)  
This command stores the least-significant word of the RISM_DATA register in the 16-bit  
output port pointed to by the RISM_ADDR register.  
6.5.21 STEP (Code 1AH)  
This command sets the target processors TRAP_FLAG and the RUN_FLAG and steps one  
instruction. After setting these flags, the action of this command is similar to the  
START_USER command followed by a TRAP.  
6.5.22 READ_REG (Code 1BH)  
This command reads the word value of a CPU register pointed to by the most-significant  
word of the RISM_DATA register and places the result in the least-significant word of the  
RISM_DATA register. Registers are accessed as shown in Table 6-2:  
Table 6-2. iRISM Registers  
MSW of RISM_DATA  
Register  
0000H  
0001H  
0002H  
0003H  
0004H  
0005H  
0006H  
0007H  
0008H  
0009H  
000AH  
000BH  
000CH  
000DH  
SS  
ES  
DS  
DI  
SI  
BP  
SP  
BX  
DX  
CX  
AX  
IP  
CS  
FLAGS  
6.5.23 WRITE_REG (Code 1CH)  
This command stores the least-significant word of the RISM_DATA register in the CPU register  
pointed to by the most-significant word of the RISM_DATA register. Registers are accessed as  
shown in Table 6-2.  
6-6  
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iRISM-186 COMMANDS  
6.5.24 Start Up Commands (/ or \)  
Upon reset, the board is in the echo mode. Until it receives an ASCII slash (/) or reverse-  
slash (\), it increments every character it receives from the host and sends the incremented  
value back to the host. It also displays the binary code of the character received on the  
LEDs. If a reverse-slash is received by the RISM, the board leaves the echo mode and starts  
normal operation. If a slash is received, it stops echoing incremented received data and  
starts responding to RISM commands with the diagnostic flag set. (See the option “-DIAG”  
on page 4-4 for additional information on the diagnostic mode.)  
6
6-7  
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A
Parts List  
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APPENDIX A  
PARTS LIST  
Table A-1 provides the board location, manufacturer, and description of each part on the 80186  
EB Evaluation Board. Table A-2 provides the same information for the 186 EC Evaluation Board.  
Table A-1. 80186 EB Board Manual Parts List (Sheet 1 of 3)  
MANUFACTURER  
PART NUMBER  
LOCATION  
DESCRIPTION  
CAP, .001µF  
CAP, .01µF  
CAP, 10µF  
FOOTPRINT  
CC0805  
CC0805  
6032  
COMMENTS  
C31  
Kemet #  
C0805C102K5RAC  
SMT Chip Cap  
C22,C26  
C5,C32  
Kemet #  
C0805C103K5RAC  
SMT Chip Cap  
SMT Tant.  
Kemet #  
A
T491C106K010AS  
C4,C9,C10,  
Kemet #  
CAP, .1µF  
CC0805  
SMT Chip Cap  
C0805C104K5RAC  
C11,C13,C14,  
C20,C21,C23,  
C24,C28,C29,  
C30,C34  
C1,C2,C3,  
Kemet #  
C2220C105J5RAC  
CAP, 1µF  
CC2220  
SMT Chip Cap  
SMT Chip Cap  
C6,C7,C8,  
C15,C19  
C33  
Kemet #  
T491D476K016AS  
CAP, 47µF  
CAP, 100µF  
CAP, 330pF  
CAP, 22pF  
7343  
C12,C27  
C25  
Kemet #  
T495X107K010AS  
7343H  
SMT Tant.  
ESR<.25 Ω  
SMT Chip Cap  
Kemet #  
C0805C331K5RAC  
CC0805  
CC0805  
CC0805  
C17,C18  
C16  
Kemet #  
C0805C220J5GAC  
SMT Chip Cap  
Not installed, but  
place footprint  
D1  
Philips #1N4148  
DIODE, 1N4148  
DIODE, 1N5817  
DO-35  
DO-41  
Axial lead Diode  
D2,D3  
Motorola # 1N5817  
Axial lead Schottky  
Diode  
E1,E4,E5  
E2,E3  
J2  
3M #23036111TG  
3M #23066121TG  
3 PIN HEADER  
4 PIN HEADER  
JUMP3  
JUMP4  
3 pin header for  
jumper  
4 pin header for  
jumper, cut 2 x 6  
Methode  
2 PIN PWR CONN  
CN2PMLX  
2 pin power connector  
#3100-8-102-01  
A-1  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
Table A-1. 80186 EB Board Manual Parts List (Sheet 2 of 3)  
MANUFACTURER  
PART NUMBER  
LOCATION  
DESCRIPTION  
14 PIN SIP SKT  
2 X 30 HEADER  
2 X 12 HEADER  
FOOTPRINT  
SIP14  
COMMENTS  
J1  
AMP #544282-3  
AMP # 4-87227-0  
AMP # 1-103186-2  
14 pin SIP socket  
terminal strip  
JP1  
HDR2X30  
HDR2X12  
Cut to size  
(3-103186-0)  
JP2  
L3  
Coilcraft #D03316P-103 10 µH INDUCTOR  
SMT inductor, 10µH  
SMT inductor, 100µH  
L2  
Coilcraft #D03316P-104 100µH INDUCTOR  
L1  
3216CHIP  
DB9FM1  
SOT23  
Not installed, but  
place footprint  
P1,P2  
Q1  
AMP # 748875-3  
DB9  
RECEPTACLE  
9 pin, sub-D, R/A,  
female  
Motorola  
PNP TRANSISTOR  
SMT PNP  
#MMBT2907ALT1  
transistor,2907A  
R1  
Dale # CRCW1206  
Dale # CRCW1206  
RES, 100k Ω  
RES, 10k Ω  
CR1206  
CR1206  
SMT resistor, 100k  
SMT resistor, 10k  
R4,R5,R6,  
R7,R8,R12,  
R13  
R9  
Dale # CRCW1206  
RES, 220k Ω  
RES,16.9k,.1%  
CR1206  
CR1206  
SMT resistor, 220k  
R11  
Dale # TNPW-1206-  
1692-B-T-2  
SMT resistor,16.9k,  
.1% tolerance  
R10  
Dale # TNPW-1206-  
1002-B-T-2  
RES,10k,.1%  
CR1206  
SMT resistor,16.9k,  
.1% tolerance  
R3  
R2  
Dale # CRCW1206  
RES, 1.5k Ω  
POT,50k  
CR1206  
SMT resistor, 1.5k  
Bourns 3006P,50k,  
potentiometer  
PT3006P  
Thru-hole  
potentiometer,50k  
RP1  
S1  
Bourns # 4610X-101  
RPACK, 10K Ω  
SIP10  
Thru-hole,10 pin, 10k  
RPACK  
ITT Cannon #  
KSAOM211  
Mom. switch  
RESET  
Thru-hole, 4 pin  
(Include square blk  
button #)  
TP1 - TP8  
U11  
Mill-Max # 3132-0-00-  
15-00-00-08-0  
Testpoint turret  
12V Supply device  
SMT 32 pin socket  
3.3V,1Mb,SRAM  
5V,1Mb,SRAM  
EPOINT  
S08  
Maxim # MAX734CSA  
Pending SMT  
availability  
XU8, XU13  
U8,U13  
U8,U13  
Berg McKenzie #  
SOJ32P-4.0  
SOJ32/400  
SRAM Sockets  
NEC  
To be installed  
(socketed)  
# D431008LLE-A17  
NEC # D431008LE-17  
Bagged, to be  
included in kit  
package  
U8,U13  
Hitachi  
#HM62W8127HLJP-35  
3.3V,1Mb,SRAM  
Possible secondary  
source for 3V & 5V  
SRAM  
A-2  
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PARTS LIST  
Table A-1. 80186 EB Board Manual Parts List (Sheet 3 of 3)  
MANUFACTURER  
PART NUMBER  
LOCATION  
DESCRIPTION  
FOOTPRINT  
COMMENTS  
XU9  
Meritec # 980021-44-01 SMT 44 pin socket  
SOP44  
SMT 44 pin  
socket,w/o alignment  
pins  
U9  
INTEL  
#PA28F400BV-T60  
4Mb,boot blk,flash  
74AC573  
Socketed  
U6,U12,U14  
U7  
Motorola #  
MC74AC573DW  
SO20W  
SO8  
SMT Octal latch  
Maxim # MAX750CSA  
AMP # 822039-3  
Step-down  
regulator  
Pending SMT  
availability  
XU10  
28 Pin PLCC  
socket  
SOCKET28  
SMT 28 pin PLCC  
socket  
U10  
U1  
Lattice  
#GAL22LV10C-15LJ  
Low voltage GAL  
Socketed  
Motorola # MC74AC14D  
Maxim # MAX561CWI  
Thru-hole DIP socket  
74AC14  
SO14  
SO28W  
XTAL8  
SMT Hex Schmitt Trg.  
inverter  
A
U2  
562 Ser. xceiver  
4 pin socket for osc  
32MHZ Oscillator  
SMT 3.3V 562  
Interface device  
XU5, XU3  
U5  
4 pin socket in 8 pin  
DIP size for oscillators  
CTS 32MHZ,half size  
can  
Socketed, Digi-Key  
# CTX174-ND  
U3  
CTS 6MHZ,half size can 6MHZ Oscillator  
Socketed, Digi-Key  
# CTX159-ND  
XU4  
Samtec  
#PLCC-084-T-N  
84 ld PLCC socket  
SOCKET84  
XTALV  
SMT 84 pin  
socket,w/o alignment  
pins  
U4  
Y1  
INTEL # N80L186EB-16 3.3V 80X186EB  
Socketed  
microprocessor  
Not installed, but  
place footprint  
Jumper shunts  
J1  
Configureable options  
Sharp # LM16155  
LCD Display  
Socketed at J3,  
mount holes will  
require stndoff  
Standoff H/W  
EF Johnson #J234-ND  
(D/K)  
Round Spacer,  
.375  
2/Bd.Require (2) 2-56  
nylon  
screw,nut,washer  
H538-ND,H612-ND,  
#2 washer (D/K)  
Nylon #2 H/W  
Nylon#2-56,3/4  
screw,nut,washer as  
per above  
A-3  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
Table A-2. 80186 EC Board Manual Parts List (Sheet 1 of 3)  
MANUFACTURER  
PART NUMBER  
LOCATION  
DESCRIPTION  
CAP, .001µF  
CAP, .01µF  
CAP, 10µF  
FOOTPRINT  
CC0805  
CC0805  
6032  
COMMENTS  
C31  
Kemet #  
C0805C102K5RAC  
SMT Chip Cap  
C21,C30  
Kemet #  
C0805C103K5RAC  
SMT Chip Cap  
SMT Tant.  
C8,C32  
Kemet #  
T491C106K010AS  
C7,C13,C14,  
Kemet #  
CAP, .1µF  
CC0805  
SMT Chip Cap  
C0805C104K5RAC  
C15,C16,C17,  
C20,C22,C23,  
C26,C27,C28,  
C29,C34  
C1,C2,C3,  
Kemet #  
CAP, 1µF  
CC2220  
SMT Chip Cap  
C2220C105J5RAC  
C6,C10,C11,  
C12,C18  
C33  
Kemet #  
T491D476K016AS  
CAP, 47µF  
CAP, 100µF  
CAP, 330pF  
CAP, 22pF  
7343  
SMT Chip Cap  
C19,C25  
C24  
Kemet #  
T495X107K010AS  
7343H  
SMT Tant. ESR<.25 Ω  
SMT Chip Cap  
Kemet #  
C0805C331K5RAC  
CC0805  
CC0805  
CC0805  
C5,C9  
C4  
Kemet #  
C0805C220J5GAC  
SMT Chip Cap  
Not installed, but  
place footprint  
D1  
Philips #1N4148  
DIODE, 1N4148  
DIODE, 1N5817  
DO-35  
DO-41  
Axial lead Diode  
D2,D3  
Motorola # 1N5817  
Axial lead Schottky  
Diode  
E1,E4,E5  
E2,E3  
J2  
3M #23036111TG  
3M #23066121TG  
3 PIN HEADER  
4 PIN HEADER  
2 PIN PWR CONN  
14 PIN SIP SKT  
JUMP3  
JUMP4  
3 pin header for  
jumper  
4 pin header for  
jumper, cut 2 x 6  
Methode  
#3100-8-102-01  
CN2PMLX  
SIP14  
2 pin power connector  
J1  
AMP #544282-3  
14 pin SIP socket  
terminal strip  
JP1  
JP2  
L3  
AMP # 4-87227-0  
AMP # 2-87227-0  
2 X 30 HEADER  
2 X 20 HEADER  
HDR2X30  
HDR2X20  
Cut to size  
Coilcraft #DO3316P-103 10 µH INDUCTOR  
Coilcraft #DO3316P-104 100µH INDUCTOR  
SMT inductor, 10µH  
SMT inductor, 100µH  
L2  
A-4  
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PARTS LIST  
Table A-2. 80186 EC Board Manual Parts List (Sheet 2 of 3)  
MANUFACTURER  
PART NUMBER  
LOCATION  
DESCRIPTION  
FOOTPRINT  
3216CHIP  
DB9FM1  
COMMENTS  
L1  
Not installed, but  
place footprint  
P1,P2  
Q1  
AMP # 748875-3  
DB9  
RECEPTACLE  
9 pin, sub-D, R/A,  
female  
Motorola #  
PNP TRANSISTOR  
SOT23  
SMT PNP  
MMBT2907ALT1  
transistor,2907A  
R1  
Dale # CRCW1206  
Dale # CRCW1206  
RES, 100k Ω  
RES, 10k Ω  
CR1206  
CR1206  
SMT resistor, 100k  
SMT resistor, 10k  
R4,R5,R6,  
R7,R8,R9,  
R10  
R11  
Dale # CRCW1206  
RES, 220k Ω  
RES,16.9k,.1%  
CR1206  
CR1206  
SMT resistor, 220k  
R13  
Dale # TNPW-1206-  
1692-B-T-2  
SMT resistor,16.9k,  
.1% tolerance  
A
R12  
Dale # TNPW-1206-  
1002-B-T-2  
RES,10k,.1%  
CR1206  
SMT resistor,16.9k,  
.1% tolerance  
R3  
R2  
Dale # CRCW1206  
RES, 1.5k Ω  
POT,50k  
CR1206  
SMT resistor, 1.5k  
Bourns 3006P,50k,  
potentiometer  
PT3006P  
Thru-hole  
potentiometer,50k  
RP1  
S1  
Bourns # 4610X-101  
RPACK, 10K Ω  
SIP10  
Thru-hole,10 pin, 10k  
RPACK  
ITT Cannon  
# KSAOM211  
Mom. switch  
RESET  
Thru-hole, 4 pin  
(Include square blk  
button #)  
TP1 - TP8  
U11  
Mill-Max # 3132-0-00-  
15-00-00-08-0  
Testpoint turret  
12V Supply device  
SMT 32 pin socket  
3.3V,1Mb,SRAM  
5V,1Mb,SRAM  
EPOINT  
S08  
Maxim # MAX734CSA  
Pending SMT  
availability  
XU7, XU13  
U7,U13  
U7,U13  
U7,U13  
Berg McKenzie  
# SOJ32P-4.0  
SOJ32/400  
SRAM Sockets  
NEC # D431008LLE-  
A17  
To be installed  
(socketed)  
NEC # D431008LE-17  
Bagged, to be included  
in kit package  
Hitachi #  
HM62W8127HLJP-35  
3.3V,1Mb,SRAM  
Possible secondary  
source for 3V & 5V  
SRAM  
XU9  
Meritec  
# 980021-44-01  
SMT 44 pin socket  
SOP44  
SMT 44 pin  
socket,w/o alignment  
pins  
U9  
INTEL # PA28F400BV- 4Mb,boot blk,flash  
T60  
Socketed  
U8,U12,U14  
U6  
Motorola  
# MC74AC573DW  
74AC573  
SO20W  
SO8  
SMT Octal latch  
Maxim # MAX750CSA  
Step-down  
regulator  
Pending SMT  
availability  
A-5  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
Table A-2. 80186 EC Board Manual Parts List (Sheet 3 of 3)  
MANUFACTURER  
PART NUMBER  
LOCATION  
DESCRIPTION  
FOOTPRINT  
COMMENTS  
XU10  
AMP # 822039-3  
28 Pin PLCC  
socket  
SOCKET28  
SMT 28 pin PLCC  
socket  
U10  
U1  
Lattice # GAL22LV10C- Low voltage GAL  
15LJ  
Socketed  
Motorola # MC74AC14D  
74AC14  
SO14  
SO28W  
XTAL8  
SMT Hex Schmitt Trg.  
inverter  
U2  
Maxim # MAX561CWI  
562 Ser. xceiver  
SMT 3.3V 562  
Interface device  
XU3, XU5  
U3  
Mill-Max #S190-00-000- 4 pin socket for osc  
00-22000  
4 pin socket in 8 pin  
DIP size for oscillators  
CTS 32MHZ,half size  
can  
32MHZ Oscillator  
Socketed, Digi-Key  
# CTX174-ND  
U5  
CTS 6MHZ,half size can 6MHZ Oscillator  
Socketed, Digi-Key  
# CTX159-ND  
XU4  
3M # 2-0100-07243-  
000-018-007  
100 ld PQFP  
socket  
Thru-hole socket  
U4  
Y1  
INTEL  
# KU80L186EC-16  
3.3V 80X186EC  
Socketed  
microprocessor  
XTALV  
Not installed, but  
place footprint  
Jumper shunts  
J1  
Configureable options  
Sharp # LM16155  
LCD Display  
Socketed at J3, mount  
holes will require  
stndoff  
Standoff H/W  
EF Johnson #J234-ND  
Round Spacer,  
.375  
2/Bd.Require (2) 2-56  
nylon  
screw,nut,washer  
H538-ND,H612-ND,#2  
washer  
Nylon #2 H/W  
Nylon#2-56,3/4  
screw,nut,washer,as  
per above  
A-6  
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INDEX  
80C186EB/EC features, 3-2  
80C188EB/EC, configuring board jumpers, 3-2  
8-bit bus, configuring the board for, 3-2  
I
I/O port unit, 3-1  
I/O space, reserved, 4-6  
iEC-86  
program variables, 5-10  
iECM-86, 4-1  
breakpoints, 5-5  
features, 4-1  
program stepping, 5-8  
supported data types, 5-10  
iECM-86 commands, 4-3  
BR, 5-6  
A
adaptor  
25-pin to 9-pin, 3-11  
for in-circuit emulation, 3-2  
B
BCLK0 input, 3-10  
breakpoints, 5-5  
bus expansion, 3-14  
BYTE, 5-11  
DWORD, 5-13  
GO, 5-7  
C
connectors  
P1, 3-9  
GO FOREVER, 5-7  
GO FROM, 5-7  
GO TILL, 5-8  
HALT, 5-7, 5-8  
INCLUDE, 5-3  
LIST, 5-4  
P2, 3-10  
customer service, 1-4  
D
data types, supported by iECM-86, 5-10  
display controller, 3-15  
LISTOFF/ON, 5-4  
LOAD, 5-2  
LOG, 5-4  
LOGOFF/LOGON, 5-4  
PAUSE, 5-3  
PORT, 5-15  
RESET CHIP, 5-5  
RESET SYSTEM, 5-5  
SAVE, 5-2  
STACK, 5-14  
STEP | SSTEP, 5-9  
STRING, 5-15  
WORD, 5-12  
E
E1 jumper, 3-8  
EIA/TIA-562 protocol, 3-10  
Embedded Controller Monitor (ECM), 4-1, 4-2  
evaluation board  
layout of EB, 2-1  
layout of EC, 2-2  
setting up, 2-4–2-5  
expansion connectors, 3-12  
Expansion memory, 3-3  
F
FaxBack service, 1-4  
Flash loader utility, 3-5  
Flash memory, 3-3  
bus width configuration, 3-5  
downloading to, 3-5–3-6  
mapping, 3-5  
WPORT, 5-16  
include files, 5-3  
iRISM-186, 4-1  
registers, 6-6  
restrictions, 4-2  
on-board, 3-1  
J
H
JP1 expansion connector, 3-12  
jumpers  
hardware overview, 3-1  
Hitachi 44780 LCD display controller, 3-15  
configuring for an 8-bit bus, 3-2  
E1, 3-8  
J2 (power connector), 3-8  
summary, 3-1  
Index-1  
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INTEL 186 EB/EC EVALUATION BOARD USER’S MANUAL  
STOP_USER, 6-4  
TRANSMIT, 6-3  
TRAP_ISR, 6-5  
WRITE_BPORT, 6-5  
WRITE_BYTE, 6-3  
WRITE_DOUBLE, 6-4  
WRITE_PC, 6-4  
WRITE_REG, 6-6  
WRITE_WORD, 6-3  
WRITE_WPORT, 6-6  
L
LCD interface, 3-15  
list files, 5-3  
log files, 5-3  
M
Maxim MAX561, 3-10  
Maxim MAX750, 3-8  
memory configuration, 3-3  
memory map, 3-3  
memory, reserved, 4-6  
RISM monitor, 3-3  
N
S
non-maskable interrupt, 4-6  
notational conventions, 1-2  
segment variable registers, 5-1  
serial control unit, 3-1  
serial port connector (P1), 3-9  
serial ports  
P
P1 connector, 3-9  
on-chip, 3-10  
reconfiguring for different operating  
frequency, 3-2  
P2 connector, 3-10  
peripheral expansion connector, 3-12, 3-13  
power supply, 3-8  
processor, selecting type using jumper, 3-1  
program control, 5-5  
program stepping, in iECM-86 programs, 5-8  
programmable chip-selects, 3-1  
SRAM memory, 3-3  
SRAM, mapping, 3-7  
super-stepping, 5-9  
T
technical support, 1-5  
timer/counter unit, 3-1  
Trap Flag, 4-6  
R
reserved I/O space, 4-6  
reserved memory, 4-6  
RISM  
used in step operation, 5-9  
receiving data from host, 6-2  
sending data to the host, 6-2  
structure, 6-2  
V
voltage, selecting using jumper, 3-1  
W
variables, 6-1  
World Wide Web, 1-4  
RISM commands  
LOAD_ADDRESS, 6-4  
MONITOR_ESCAPE, 6-5  
READ_BPORT, 6-5  
READ_BYTE, 6-3  
READ_DOUBLE, 6-3  
READ_PC, 6-4  
READ_REG, 6-6  
READ_WORD, 6-3  
READ_WPORT, 6-5  
REPORT_STATUS, 6-5  
SET_DATA_FLAG, 6-3  
start-up commands, 6-7  
START_USER, 6-4  
STEP, 6-6  
Index-2  
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