Intel 8085, 8080 manual ISIS·IIAssembler Controls

Page 12

Assembler Controls

808O/808S Assembler

Control

PIG

Function Area

flAGELENGTH (66)

P

Listing Format

PAGEWIDTH (120)

P

Listing Format

TITLE

G

Listing Format

EJECT

G

Listing Format

GEN/NOGEN

G

Macro List

MACRODEBUG/NOMACRODEBUG

P

Macro List

MACROFILE/NOMACROFILE

P

Macro Temporary File

MOD85

P

8085 Switch

SAVE

G

Stack Controls

RESTORE

G

Fetch Controls

INCLUDE

G

Library Function

TTY/NOTTY

P

Teletypewriter Function

In general, controls go into effect at the end of the control line. Exceptions occur for control lines that cause a transition between 'listing' and 'not listing' states.

If the transition is caused by a change in the LISTINOLIST controls, the control line containing the LISTINOLIST is always printed. If a change in GEN/NOGEN causes the transition, the control line is not printed. If the control line contains both LISTINOLIST and GEN/NOGEN changes, the control line is printed.

ISIS·IIAssembler Controls

ISIS-II Assembly-Time Command

The ISIS-II Assembler for the 8080 or 8085 is invoked by calling the ISIS-II file ASM80. This call includes the name of your source file and any assembler controls you wish to specify. Items in the control list are separated by spaces. The call is terminated by a carriage return.

-ASM80 file control-list

The "file" in this format is your source file. This file (and files enclosed in paren- theses as part of a control) can be a 1-6 character file name, a file name followed by a period and 1-3 character extension, an ISIS-II device name, or an ISIS-II device name followed by a file name and extension. (See the ISIS-II System User's Guide for details.)

Examples:

FILE20

(filename)

PROG.SRC

(filename. extension)

:HR:

(:ISIS-II device name:)

:F1 :ASSMB.SRC

(:ISIS-II dev name:filename.ext)

All control items specified must be spelled out in their entirety.

Example:

·ASM80PROG.SRC DEBUG SYMBOLS XREF

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Contents ISIS-II 8080/8085 Macro Assembler Operatorsmanual Scope Prefacei Page Contentsi Page Chapter Assembler Overview ISIS-II Assembler EnvironmentInput/Output Files Symbol-Cross-Reference File Assembler FilesPage Chapter ISIS·IIAssembler Controls Primary Controls General Controls ISIS-II Assembler Control Lines Page Sample Assembly Activation SequenceAsmbo MBADD.SRC Symbols Xref Macrofile Reducing Assembly Time Page Chapter List File Formats List File Formats 808O/808S Assembler Assembly Output Line Symbol Table Listing Symbol-Cross-Reference Listing Cross-Reference Output LineChapter PL/M Linkage Conventions Page Absolute Programs Relocatable ProgramsPage Error Detection and Reporting Error CodesError Messqes ISIS-II Error Messages FOCC= OOnn Request for Readerscomments 111111
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8080, 8085 specifications

The Intel 8085 and 8080 microprocessors were groundbreaking innovations in the world of computing, paving the way for future microprocessor development and personal computing.

The Intel 8080, introduced in 1974, was an 8-bit microprocessor that played a fundamental role in the early days of personal computing. With a 16-bit address bus, it had the capability to address 64 KB of memory. Running at clock speeds of 2 MHz, the 8080 was notable for its instruction set, which included 78 instructions and 246 opcodes. It supported a range of addressing modes including direct, indirect, and register addressing. The 8080 was compatible with a variety of peripherals and played a crucial role in the development of many early computers.

The microprocessor's architecture was based on a simple and efficient design, making it accessible for hobbyists and engineers alike. It included an 8-bit accumulator, which allowed for data manipulation and storage during processing. Additionally, the 8080 featured registers like the program counter and stack pointer, which facilitated program flow control and data management. Its ability to handle interrupts also made it suitable for multitasking applications.

The Intel 8085, introduced in 1976, was an enhancement of the 8080 microprocessor. It maintained a similar architecture but included several key improvements. Notably, the 8085 had a built-in clock oscillator, simplifying system design by eliminating the need for external clock circuitry. It also featured a 5-bit control signal for status line management, which allowed for more flexible interfacing with peripheral devices. The 8085 was capable of running at speeds of up to 3 MHz and had an extended instruction set with 74 instructions.

One of the standout features of the 8085 was its support for 5 extra instructions for stack manipulation and I/O operations, which optimized the programming process. Additionally, it supported serial communication, making it suitable for interfacing with external devices. Its 16-bit address bus retained the 64 KB memory addressing capability of its predecessor.

Both the 8080 and 8085 microprocessors laid the groundwork for more advanced microprocessors in the years that followed. They demonstrated the potential of integrated circuits in computing and influenced the design and architecture of subsequent Intel microprocessors. Their legacy endures in the way they revolutionized computing, making technology accessible to a broader audience, and their influence is still felt in the design and architecture of modern microprocessors today.