Intel 8080, 8085 manual Primary Controls

Page 13

8080/8085 Assembler

Assembler Controls

Primary Controls

Control

Effect

OBJECT(file)

An object code file is generated and is output to the

 

specified diskette file. If this control is omitted,

 

"OBJECT(file.OBJ)" is assumed, where "file" is the

 

name of your source file; the file is directed to the same

 

drive used for the source file.

NOOBJECT

Object code generation is suppressed.

MOD85

The assembler assumes that BOBO code is being

 

assembled unless the B085 instruction set is specified by

 

this control. This assembler issues a warning if an B085 in-

 

struction is encountered in the 8080 mode.

DEBUG

If an object file is requested, the symbol table is output to

 

that file. DEBUG has no effect otherwise.

NODEBUG

The symbol table is not included in the object file.

PRINT(file)

An assembly list file is generated and is output to the

 

specified file. If this control is omitted, "PRINT(file.LST)"

 

is assumed, where "file" is the name of your source code

 

file; the file is directed to the name drive used for the

 

source file. See general control LIST.

NOPRINT

The assembly output listing is suppressed. No file

 

is specified for listing; therefore, no listing output is

 

possible.

SYMBOLS

If a list file is opened by PRINT, the symbol table is output

 

to the list file. SYMBOLS has no effect otherwise.

NOSYMBOLS

The symbol table is not included in the list file created by

 

PRINT.

XREF

A symbol-cross-reference file is requested. An

 

intermediate file is output to ASXREF.TMP and the cross-

 

reference listing to the file created by PRINT.

NOXREF

Symbol-cross-reference file generation is suppressed.

MACROFILE(drive)

The macro definition file is directed to the specified drive.

 

If no drive is specified, the drive where the source file

 

resides is used. Your Intellec system must have a 48K

 

memory if MACROFILE is specified as the assembler runs

 

in nonoverlay mode. MACROFILE also adds the macro

 

reserved words (MACRO, LOCAL, etc.) to the reserved

 

word list.

NOMACROFILE

No macro temporary files are created. If your source file

 

contains macros, all definitions and calls cause errors.

 

This control lets the assembler run on a 32K-memory

 

Intellec system in overlay mode.

PAGELENGTH(n)

Each listfile page is "n" lines long, where un" mustbe at

 

least 12 and includes 3 blank lines at the top of the page, 3

 

blank lines at the bottom of the page, and any page

 

headings specified. If "n" is ~11, PAGELENGTH is set to

 

12. The default value is 66.

 

Note that 3 blank lines are issued to reach the next "top-

 

of- page" as opposed to issuing form feeds to reach the

 

physical "top-of-form.',

PAGEWIDTH(n)

Each list file line can be up to "nil characters long, where

 

"n" must be in the range 72<n<132. Lines exceeding the

 

page width are continued in column 25 of the following line

 

(but lines >132 characters are truncated to 132). The

 

default page width is 120.

2-3

Image 13
Contents ISIS-II 8080/8085 Macro Assembler Operatorsmanual Scope Prefacei Page Contentsi Page ISIS-II Assembler Environment Chapter Assembler OverviewInput/Output Files Assembler Files Symbol-Cross-Reference FilePage Chapter ISIS·IIAssembler Controls Primary Controls General Controls ISIS-II Assembler Control Lines Page Activation Sequence Sample AssemblyAsmbo 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 Cross-Reference Output Line Symbol-Cross-Reference ListingChapter PL/M Linkage Conventions Page Relocatable Programs Absolute ProgramsPage Error Codes Error Detection and ReportingError 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.