Tiny BASIC explained

Tiny BASIC
Paradigms:-->
Designers:-->
Released:1975
Programming Language:IL (Interpretive Language)
License:Public domain
File Formats:-->
Dialects:Denver Tiny BASIC, Enhanced 6800 Tiny BASIC, MINOL, National Industrial Basic Language, Palo Alto Tiny BASIC, 6800 Tiny BASIC, TBI68K, Tiny BASIC Extended
Influenced By:Dartmouth BASIC, 8008 BASIC
Influenced:Astro BASIC, Atari BASIC, Level I BASIC

Tiny BASIC is a family of dialects of the BASIC programming language that can fit into 4 or fewer KBs of memory. Tiny BASIC was designed by Dennis Allison and the People's Computer Company (PCC) in response to the open letter published by Bill Gates complaining about users pirating Altair BASIC, which sold for $150. Tiny BASIC was intended to be a completely free version of BASIC that would run on the same early microcomputers.

Tiny BASIC was released as a specification, not an implementation, published in the September 1975 issue of the PPC newsletter. The article invited programmers to implement it on their machines and send the resulting assembler language implementation back for inclusion in a series of three planned newsletters. Li-Chen Wang, author of Palo Alto Tiny BASIC, coined the term "copyleft" to describe this concept. The community response was so overwhelming that the newsletter was relaunched as Dr. Dobb's Journal, the first regular periodical to focus on microcomputer software. Dr. Dobb's lasted in print form for 34 years and then online until 2014, when its website became a static archive.

The small size and free source code made these implementations invaluable in the early days of microcomputers in the mid-1970s, when RAM was expensive and typical memory size was only 4 to 8 KB. While the minimal version of Microsoft's Altair BASIC would also run in 4 KB machines, it left only 790 bytes free for BASIC programs. More free space was a significant advantage of Tiny BASIC. To meet these strict size limits, Tiny BASIC dialects generally lacked a variety of features commonly found in other dialects, for instance, most versions lacked string variables, lacked floating-point math, and allowed only single-letter variable names.

Tiny BASIC implementations are still used today, for programming microcontrollers such as the Arduino.

History

Altair BASIC

The earliest microcomputers, like the MITS Altair 8800, generally had no built-in input/output (I/O) beyond front-panel switches and LED lamps. Useful work generally required the addition of an I/O expansion card and the use of some form of terminal. At the time, video-based terminals were very expensive, costing much more than the computer, so many users turned to mechanical devices like the Teletype Model 33. The Model 33, like most teleprinters of the era, included a tape punch system intended to allow operators to pre-record their messages and then play them at "high speed", faster than most individuals could type the message live. For the early microcomputers, this provided a convenient computer data storage format, allowing the users to write programs to paper tape and distribute them to other users.[1]

The Homebrew Computer Club met for the first time in March 1975, and its members soon used the meetings to swap software on punched tape. At the June meeting, a tape containing a pre-release version of Altair BASIC disappeared. The tape was given to Steve Dompier, who passed it on to Dan Sokol, who had access to a high-speed tape punch. At the next meeting, 50 copies of Altair BASIC on paper tape appeared in a cardboard box. When Ed Roberts, founder of MITS, learned of this, he stated "Anyone who is using a stolen copy of MITS BASIC should identify himself for what he is, a thief."[2] Bill Gates made this more formal, writing "An Open Letter to Hobbyists", complaining that "As the majority of hobbyists must be aware, most of you steal your software."

Tiny BASIC

The complaint was not well received. Among the many responses, Bob Albrecht, another Homebrew member and founder of the People's Computer Company (PCC), felt the best response would be to produce their own BASIC that was completely free to use by anyone. He approached Dennis Allison, a member of the Computer Science faculty at Stanford University, to write a specification for a version of BASIC that would fit in 2 to 3 kilobytes of memory. To aid porting, the design was based on an intermediate language (IL), an interpreter for the interpreter, which meant only a small portion of the total code had to be ported.

Allison's initial design was published in the September 1975 edition of the PCC newsletter, along with an Intel 8080 version of the IL interpreter. The article called on programmers to implement the design on their computer and send the resulting assembly language version back to the PCC. They stated their plans to publish three special newsletters containing these user-submitted versions, along with bug fixes, programs written in the new BASIC, and suggestions and enhancements. The concept gained further notice when it was republished in the January 1976 edition of the ACM Special Interest Group on Programming Languages.[3] Submissions poured in. Among the notable early versions was Tiny BASIC Extended by Dick Whipple and John Arnold which ran in 3K of RAM, added FOR...NXT loops, and allowed a single numeric array. They avoided the use of the IL and wrote it directly in machine code, using octal.

The first of the three planned newsletters, with the title "Dr. Dobb's Journal of Computer Calisthenics & Orthodontia, Running Light Without Overbyte", was published in January 1976.[4] It starts with a note from Albrecht, under the penname "the dragon", suggesting that three editions would not be enough, and asked the readers if they would like to see it continue. It also reprinted the original article on Tiny BASIC from PCC, included the complete listing of Extended TB, and included a number of small BASIC programs including tips-and-tricks from Allison. Response to the first issue was so impressive that the introduction to the second issue stated they had already decided to continue publishing the new newsletter under the simplified name Dr. Dobb's Journal. Over the next several issues, additional versions of the language were published, and similar articles began appearing in other magazines like Interface Age.

Spread

By the middle of 1976, Tiny BASIC interpreters were available for the Intel 8080, the Motorola 6800 and MOS Technology 6502 processors. This was a forerunner of the free software community's collaborative development before the internet allowed easy transfer of files, and was an example of a free software project before the free software movement.[5] Computer hobbyists would exchange paper tapes, cassettes or even retype the files from the printed listings.[6]

Jim Warren, editor of Dr. Dobb's, wrote in the July 1976 ACM Programming Language newsletter about the motivations and methods of this successful project. He started with this: "There is a viable alternative to the problems raised by Bill Gates in his irate letter to computer hobbyists concerning 'ripping off' software. When software is free, or so inexpensive that it's easier to pay for it than to duplicate it, then it won't be 'stolen'." The Bill Gates letter was written to make software into products. The alternative method was to have an experienced professional do the overall design and then outline an implementation strategy. Knowledgeable amateurs would implement the design for a variety of computer systems. Warren predicted this strategy would be continued and expanded.[6]

The May 1976 issue of Dr. Dobbs had Li-Chen Wang's Palo Alto Tiny BASIC for the 8080. The listing began with the usual title, author's name and date but it also had "@COPYLEFT ALL WRONGS RESERVED".[7] A fellow Homebrew Computer Club member, Roger Rauskolb, modified and improved Li-Chen Wang's program and this was published in the December 1976 issue of Interface Age magazine.[8] Roger added his name and preserved the COPYLEFT Notice.

Description

Basic concepts

Tiny BASIC was designed to use as little memory as possible, and this is reflected in the paucity of features as well as details of its interpreter system. Early microcomputers lacked the RAM and secondary storage for a BASIC compiler, which was more typical of timesharing systems.

Like most BASICs of the era, Tiny Basic was interactive with the user typing statements into a command line. As microcomputers of the era were often used with teletype machines or "dumb" terminals, direct editing of existing text was not possible and the editor instead used takeout characters, often the backslash, to indicate where the user backed up to edit existing text.

If the user typed a statement into the command line the system examined it to see if it started with a number. If it did not, the line was immediately parsed and operated on, potentially generating output via . This was known as "direct mode".

If the line was entered with a leading number, the number was converted from decimal format, like "50", and converted to a 8-bit value, in this case, hexadecimal. This number was used as an index into an array-like storage area where the rest of the line was stored in exactly the format it was typed. When the user typed into the command line the system would loop over the array, convert the line number back to decimal format, and then print out the rest of the text in the line.

When a program was present in memory and the user types in the command, the system enters "indirect mode". In this mode, a pointer is set to point to the first line of the program, for instance, 10 . The original text for that line is then retrieved from the store and run as if the user had just typed it in direct mode. The pointer then advances to the next line and the process continues.

Formal grammar

The grammar is listed below in Backus–Naur form, almost exactly as it was specified in the Design Note.[9] In the listing, an asterisk ("*") denotes zero or more of the object to its left except for the first asterisk in the definition of "term", which is the multiplication operator; parentheses group objects; and an epsilon ("ε") signifies the empty string. As is common in computer language grammar notation, the vertical bar ("|") distinguishes alternatives, as does their being listed on separate lines. The symbol "CR" denotes a carriage return (usually generated by a keyboard's "Enter" key). A BREAK from the console will interrupt execution of the program. line ::= number statement CR | statement CR statement ::= PRINT expr-list IF expression relop expression THEN statement GOTO expression INPUT var-list LET var = expression GOSUB expression RETURN CLEAR LIST RUN END expr-list ::= (string|expression) ((string|expression))* var-list ::= var (var)* expression ::= (+|-|ε) term ((+|-) term)* term ::= factor ((*|/) factor)* factor ::= var | number | (expression) var ::= A | B | C ... | Y | Z number ::= digit digit* digit ::= 0 | 1 | 2 | 3 | ... | 8 | 9 relop ::= < (>|=|ε) | > (<|=|ε) | =

string ::= " (|!|#|$ ... -|.|/|digit|: ... @|A|B|C ... |X|Y|Z)* "

Note that string wasn't defined in the Design Note.

This syntax, as simple as it was, added one innovation: and could take an expression rather than just a line number, providing an assigned GOTO[10] rather than the switch statement of the, a structure then supported in HP Time-Shared BASIC and predating . The syntax allowing (as opposed to just a line number to branch to) was not yet supported in Dartmouth BASIC at this time but had been introduced by Digital[11] and copied by Microsoft.

Implementation in a virtual machine

The Design Note specified a virtual machine, in which the Tiny BASIC interpreter is itself run on a virtual machine interpreter. The designer's idea to use an application virtual machine goes back to Val Schorre (with META II, 1964) and Glennie (Syntax Machine). The choice of a virtual machine approach economized on memory space and implementation effort, although the BASIC programs run thereon were executed somewhat slowly.[12]

Dialects that used the virtual machine included Tiny BASIC Extended, Tom Pittman's Tiny BASIC[13] and NIBL. Other dialects such as Denver Tiny BASIC (DTB) and Palo Alto Tiny BASIC were direct interpreters. Some programmers, such as Fred Greeb with DTB, treated the IL (Interpretive Language) program as pseudocode for the algorithm to implement in assembly language; Denver Tiny BASIC did not use a virtual machine, but it did closely follow the IL program.

This is a representative excerpt from the 120-line IL program:S1: TST S3,'GO' ;GOTO OR GOSUB? TST S2,'TO' ;YES...TO, OR...SUB CALL EXPR ;GET LABEL DONE ;ERROR IF CR NOT NEXT XFER ;SET UP AND JUMPS3: TST S8,'PRINT' ;PRINT.

A common pattern in the program is to test for a keyword or part of a keyword, then act on that information. Each test is an assertion as to what is next in the line buffer. If the assertion fails, control jumps to a subsequent label (usually looking for a new keyword or token). Here the system advances its buffer cursor over any spaces and tests for and if it fails to find it then jumps to line . If it finds it, execution continues with the next IL command. In this case, the system next tests for, skipping to line if it fails (a test for, to see if this is instead a command). If it passes, control continues; in this case, calling an IL subroutine that starts at label, which parses an expression. In Tiny BASIC, (a computed GO TO) is as legal as and is the alternative to the ON-GOTO of larger BASIC implementations. The subroutine pushes the result of the expression onto the arithmetic stack (in this case, the line number). verifies no other text follows the expression and gives an error if it does. pops the number from the stack and transfers execution (GOes TO) the corresponding line number, if it exists.

The following table gives a partial list of the 32 commands of the virtual machine in which the first Tiny BASIC interpreter was written.[14]

If string matches the BASIC line, advance cursor over and execute the next IL instruction; if the test fails, execute the IL instruction at the label lbl
  • : Execute the IL subroutine starting at ; save the IL address following the CALL on the control stack
  • : Report a syntax error if after deleting leading blanks the cursor is not positioned to reach a carriage return
  • : Test value at the top of the AE stack to be within range. If not, report an error. If so, attempt to position cursor at that line. If it exists, begin interpretation there; if not, report an error.
  • : Continue execution of the IL at the label specified
  • : Return to the IL location specified at the top of the control stack
  • : Print characters from the BASIC text up to but not including the closing quotation mark
  • : Print number obtained by popping the top of the expression stack
  • : Insert spaces to move the print head to next zone
  • : Output a CRLF[15] to the printer
  • Tom Pittman, discussing the IL, says: "The TINY BASIC interpreter was designed by Dennis Allison as a recursive descent parser. Some of the elegant simplicity of this design was lost in the addition of syntactical sugar to the language but the basic form remains. The IL is especially suited to Recursive Descent parsing of TINY BASIC because of the general recursive nature of its procedures and the simplicity of the TINY BASIC tokens. The IL language is effectively optimized for the interpretation of TINY. Experience has shown that the difficulty of adding new features to the language is all out of proportion with the nature of the features. Usually it is necessary to add additional machine language subroutines to support the new features. Often the difficulty outweighs the advantages."[16]

    Deviations from the design

    Defining Tiny BASIC for the Homebrew Computer Club, Pittman wrote, "Tiny BASIC is a proper subset of Dartmouth BASIC, consisting of the following statement types only: LET, PRINT, INPUT, IF, GOTO, GOSUB, RETURN, END, CLEAR, LIST, RUN. Arithmetic is in 16-bit integers only with the operators + - * / and nested parentheses. There are only the 26 single letter variable names A, B, ...Z, and no functions. There are no strings or arrays... Tiny BASIC specifies line numbers less than 256."[17] He then went on to describe his implementation: "This language has been augmented to include the functions RND, USR, and PEEK and POKE, giving the user access to all his system components in the 6800 from the BASIC program."

    Many implementers brought their own experiences with HP Time-Shared BASIC or DEC BASIC-PLUS to their designs and relaxed the formal Tiny BASIC language specification. Of the seven prominent implementations published by 1977:

    As an alternative to tokenization, to save RAM, TBX,[18] DTB,[19] and MINOL[20] truncated keywords: for, for, for . The full, traditional keywords were not accepted. In contrast, PATB allowed accepted traditional keywords but also allowed any keyword to be abbreviated to its minimal unique string, with a trailing period. For instance, could be typed, although and other variations also worked. This system was retained in Level I BASIC for the TRS-80, which used PATB, and was also later found in Atari BASIC and the BASIC of various Sharp Pocket Computers.[21]

    Dialects

    The most prominent dialects of Tiny BASIC were the original Design Note, Tiny BASIC Extended, Palo Alto Tiny BASIC, and 6800 Tiny BASIC. However, many other versions of Tiny BASIC existed.

    List of prominent dialects

    Tiny BASIC was first published in a newsletter offshoot of the People's Computer Company, a newsletter which became Dr. Dobb's Journal, a long-lived computing magazine. About ten versions were published in the magazine.

    Prominent dialects of Tiny BASIC (in Dr. Dobb's Journal)
    Date published Issue Dialect Author Processor Size
    December 1975 1[22] Design Note Dennis Allison
    February 1976 2 Tiny BASIC Extended (TBX) Dick Whipple & John Arnold 2.9K
    March 1976 3 Denver Tiny BASIC (DTB) Fred Greeb 8080 2.75K
    March 1976 3[23] 6800 Tiny BASIC (6800TB) Tom Pittman 2K[24]
    April 1976 4 MINOL Eric T. Mueller 8080 1.75K
    May 1976 5[25] Palo Alto Tiny BASIC (PATB) Li-Chen Wang 8080 1.77K
    November 1976 10[26] National Industrial Basic Language (NIBL) Mark Alexander & Steve Leininger 4K
    October 1980 49[27] Enhanced 6800 Tiny BASIC Robert Hudson 6800
    February 1985 100[28] TBI68K Gordon Brandly
    January 2006 351[29] Return of Tiny BASIC Tom Pittman (C)

    TBX was also known as Texas Tiny BASIC.[30]

    Both SCELBAL[31] and 6800 Tiny BASIC were announced in the magazine but did not publish their source code.

    Palo Alto Tiny BASIC

    Palo Alto Tiny BASIC
    Paradigms:-->
    Designers:-->
    Developer:Li Chen Wang
    Released:1976
    License:Public domain
    File Formats:-->
    Dialects:3K Control Basic
    Influenced By:Tiny BASIC Design Note, Tiny BASIC Extended
    Influenced:Astro BASIC, Level I BASIC, Sharp PC-1211 BASIC

    One of the most popular of the many versions of Tiny BASIC was Palo Alto Tiny BASIC, or PATB for short, by Li-Chen Wang. PATB first appeared in the May 1976 edition of Dr. Dobbs, written in a custom assembly language with non-standard mnemonics. This led to further ports that worked with conventional assemblers on the 8080.[21] The first version of the interpreter occupied 1.77 kilobytes of memory and assumed the use of a Teletype Machine (TTY) for user input/output. An erratum to the original article appeared in the June/July issue of Dr. Dobb's (Vol. 1, No 6). This article also included information on adding additional I/O devices, using code for the VDM video display by Processor Technology as an example.

    Wang was one of the first to use word copyleft. In Palo Alto Tiny BASIC's distribution notice, he had written "@COPYLEFT ALL WRONGS RESERVED".[32] Tiny BASIC was not distributed under any formal form of copyleft distribution terms, but was presented in a context where source code was being shared and modified. In fact, Wang had earlier contributed edits to Tiny BASIC Extended before writing his own interpreter.[18] He encouraged others to adapt his source code and publish their adaptions, as with Roger Rauskolb's version of PATB published in Interface Age.[8] He also published a third version in PCC's Reference Book of Personal and Home Computing.[33]

    One of the most notable changes in PATB is the addition of the FOR...NEXT loop. In the original TB, loops could only be implemented using and . As in Microsoft BASIC, the upper and lower bounds of the loop were set on loop entry, and did not change during the loop, so if one of the bounds was based on a variable expression; changing the variable did not change the bound. The modifier was optional, as in MS.[21]

    Another significant change was the ability to place several statements on a single line. For reasons not explained, PATB used the semicolon to separate statements, rather than the already common colon .

    Other changes include the addition of a single numeric array, with the variable name, in addition to, and the use of for not-equals in comparisons, as opposed to .

    PATB used words for error messages instead of numbers. To reduce the amount of memory required, there were only three messages and they consisted of single words. The system would respond with for syntax errors, for run-time errors like GOTOs to a line that didn't exist or numeric overflows, and for out-of-memory problems.[21]

    Wang also wrote a STARTREK program in his Tiny BASIC that appeared in the July 1976 issue of the People's Computer Company Newsletter.[34] [35]

    He later adapted the language into 3K Control Basic for Cromemco, adding variable names of the form letter-digit (e.g., A0 to Z9), logic functions (AND, OR, XOR), a CALL command to execute machine language routines, more PRINT-formatting options, and others (GET and PUT instead of PEEK and POKE; I/O port functions).[36]

    Palo Alto Tiny BASIC was adapted for many other implementations, including Level I BASIC (1977), BASIC for the Sharp PC-1211 pocket computer (1980), and Astro BASIC (1982, by Jamie Fenton).[37]

    MINOL

    Written by a junior in high school, MINOL was the only implementation that didn't support the full Design Note, lacking operator precedence, having only three relops (<, =, #), omitting and . It only supported unsigned 8-bit precision (in contrast to signed 16-bit precision for every other implementation) and line numbers from 0 to 254.

    No spaces were permitted except in strings; returns a random number, before an expression loads a string at that address; returns to operating system. Memory was addressable as if it were a two-dimensioned array of high and low bytes (e.g., "(0,0)" to "(255,255)"); executes a machine language subroutine.[20]

    Miscellaneous dialects

    Many dialects appeared in various other publications.

    Inspired by PCC's call for Tiny BASICs, Robert Uiterwyk wrote MICRO BASIC 1.3 for the SWTPC 6800 system), which SWTPC published in the June 1976 issue of the SWTPC newsletter. Uiterwyk had handwritten the language on a legal tablet. He later expanded the language to 4K, adding support for floating point; this implementation was unique among BASIC interpreters by using Binary Coded Decimal to 9 digits of precision, with a range up to 1099, and by being published for free as a "Floppy ROM" magazine insert. An 8K version added string variables and trigonometry functions. Both the 4K and 8K versions were sold by SWTPC. In January, 1978, Uiterwyk sold the rights of the source code to Motorola.[38] [39]

    Thomas F. Waitman wrote a Tiny BASIC in 1976 for the Hewlett-Packard HP-2640 and HP-2645 terminals (which used the Intel 8008 and 8080 processors), which was published in the Hewlett-Packard Journal.

    Published in the December 1976 issue of Interface Age was LLL (Lawrence Livermore Laboratory) BASIC, the first draft of which was developed by Steve Leininger from Allison's specification before Leininger left National Semiconductor for Tandy Corporation. The final interpreter was developed by John Dickenson, Jerry Barber, and John Teeter at the University of Idaho on a contract with LLL. Taking 5K, it included a floating-point package, developed by David Mead, Hal Brand, and Frank Olken. The program was placed into the public domain by LLL, which developed the system under the auspices of theU.S. Energy Research and Development Administration.[40]

    4K BASICs

    Altair BASIC, 4K BASIC, could run within a 4 KB RAM machine, leaving only about 790 bytes free for program code.[41] [42] The Tiny BASIC initiative started in response to the $150 charge for Altair 4K BASIC.

    In 1975, Steve Wozniak joined the newly formed Homebrew Computer Club, which had fellow members Li-Chen Wang (Palo Alto Tiny BASIC) and Tom Pittman (6800 Tiny BASIC). Wozniak concluded that his machine would have to have a BASIC of its own, which would, hopefully, be the first for the MOS Technology 6502 processor. As the language needed 4 KB RAM, he made that the minimum memory for the design.[43] Integer BASIC was originally published on Compact Cassette in 1976.

    In 1977, Radio Shack (as it was known then) released their first computer, the TRS-80, a Z80 system with Level I BASIC in a 4 KB ROM. Tandy-employee Steve Leininger had written the first draft of the NIBL (National Industrial Basic Language) interpreter for the SC/MP while employed at National Semiconductor.[26] Unable to take that source code with him, he adapted Li-Chen Wang's Palo Alto Tiny BASIC for the original prototype of the TRS-80 Model I. He extensively revised the interpreter, adding floating-point support, simple black-and-white graphics, and statements.[44]

    Originally developed in 1979, Sinclair 4K BASIC, written by John Grant, used as its language definition the 1978 American National Standards Institute (ANSI) Minimal BASIC standard, but was itself an incomplete 4 KB implementation with integer arithmetic only.[45]

    Microcontroller dialects

    Tiny BASIC implementations have been adapted for processor control and for microcontrollers such as the Arduino:

    Later implementations

    In 2002, Emmanuel Chailloux, Pascal Manoury and Bruno Pagano published a Tiny BASIC (lacking /) in Developing Applications with Objective Caml as an example Objective Caml application.[50]

    In 2013, Alex Yang published an implementation in Python.[51]

    In 2019, Sergey Kuznetsov published a version in Ruby.[52]

    Also in 2019, Oscar Toledo Gutierrez published bootBASIC, which fits in the 512 bytes of the boot sector of an 8086/8088 machine, making it the smallest BASIC implementation yet. To accomplish this, the language drops relational operators (IF statements work on nonzero values), limits lines of code to 19 characters or less, and doesn't update the display when backspace is pressed.[53] Additionally, it lacks GOSUB and RETURN but does include a RND function (without arguments, returning a value between 0 and 255).[54] The language uses an array to store program lines, requiring 20,000 bytes to do so.[55]

    In 2023, Gordon Henderson published a Tiny Basic implementation in 6502 assembler. It is influenced by NIBL and can run in as little as 3.5KB of ROM requiring at least 1KB of RAM for data and program storage. It supports DO/UNTIL, FOR/NEXT, simple strings and memory peek/poke (byte or 16-bit word), GOSUB/RETURN, CALL, RND with facilities for hexadecimal input and output.[56]

    Dialects compared

    The following table compares the language feature of Tiny BASIC implementations against other prominent BASICs that preceded them.

    Comparison of BASIC Implementations – Tiny BASICs and Other BASICs
    Dialect Programmer(s) Processor Type INPUT LET PRINT GOTO IF ...THEN GOSUB RETURN END RUN LIST CLEAR NEW REM FOR/NEXT READ / DATA / RESTORE Added BASIC commands Customizations Expressions relop Functions RND Memory Function Line numbers Statement delimiter Errors Precision Arithmetic Variables Arrays Strings
    (Dartmouth students) GE-225 Compile-and-go [!] LET var = expression PRINT expr-list GO TO number IF expression relop expression THEN line-number GOSUB number RETURN END RUN LIST--start NEW [prompts for program name] REM FOR / TO / STEP / NEXT READ, DATA STOP precedence, ^ < <= = >= > <> INT, SIN, COS, TAN, ATN, EXP, LOG, ABS, SQR, DEF FN RND(0) 0..1 1 to 99999 22 defined 9 digits ±999,999,999; E notation base 2 -256 to +255 (E±76). A–Z, A0–Z9 DIM (one letter name, two dimensions); if omitted, assumed to go from 0 to 10; up to 1500 elements across all arrays (added in version 4)
    (DEC staff) PDP-8 Compile-and-go INPUT var-list LET var = expression PRINT expr-list GO TO number IF expression relop expression [THEN/GO TO] line-number GOSUB number RETURN END RUN LIST (first (last)) NEW [prompts for program name] REM FOR / TO / STEP / NEXT READ, DATA, RESTORE STOP, OLD, SAVE, UNSAVE DELETE (first (last)), BYE precedence, ^ < <= = >= > <> INT, SGN, SIN, COS, TAN, ATN, EXP, LOG, ABS, SQR, DEF FN RND(0) 0..1 1 to 2045 23 defined ±134,217,727; 14E-38A–Z, AA–Z9 DIM (one letter name, two dimensions)
    Alfred Weaver, Michael Tindall, Ronald Danielson 8008 Interpreter INPUT * LET var = formula PRINT / * GO TO number IF expression THEN line-number GOSUB number RETURN END RUN REM FOR / TO / STEP / NEXT DEF FN, STOP precedence, ^ < <= = >= > # AND OR NOT FNA..Z, SIN, COS, LOG, SQR, EXP, ATN 0 to 999 4-byte mantissa and 1-byte exponent [Datapoint 2200 floating-point arithmetic package] A–Z, A0–Z9 DIM (one letter name, three dimensions)
    Bill Gates, Paul Allen, Monte Davidoff 8080 Interpreter INPUT ("string",) var-list (LET) var = expression PRINT expr-list GOTO number IF expression THEN line-number/statement GOSUB number RETURN END RUN LIST (start) NEW REM FOR / TO / STEP / NEXT READ, DATA, RESTORE STOP precedence < <= = >= > <> ABS, INT, SGN, SQR, TAB, USR RND(X) <0, new using X as seed; =0, repeat; >0, next 1 to 65535 12 defined 40-bit operand floating DIM (one dimension)
    Dennis Allison Interpreter INPUT var-list LET var = expression PRINT expr-list GOTO expression IF expression relop expression THEN statement GOSUB expression RETURN END RUN LIST [eq. to NEW] precedence < <= = >= > <> >< 1 to 255 8 defined 16-bit ± 32767 A–Z
    Dick Whipple & John Arnold 8080 Interpreter IN (LET) var = expression PR expr-list GO TO IF expression [no THEN] statement GO SUB RET END RUN LST (first (last)) NEW FOR-NXT (no STEP) DTA (array LET) precedence < <= = >= > <> >< TB spaces in print RN (random 0-10000) SZE 1 to 65535 $ 14 defined 16-bit ± 32767 A–Z DIM, 1- or 2-dimensions, 255x255 max
    Fred Greeb 8080 Interpreter IN (LET) var = expression PR expr-list GOTO IF expression [no THEN] statement GOSUB RET END RUN LIST (first last) [eq. to NEW] TAPE [SAVE], LOAD CLRS [CLS] precedence < <= = >= > <> >< RND(0), RND(1) SIZE 2 to 255 20 defined 16-bit ± 32767 A–Z, A1 to A6 to Z6 DIM, 1 dimension
    Tom Pittman 6800 Interpreter INPUT (expression) var-list LET var = expression PRINT expr-list GOTO expression IF expression relop expression THEN statement GOSUB expression RETURN END RUN LIST (first last) [eq. to NEW] REM precedence < <= = >= > <> >< USR RND 1 to 65535 53 defined 16-bit ± 32767 A–Z
    Eric T. Mueller 8080 Interpreter IN [{{Codett|code=GOTO 0|lang=basic}} jumps back to start of direct statement] END RUN LIST CLEAR [only variables] NEW < = # 1 to 254 6 defined 8-bit 0 to 255 A–Z (H,L) memory location single char
    Li-Chen Wang 8080 Interpreter INPUT [(expression) var]* (LET) var = expression PRINT expr-list GOTO expression IF expression [no THEN] statement GOSUB expression RETURN STOP RUN LIST (start) NEW REM FOR / TO / STEP / NEXT STOP precedence < <= = >= > # ABS RND SIZE 1 to 32767 3 defined 16-bit ± 32767 A–Z @(1 array of 1 dimension)
    Mark Alexander & Steve Leininger SC/MP Interpreter INPUT ($)var (LET) var = expression PR/PRINT expr-list GOTO expression IF expression (THEN) statement GOSUB expression RETURN END RUN LIST (start) CLEAR [variables & stack] NEW REM FOR / TO / STEP / NEXT DO/UNTIL Memory addressing (@ [PEEK/POKE], STAT, PAGE) precedence < <= = >= > <> MOD, AND, OR, NOT, RND(A,Z) TOP 0 to 32767 13 four-char defined 16-bit ± 32767 A–Z memory addressing
    Steve Leininger Z80 Interpreter INPUT (#digit) [(expression) var]* (LET) var = expression PRINT (#digit) expr-list GOTO number IF expression THEN statement GOSUB number RETURN END RUN (start) LIST (start) NEW REM FOR / TO / STEP / NEXT READ, DATA, RESTORE STOP, CONT, ON-GOTO/GOSUB CLOAD, CSAVE, CLS, SET, RESET precedence < <= = >= > <> >< ABS, INT, MEM, POINT(X,Y) RND MEM 1 to 32767 3 defined 16-bit ± 32767 A–Z A(1 array of 1 dimension)
    Robert Uiterwyk 6800 Interpreter INPUT var-list (LET) var = expression PRINT expr-list GOTO expression IF expression relop expression THEN statement GOSUB expression RETURN END RUN LIST (first (last)) NEW FOR/TO/NEXT (no STEP) TAB precedence < <= = >= > <> >< RND, SIZE RND [returns 1-32762] SIZE (statement that prints bytes used and bytes free) 1 to 65535 17 defined 16-bit [later BCD!] ± 32767 A–Z DIM (two dimensions, max size of 255)
    Mark Arnold & Nat Wadsworth 8008 Interpreter INPUT var-list (LET) var = expression PRINT expr-list GOTO number IF expression relop expression GOTO line-number THEN statement GOSUB number RETURN END RUN LIST SCR[atch] REM FOR / TO / STEP / NEXT SAVE, LOAD UDF [USR] precedence, ^ < <= = >= > <> INT, SGN, ABS, SQR, CHR [usable only in PRINT], TAB RND(0) 0..1 1 to 999999 18 defined 32-bit operand floating or fixed point ±134,217,727; 14E-38DIM (one letter name, one dimension; up to 4 arrays of up to 64 entries in total)
    Steve Wozniak 6502 Interpreter INPUT ("string",) var-list (LET) var = expression PRINT expr-list GOTO expression IF expression relop expression THEN line-number/statement GOSUB expression RETURN END RUN (start) LIST (first (last)) SCR REM FOR / TO / STEP / NEXT AUTO, DEL, POKE TAB (command), CALL precedence < <= = >= > <> # AND OR NOT MOD SGN, ABS, PEEK, LEN RND(X) 0..X (or X..0!) HIMEM, LOMEM 1 to 32767 [early version, then :] 16 defined 16-bit ± 32767 A–Z followed by any number of alphanumeric DIM (one dimension) dimensioned
    (University of Idaho staff) 8080 Interpreter INPUT var-list (LET) var = expression PRINT expr-list GO TO number IF expression relop expression (THEN) statement GO SUB number RETURN END RUN LIST SCR REM FOR/TO/NEXT (no STEP) STOP CALL, GET, PUT precedence < <= = >= > <> >< 0 to 32767 14 defined 32-bit operand floating point A–Z, A0–Z9 DIM (integers only, one letter name, one dimension, max size of 255)
    John GrantZ-80 Interpreter INPUT var LET var = expression PRINT expr-list GO TO number IF expression THEN statement GO SUB number RETURN RUN (number) LIST CLEAR NEW REM FOR/TO/NEXT (no STEP) STOP POKE precedence < = > ABS, CHR$, CODE, PEEK, RND, STR$, TL$, USR RND, RANDOMISE 1 to 9999 10 defined 16-bit integer 16-bit integer A–Z followed by any number of alphanumeric DIM A-Z (integers only, one letter name, one dimension, max size of 255) A$-Z$

    See also

    References

    Bibliography

    External links

    Notes and References

    1. Web site: Don. Lancaster. TV Typewriter Cookbook. https://ghostarchive.org/archive/20221009/https://www.tinaja.com/ebooks/tvtcb.pdf . 2022-10-09 . live. 1976. 210–211.
    2. Letter from the President . Computer Notes . Roberts . H. Edward . 1 . 5 . 3–4 . MITS . Albuquerque NM. . October 1975 . dead . https://web.archive.org/web/20120323162008/http://startup.nmnaturalhistory.org/gallery/notesViewer.php?ii=75_10&p=3 . March 23, 2012.
    3. Allison . Dennis . Design notes for TINY BASIC . SIGPLAN Notices . 11 . 7 . 25–33 . ACM . July 1976 . 10.1145/987491.987494 . 18819472 . free .
    4. . TB Code Sheet . 1 . 1 . December 1975 .
    5. Web site: Open hardware: How and why it works. . The open software movement was founded by Dennis Allison in his release of Tiny BASIC in 1975.
    6. Warren . Jim C. . Jim Warren (computer specialist). Correspondence . SIGPLAN Notices . 11 . 7 . 1–2 . ACM . 0362-1340 . July 1976.
    7. Wang . Li-Chen . Li-Chen Wang . Palo Alto Tiny BASIC . . 1 . 5 . 12–25 . May 1976. Source code begins with the following six lines.
      TINY BASIC FOR INTEL 8080
      VERSION 1.0
      BY LI-CHEN WANG
      10 JUNE, 1976
      @COPYLEFT
      ALL WRONGS RESERVED
      The June date in the May issue is correct. The magazine was behind schedule, the June and July issues were combined to catch up.
    8. Rauskolb . Roger . Dr. Wang's Palo Alto Tiny BASIC . Interface Age . 2 . 1 . 92–108 . December 1976. The source code begins with the following nine lines:
      ;*********************************
      ;
      ;    TINY BASIC FOR INTEL 8080
      ;          VERSION 2.0
      ;        BY LI-CHEN WANG
      ;     MODIFIED AND TRANSLATED
      ;       TO INTEL MNEMONICS
      ;        BY ROGER RAUSKOLB
      ;         10 OCTOBER,1976
      ;           @COPYLEFT
      ;      ALL WRONGS RESERVED
      ;
      ;*********************************
    9. Build Your Own BASIC . Dennis . Allison . Dr. Dobb's Journal . 1 . 1 . 1976 . 9.
    10. Quick Reference Guide for Tiny BASIC . Dennis . Allison . Dr. Dobb's Journal . 1 . 1 . 1976 . 6.
    11. Book: BASIC-PLUS Language Manual. Digital Equipment Corporation. 1972. Maynard, Massachusetts. PDF. 3–13. CITEREFPLUS1972.
    12. Allen. Dennis. TINY BASIC. People's Computer Company. 4. 3.
    13. Web site: Veit. Holger. Tom Pittman's 6800 tiny BASIC. 2 May 2017.
    14. Dr. Dobb's Journal, Volume 1, Number 1, 1976, p. 12.
    15. The CRLF there symbolizes a carriage return followed by a line feed.
    16. Web site: Tiny BASIC Experimenter's Kit . Pittman . Tom . August 9, 2020.
    17. Web site: TINY BASIC 6800 . https://ghostarchive.org/archive/20221009/https://archive.computerhistory.org/resources/access/text/2015/02/102740021-05-14-acc.pdf . 2022-10-09 . live. 13 Aug 2020.
    18. . Tiny BASIC Extended . 1 . 2 . February 1976.
    19. . Denver Tiny BASIC . 1 . 3 . March 1976.
    20. . MINOL . 1 . 4 . April 1976.
    21. Roger . Rauskolb . Dr. Wang's Palo Alto Tiny BASIC . Interface Age . December 1976 . 92–108 . https://ghostarchive.org/archive/20221009/http://www.jk-quantized.com/experiments/8080Emulator/TinyBASIC-2.0.pdf . 2022-10-09 . live.
    22. . Design Note . 1 . 1 . December 1975.
    23. . 6800 Tiny BASIC . 1 . 3 . March 1976.
    24. Web site: TINY BASIC User Manual+.
    25. Wang . Li-Chen . Li-Chen Wang . Palo Alto Tiny BASIC . . 1 . 5 . 12–25 . May 1976.
    26. . NIBL . 1 . 10 . November 1976.
    27. . Enhanced & Modified 6800 Tiny BASIC . October 1980.
    28. . TBI68K . February 1985.
    29. . Return of Tiny BASIC . January 2006.
    30. Texas Tiny BASIC (TBX) Marries TV-Cassette Operating System (TVCOS) . . 1 . 5 . 28–31 . May 1976.
    31. Dr. Dobb's Journal . February 1976 . SCELBAL – A Higher Level Language for 8008/8080 Systems . Mark . Arnold . Nat . Wadsworth . 30–53.
    32. Wang. Li-Chen. Li-Chen Wang. May 1976. Palo Alto Tiny BASIC. Dr. Dobb's Journal of Computer Calisthenics & Orthodontia, Running Light Without Overbyte. 1. 5. 12–25. (NB. Source code begins with the following six lines. "TINY BASIC FOR INTEL 8080; VERSION 1.0; BY LI-CHEN WANG; 10 JUNE, 1976; @COPYLEFT; ALL WRONGS RESERVED". The June date in the May issue is correct. The magazine was behind schedule, the June and July issues were combined to catch up.)
    33. Book: McCabe . Dwight [editor] . PCC's Reference Book of Personal and Home Computing . July 1, 1977 . People's Computer Company . Menlo Park, CA . 0-918790-02-6 . 248 . 1st.
    34. Web site: People's Computer Company. https://ghostarchive.org/archive/20221009/https://archive.computerhistory.org/resources/access/text/2017/09/102661095/102661095-05-v5-n1-acc.pdf . 2022-10-09 . live. 25 December 2019.
    35. Web site: Turnbull. Pete. Startrek.asc. 25 December 2019.
    36. Web site: 3K Control Basic Instruction Manual . Cromemco . 2013-02-18 . dead . https://web.archive.org/web/20131222220843/http://www.dunnington.u-net.com/public/Cromemco/Cromemco%203K%20Basic%20Instruction%20Manual.PDF . 2013-12-22 .
    37. Book: Ainsworth . Dick . Astro BASIC . 1982 . Astrocade, Inc. . 3.
    38. Web site: Robert Uiterwyk's BASIC.
    39. Web site: Robert Uiterwyk's Micro Basic.
    40. Web site: Part 1 Of LLL 8080 BASIC Interpreter. https://ghostarchive.org/archive/20221009/http://www.bitsavers.org/pdf/interfaceAge/197612/110-124.pdf . 2022-10-09 . live .
    41. Web site: 4 Altair Language Systems . Altair BASIC.
    42. Book: Altair BASIC . https://ghostarchive.org/archive/20221009/http://www.virtualaltair.com/virtualaltair.com/PDF/AltairBasic_1275.pdf . 2022-10-09 . live . 25 August 1975 . MITS.
    43. Web site: Steven . Wozniak . How Steve Wozniak Wrote BASIC for the Original Apple From Scratch . Gizmodo . 1 May 2014.
    44. Book: Welsh . David . Welsh . Theresa . Priming the Pump: How TRS-80 Enthusiasts Helped Spark the PC Revolution . 2007 . 7.
    45. Web site: ZX80 – 8K BASIC ROM UPGRADE.
    46. Web site: Ness. Stephen. XYBASIC. Ness Software. 4 August 2020.
    47. Web site: TinyBasicPlus. GitHub.
    48. Web site: It's here! Half-Byte Tiny Basic 2 for Arduino and compatibles. 27 November 2014.
    49. Web site: Running Tiny Basic on the Micro: Bit. 28 March 2020.
    50. Book: Chailloux . Emmanuel . Manoury . Pascal . Pagano . Bruno . Developing Applications with Objective Caml . 2002 . O'Reilly . France . 2841771210.
    51. Web site: aleozlx/tinybasic . . 2020-09-20.
    52. Web site: PaloAltoTinyBasic . 2020-09-20.
    53. Web site: Williams . Al . bootBASIC Fits Your Favorite Language in the Boot Sector . Hack A Day . 31 July 2019 . 26 March 2022.
    54. Web site: Gutierrez . Oscar Toledo . bootBASIC is a BASIC language in 512 bytes of x86 machine code. . Github . 26 March 2022.
    55. Book: Gutierrez . Oscar Toledo . Programming Boot Sector Games . 27 July 2019 . Lulu . 978-0-359-76262-0 . 155.
    56. Web site: Henderson . Gordon . 2023 . A Tiny Basic for the 6502 . Drogon Projects.