less_retarded_wiki/forth.md

# Forth

{ I'm a bit ashamed but I'm not really "fluent" at Forth, I just played around with it for a bit. Yes, I'm planning to get into it more after I do the other million things on my TODO list. Let me know if there is some BS, thank u <3 ~drummyfish }

Forth ("fourth generation" shortened to four characters due to technical limitations) is a very [elegant](beauty.md), extremely [minimal](minimalism.md) [stack](stack.md)-based [programming language](programming_language.md) that uses [postfix](notation.md) (reverse Polish) notation -- it is one of the very best programming languages ever conceived. Its vanilla form is super simple, it's much simpler than [C](c.md), it is cleverly designed and its compiler/interpreter can be made easily, giving it high practical freedom (i.e. not being practically controlled by any central organization). As of writing this the smallest Forth implementation, [milliforth](milliforth.md), has just **340 bytes** (!!!) of [machine code](machine_code.md), that's just incredible. Forth is used e.g. in [space](space.md) technology (e.g. [RTX2010](rtx2010.md), a radiation hardened space computer directly executing Forth) and [embedded](embedded.md) systems as a way to write efficient [low level](low_level.md) programs that are, unlike those written in [assembly](assembly.md), [portable](portability.md) (fun fact: there even exist computers directly running Forth in hardware). Forth was the main influence for [Comun](comun.md), the [LRS](lrs.md) programming language, it is also used by [Collapse OS](collapseos.md) and [Dusk OS](duskos.md) as the main language. In its minimalism Forth competes a bit with [Lisp](lisp.md).

**Forth is magical and may be the greatest thing yet conceived in computing**, it really looks like the pinnacle of programming. While in the world of "normal" programming languages you have to make tradeoffs, such as sacrificing performance for flexibility, Forth beats basically all traditional languages at EVERYTHING at once: [simplicity](minimalism.md), [beauty](beauty.md), memory compactness, flexibility, performance and [portability](portability.md). It is also more than just a programming language, it is just a system for computing and can serve for example as a [text editor](text_editor.md) or even an [operating system](os.md) (that is why e.g. DuskOS is written in Forth -- it is not as much written in Forth as it actually IS Forth). Of course you may ask: if it's so great, why isn't it used very much? Someone somewhere once summed it up like this: Forth gives one extreme freedom and this allows [retards](soydev.md) to make bad design and fuck things up -- [capitalism](capitalism.md) needs languages for monkeys, that's why [bad languages](rust.md) are widely used. And remember: popularity has never been a measure of quality -- the best art will never be mainstream, it can only be understood by a few.

Forth is a bit unique in its philosophy, it can really be hardly compared to traditional languages such as [C++](cpp.md) or [Java](java.md) -- while the "typical language" is always basically the same thing for the programmer (no matter the implementation) and provides a few predefined, highly complex, universal, hardcoded constructs that are simply there and cannot be changed (such as an [OOP](oop.md) system, templates, control structures, ...), **Forth adopts [Unix philosophy](unix_philosophy.md)** by defining just the concept of a word and maybe providing a few simple words and letting the programmer extend the language (that is even the compiler/interpreter itself) by defining new words out of the simpler ones, and this includes even things such as control structures (branches, loops, ...) for example. For instance: in traditional languages you have a few predefined formats in which you may write numbers, e.g. in C you may use decimal numbers as `123` or hexadecimal numbers as `0x7b`; in Forth you may change the base at any time to any value by assigning to the `base` variable, which will change how Forth parses and outputs numbers (while a number is considered any word that's not been found in dictionary). Almost everything in Forth can be modified this way, so pure Forth without any words is not much more than a description of a format of how words will be represented and handled on a very basic level -- something on the level of simplicity of let's say [lambda calculus](lambda_calculus.md) -- and only a *Forth system* of basic words (such as that defined by ANS Forth standard) provides a basic "practically usable" language. The point is this can still be extended yet further, without end or limitations.

{ There used to be a nice Forth wiki at wiki.forthfreak.net, now it has to be accessed via archive as it's dead. Also some nice site here https://www.forth.org/compilers.html. ~drummyfish }

{ Since Forth adopts a kind of unique philosophy, there are some discussion about how low level Forth really is, if it really is a language or something like a "metalanguage", or an "environment" to create your own language by defining your own words. Now this is not a place to go very deep on this but kind of a sum up may be this: Forth in its base version is very low level, however it's very extensible and many Forth systems extend the base language to some kind of much higher level language, hence the debates. ~drummyfish }

The language is usually presented as [interpreted](interpreter.md) but may perfectly well be [compiled](compiler.md) too, in fact it maps very well to [assembly](assembly.md). Some words may be written directly in machine code, so we may possibly see Forth as a kind of a "wrapper for assembly". And even if interpreted, the language can still be very fast thanks to its simplicity. Forth systems traditionally include not just a compiler/interpreter but also an **interactive environment**, kind of [REPL](repl.md) language shell.

There are several Forth standards, most notably ANS Forth from 1994 (the document is [proprietary](proprietary.md), sharing is allowed, 640 kB as txt). Besides others it also allows Forth to include optional [floating point](float.md) support, however Forth programmers highly prefer [fixed point](fixed_point.md) (as stated in the book *Starting Forth*). Then there is a newer Forth 2012 standard, but it's probably better to stick to the older one.

A [free](free_software.md) implementation is e.g. GNU Forth ([gforth](gforth.md)) or [pforth](pforth.md) (a possibly better option by LRS standards, favors [portability](portability.md) over performance).

There is a book called **Starting Forth** that's freely downloadable and quite good at teaching the language.

Forth was invented by [Charles Moore](charles_moore.md) (NOT the one of the [Moore's Law](moores_law.md) though) in 1968, for programming radio telescopes.

## Language

Forth is case-insensitive (this may however not be the case in some implementations).

The language operates on an evaluation **[stack](stack.md)**: e.g. the operation + takes the two values at the top of the stack, adds them together and pushed the result back on the stack (i.e. for example `1 2 +` in Forth is the same as `1 + 2` in C). Besides this there are also some "advanced" features like variables living outside the stack, if you want to use them.

In fact there are two stacks in Forth: the **parameter stack** (also data stack) and **return stack**. Parameter stack is the "normal" stack on which we do most computations and on which we pass parameters and return values. Returns stack is the stack on which return addresses are stored, BUT it is also used as a temporary stack so that we can let's say put aside a few values to dive deeper on the main stack, however this has to be done carefully -- before end of word ("function") is reached, the return stack must be restored to the original state of course.

The stack is composed of **cells**: the size of the cell is implementation defined. The values stored in cells are just binary, they don't have any data type, so whether a value in given cell is considered signed or unsigned is up to the programmer -- some operators treat numbers as signed and some as unsigned (just like in [comun](comun.md)); note that with many operators the distinction doesn't matter (e.g. addition doesn't care if the numbers are signed or not, but comparison does).

Basic [abstraction](abstraction.md) of Forth is so called **word**: a word is simply a string without spaces like `abc` or `1mm#3`. A word represents simply some operations, which may include running native code, pushing numbers on stack or calling other words, for example the word the word `+` performs the addition on top of the stack, `dup` duplicates the top of the stack etc. The programmer can define his own words -- so words are basically kind of "[functions](function.md)" or rather procedures or routines (however words don't return anything or take any arguments in traditional way, they all just invoke some operations -- arguments and return values are passed using the stack). Defining new words expands the current **dictionary**, so Forth basically extends itself as it's running. A word is defined like this:

```
: myword operation1 operation2 ... ;
```

For example a word that computes and average of the two values on top of the stack can be defined as:

```
: average + 2 / ;
```

Dictionary is a very important concept in Forth, it usually stores the words as a [linked list](list.md), starting with the oldest word -- this allows for example temporary shadowing of previously defined words with the same name.

Forth programmers use so called **stack notation** to document the function's "signature", i.e. what it does with the stack -- they write this notation in a comment above a defined word to signify to others what the word will do. Stack notation has the format `( before -- after )`, for example the effect of the above defined `average` words would be written as `( a b -- avg )` in this notation.

Some built-in words include:

```
GENERAL:

+           add                     ( a b -- [a+b] )
-           subtract                ( a b -- [a-b] )
*           multiply                ( a b -- [a*b] )
/           divide                  ( a b -- [a/b] )
=           equals                  ( a b -- [-1 if a = b else 0] )
<>          not equals              ( a b -- [-1 if a != b else 0] )
<           less than (signed)      ( a b -- [-1 if a < b else 0] )
>           greater than (signed)   ( a b -- [-1 if a > b else 0] )
u<          less than (unsigned)    ( a b -- [-1 if a u< b else 0] )
u>          greater than (unsigned) ( a b -- [-1 if a u> b else 0] )
0=          equals zero               ( a -- [-1 if a = 0 else 0] )
and         bitwise and             ( a b -- [a&b] )
or          bitwise or              ( a b -- [a|b] )
mod         modulo                  ( a b -- [a % b] )
dup         duplicate                 ( a -- a a )
drop        pop stack top             ( a -- )
swap        swap items              ( a b -- b a )
rot         rotate 3              ( a b c -- b c a )
pick        push Nth item   ( xN ... x0 N -- ... x0 xN )
.           pop & print number as signed
u.          pop & print number as unsigned
key         read char on top
.s          print stack
emit        pop & print top as char
cr          print newline
cells       times cell width          ( a -- [a * cell width in bytes] )
depth       gets stack size       ( a ... -- [previous stack size] )
quit        don't print "ok" at the end of execution
bye         quit

RETURN STACK:

>r          pops value, pushed it to return stack
r>          pops value from return stack, pushes it
r@          pushes value from return stack (doesn't pop it)
i           pushes value from return stack (without pop)
i'          pushes second value from return stack (without pop)
j           pushes third value from return stack (without pop)

VARIABLES/CONSTS:

variable X      creates var named X (X will be a word that pushed its addr.), allocates 1 cell
create X        assigns X address (without allocating memory)
N X !           stores value N to variable X
N X +!          adds value N to variable X
X @             pushes value of variable X to stack
N constant C    creates constant C with value N (C will be a new word)
C               pushes the value of constant C

SPECIAL:

( )                       comment (inline)
\                         comment (until newline)
." S"                     print string S (compiles in the string)
" S"                      create string S (don't print, pushes pointer and length)
type                      print string (expects pointer and length)
X if C then               if X, execute C (only in word def., X is popped)
X if C1 else C2 then      if X, execute C1 else C2 (only in word def.)
do C loop                 loops from stack top value to stack second from,
                          top, special word "i" will hold the iteration val.
begin C until             like do/loop but keeps looping as long as top = 0
begin C while             like begin/until but loops as long as top != 0
begin C again             infinite loop
begin C1 while C2 repeat  loop with middle condition
leave                     loop break (only for counted loops)
N allot                   allocates N bytes of memory (moves end-of-mem ptr), e.g. for arrays
here                      returns current end-of-mem address ("H" pointer)
exit                      exits from current word
recurse                   recursively call the word currently being defined
see W                     shows (decompiles) the definition of word W
' W                       get address of word W
```

Forth uses counted **strings** (unlike [C](c.md) which uses NULL terminated strings), i.e. a string consists of an address pointing to the string start, and number saying the length of the string.

TODO: local variables, addresses, arrays, compile-time behavior of words, strings, double words

## Examples

These are some tiny example programs:

```
100 1 2 + 7 * / . \ computes and prints 100 / ((1 + 2) * 7)
```

```
cr ." hey bitch" cr \ prints: hey bitch
```

```
: myloop 5 0 do i . loop ; myloop \ prints 0 1 2 3 4
```

And here is our standardized **[divisor tree](divisor_tree.md)** program written in Forth:

```
\ takes x, pops it and recursively prints its divisor tree
: printDivisorTree
  dup 3 <= if
    0 swap 1 swap          \ stack now: 0 1 x
  else
    >r 0 1 r>              \ stack now: a b x

    dup 2 / 1 + 2 do       \ find the closest divisors (a, b)
      dup i mod 0 = if     \ i divides x?
        2 pick 2 pick < if \ a < b?
          i
          swap
          >r               \ use return stack for tmp storage
          swap drop
          swap drop
          dup r@ swap /
          r>
        then
      then
    loop
  then

  ." ( "

  2 pick 0 <> if           \ divisors found?
    2 pick recurse
    dup .
    1 pick recurse
  else
    dup .
  then

  ." ) "

  drop drop drop
;

: digitToNum
  dup dup 48 >= swap 57 <= and if
    48 -
  else
    drop -1
  then
;

: main
  begin \ main loop, read numbers from user
    ." enter a number: "

    0   \ number to read
    begin
      key

      dup 13 <> while \ newline?

      digitToNum

      dup -1 = if
        bye
      then

      swap 10 * +
    repeat

    drop \ key

    dup 1000 < if
      dup . cr
      printDivisorTree cr
    else
      bye
    then
  again
;

main
bye
```

## How To

Source code files usually have `.fs` extension. We can use mentioned gforth to run our files. Let's create file `my.fs`; in it we write: { Hope the code is OK, I never actually programmed in Forth before. ~drummyfish }

```
: factorial
  dup 1 > if
    dup 1 - recurse *
  else
    drop 1
  then
;

5 factorial .

bye
```

We can run this simply with `gforth my.fs`, the programs should write `120`.

## See Also

- [Lisp](lisp.md)
- [comun](comun.md)
- [Tcl](tcl.md)