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So I'm just learning Forth and was curious if anyone could help me understand how memory management generally works. At the moment I only have (some) experience with the C stack-vs-heap paradigm.

From what I understand, one can allocate in the Dictionary, or on the heap. Is the Dictionary faster/preferred like the stack in C? But unlike in C, there aren't scopes and automatic stack reclamation, so I'm wondering if one only uses the dictionary for global data structures (if at all).

As far as the heap goes, is it pretty much like C? Is heap management a standard (ANS) concept, or is it implementation-defined?

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3 Answers 3

up vote 6 down vote accepted

It is not Dictionary, or on the heap - the equivalent of the heap is the dictionary. However, with the severe limitation that it acts more like a stack than a heap - new words are added to the end of the dictionary (allocation by ALLOT and freeing by FORGET or FREE (but freeing all newer words - acting more like multiple POPs)).

An implementation can control the memory layout and thus implement a traditional heap (or garbage collection). An example is A FORTH implementation of the Heap Data Structure for Memory Mangement (1984). Another implementation is Dynamic Memory Heaps for Quartus Forth (2000).

A lot is implementation dependent or extensions. For instance, the memory layout is often with the two block buffers (location by BLOCK and TIB), the text input buffer and values and low-level/primitive functions of the language, in the lowest portion, dictionary in the middle (growing upwards) and the return stack and the parameter stack at the top 1.

The address of the first available byte above the dictionary is returned by HERE (it changes as the dictionary expands).

There is also a scratchpad area above the dictionary (address returned by PAD) for temporarily storing data. The scratchpad area can be regarded as free memory.

The preferred mode of operation is to use the stack as much as possible instead of local variables or a heap.

1 p. 286 (about a particular edition of Forth, MMSFORTH) in chapter "FORTH's Memory, Dictionary, and Vocabularies", Forth: A text and a reference. Mahlon G. Kelly and Nicholas Spies. ISBN 0-13-326349-5 / 0-13-326331-2 (pbk.). 1986 by Prentice-Hall.

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Peter Mortensen laid it out very well. I'll add a few notes that might help a C programmer some.

The stack is closest to what C terms "auto" variables, and what are commonly called local variables. You can give your stack values names in some forths, but most programmers try to write their code so that naming the values is unnecessary.

The dictionary can best be viewed as "static data" from a C programming perspective. You can reserve ranges of addresses in the dictionary, but in general you will use ALLOT and related words to create static data structures and pools which do not change size after allocation. If you want to implement a linked list that can grow in real time, you might ALLOT enough space for the link cells you will need, and write words to maintain a free list of cells you can draw from. There are naturally implementations of this sort of thing available, and writing your own is a good way to hone pointer management skills.

Heap allocation is available in many modern Forths, and the standard defines ALLOCATE, FREE and RESIZE words that work like malloc(), free(), and realloc() in C. The memory they return is from the OS system heap, and it's generally a good idea to store the address in a variable or some other more permanent structure than the stack so that you don't inadvertently lose the pointer before you can free it. As a side note, these words (along with the file i/o words) return a status on the stack that is non-zero if an error occurred. This convention fits nicely with the exception handling mechanism, and allows you to write code like:

variable PTR
1024 allocate throw PTR !
\ do some stuff with PTR
PTR @ free throw
0 PTR !

Or for a more complex if somewhat artificial example of allocate/free:

\ A simple 2-cell linked list implementation using allocate and free
: >link ( a -- a ) ;
: >data ( a -- a ) cell + ;
: newcons ( a -- a )    \ make a cons cell that links to the input
   2 cells allocate throw  tuck >link ! ;
: linkcons ( a -- a )   \ make a cons cell that gets linked by the input
   0 newcons dup rot >link ! ;
: makelist ( n -- a )   \ returns the head of a list of the numbers from 0..n
   0 newcons  dup >r
   over 0 ?do
     i over >data ! linkcons ( a -- a )
   loop  >data !  r> ;
: walklist ( a -- )
   begin   dup >data ?  >link @           dup 0= until drop ;
: freelist ( a -- )
   begin   dup >link @  swap free throw   dup 0= until drop ;
: unittest  10 makelist dup walklist freelist ;
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This may be a bit too late... would you mind explaining the purpose of >link word? –  user797257 Aug 13 '13 at 14:50
    
Sorry - >link is an accessor that goes from the pointer to the "cons cell" (to borrow a term from LISP) to the address of the "next" pointer. It's implemented as NO-OP because in this implementation, the "Next" pointer is the first thing stored in the cons cell. –  Dan Higdon Feb 12 at 22:14

Some Forth implementations support local variables on the return stack frame and allocating memory blocks. For example in SP-Forth:

lib/ext/locals.f
lib/ext/uppercase.f

100 CONSTANT /buf

: test ( c-addr u -- ) { \ len [ /buf 1 CHARS + ] buf }
  buf SWAP /buf UMIN DUP TO len CMOVE
  buf len UPPERCASE
  0 buf len + C! \ just for illustration
  buf len TYPE
;

S" abc" test \ --> "ABC"
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