TREE-META

The TREE-META (or Tree Meta, TREEMETA) Translator Writing System is a compiler-compiler system for context-free languages originally developed in the 1960s. Parsing statements of the metalanguage resemble augmented Backus–Naur form with embedded tree-building directives. Unparsing^[1] rules include extensive tree-scanning and code-generation constructs.

TREE-META was instrumental in the development of NLS (oN-Line System) and was ported to many systems including the UNIVAC 1108, GE 645, SDS 940, ICL 1906A, PERQ, and UCSD p-System.^[2][3]

This is a complete example of a TREE-META program extracted (and untested) from the more complete (declarations, conditionals, and blocks) example in Appendix 6 of the ICL 1900 TREE-META manual.^[4] That document also has a definition of TREE-META in TREE-META in Appendix 3. This program is not just a recognizer, but also outputs the assembly language for the input. It demonstrates one of the key features of TREE-META, which is tree pattern matching. It is used on both the LHS (GET and VAL for example) and the RHS (ADD and SUB).

% This is an ALGOL-style comment delimited by %

% ====================== INPUT PARSE RULES ======================= %

.META PROG 
% A program defining driving rule is required.                     %
% This PROG rule is the driver of the complete program.            %

PROG  = $STMT ;
% $ is the zero or more operator.                                  %
% PROG (the program) is defined as zero or more STMT (statements). %

STMT = .ID ':=' AEXP :STORE[2]*;
% Parse an assignment statement from the source to the tree.       % 
% ':=' is a string constant, :STORE creates a STORE node,          %
% [2] defines this as having two branches i.e. STORE[ID,AEXP].     %
% * triggers a unparse of the tree, Starting with the last created %
% tree i.e. the STORE[ID,AEXP] which is emitted as output and      %
% removed from the tree.                                           %

AEXP = FACTOR $('+' FACTOR :ADD[2] / '-' FACTOR :SUB[2]);
% Here we have the recognizer for arithmetic '+' :ADD and '-' :SUB %
% tree building. Again the [2] creates a 2-branch ADD or SUB tree. %
% Unparsing is deferred until an entire statement has been parsed. %
% ADD[FACTOR,FACTOR] or SUB[FACTOR,FACTOR]                         %

FACTOR = '-' PRIME :MINUSS[1] / PRIME ;

PRIME =  .ID / .NUM / '(' AEXP ')' ?3? ;
% ?3? is a hint for error messages.                                %
    
% ===================== OUTPUT UNPARSE RULES ===================== %

STORE[-,-] => GET[*2] 'STORE ' *1 ;
% *1 is the left tree branch. *2 is the right                      %
% GET[*2] will generate code to load *2.                           %
% The 'STORE' string will be output                                %
% followed by left branch *1 a symbol                              %
% Whatever *2, it will be loaded by GET[*2].                       %

GET[.ID] => 'LOAD ' *1 /
   [.NUM] => ' LOADI ' *1 /
   [MINUSS[.NUM]] => 'LOADN ' *1:*1 /
   [-]  => *1 ;
% Here an .ID or a .NUM will simply be loaded. A MINUSS node       %
% containing a .NUM will have this used, the notation *1:*1 means  %
% the first branch (a .NUM) of the first branch (MINUSS).          %
% Anything else will be passed on for node recognition             %
% The unparse rules deconstruct a tree outputing code.             %

ADD[-,-] =>  SIMP[*2] GET[*1] 'ADD' VAL[*2]  / 
             SIMP[*1] GET[*2] 'ADD' VAL[*1] / 
             GET[*1] 'STORE T+' < OUT[A] ; A<-A+1 > /
             GET[*2] 'ADD T+' < A<-A-1 ; OUT[A] > ;
% Chevrons < > indicate an arithmetic operation, for example to    %
% generate an offset A relative to a base address T.               %

SUB[-,-]  => SIMP[*2] GET[*1] 'SUB' VAL[*2] / 
             SIMP[*1] GET[*2] 'NEGATE' % 'ADD' VAL[*1] /
             GET[*2] 'STORE T+' < OUT[A] ; A<-A+1 > / 
             GET[*1] 'SUB T+' < A<-A-1 ; OUT[A] > ;
% A percent character in an unparse rule indicates a newline.      %

SIMP[.ID]           => .EMPTY /
    [.NUM]          => .EMPTY /
    [MINUSS[.NUM]]  => .EMPTY;

VAL[.ID]             => ' ' *1 /
   [.NUM]            => 'I ' *1 /
   [MINUSS[.NUM]]    => 'N ' *1:*1 ;

MINUSS[-]            => GET[*1] 'NEGATE' ;

.END

• NLS (computer system)
• META II

• C. Stephen Carr, David A. Luther, Sherian Erdmann, The TREE-META Compiler-Compiler System: A Meta Compiler System for the Univac 1108 and General Electric 645^{[dead link]}, University of Utah Technical Report RADC-TR-69-83.
• [1]^{[dead link]}, also [2] 1968 Tech Report by Englebart, English, and Rulifson on Tree Meta's use in what they called Special-Purpose Languages (SPL's), which we now call Domain Specific Languages (DSL's), in the NLS.
• Donald I. Andrews, J. F. Rulifson (1967). Tree Meta (Working Draft): A Meta Compiler for the SDS 940, Stanford Research Institute, Menlo Park, CA. Engelbart Collection, Stanford University Archive, M 638, Box 16, Folder 3.
• ANDREWS, LEHTMAN, and WHP. "Tree Meta – a metacompiler for the Augmentation Research Center". Preliminary draft, 25 March 1971.
• Alan C. Kay The Reactive Engine Ph.D. thesis 1969 University of Utah. Notes that Henri Gouraud did the FLEX compiler in TREE-META on the SRI (Engelbart) SDS-940.
• Atlas Computer Laboratory quarterly report (21 November 1975), F. R. A. Hopgood documents work using TREE-META to create a compiler generating FR80 assembler output.
• Atlas Computer Laboratory quarterly report (12 October 1973), C. J. Pavelin documents (section 4.10) TREE-META being ported to the 1906A.
• TREE-META: a meta-compiler for the Interdata Model 4 by W. M. Newman. Queen Mary College, London. November 1972.

• Manual for ICL 1900 version of TREE-META by F R A Hopgood.
• Home page for collecting information about TREE-META
• TREE META Draft Document December, 1967 at bitsavers.org
• TREE META Release Document April, 1968 at bitsavers.org
• STUDY FOR THE DEVELOPMENT OF HUMAN INTELLECT AUGMENTATION TECHNIQUES by D. C. Engelbart
• Implementation of TREE-META in C (based on the version of TREE-META for the ICL 1900) ^{[dead link]}
• A revival of the TREE-META compiler-compiler.