Translational Backus–Naur form
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Translational Backus–Naur Form (TBNF or Translational BNF) refers to Backus–Naur form, which is a formal grammar notation used to define the syntax of computer languages, such as Algol, Ada, C++, COBOL, Fortran, Java, Perl, Python, and many others. TBNF goes beyond BNF and extended BNF (EBNF) grammar notation because it not only defines the syntax of a language, but also defines the structure of the abstract syntax tree (AST) to be created in memory and the output intermediate code to be generated. Thus TBNF defines the complete translation process from input source code to intermediate code. Specification of the output intermediate code is optional, in which case you will still get automatic AST creation and have the ability to define its structure in the grammar.
Overview
[edit]The TBNF concept was first published in April 2006 in a paper at SIGPLAN Notices, a special interest group of the ACM. [1]
Here is a sample grammar specified in TBNF:
/* TBNF Grammar for a simple language.
Five node arguments are used in this grammar to avoid having to create node actions.
*/
/* Input Tokens. */
<error> => error() ;
<identifier> => lookup(); // Lookup & store in symbol table.
<integer> => lookup(); // Lookup & store in symbol table.
<eof> ;
/* Operator precedence. */
{ '==' '!=' } << // Lowest priority.
{ '+' '-' } <<
{ '*' '/' } << // Highest priority.
/* Productions. */
Goal -> Program... <eof> *> goal_ (0,,"\t\tSTART\n" ,,"\t\tEOF\n\n")
Program -> 'program' <identifier> '{' Stmt... '}' *> program_ (2,,"\t\tPROGRAM %s\n",,"\t\tEND PROGRAM %s\n")
Stmt -> Assignment
-> IfThen
-> IfElse
-> IfThenElse
Assignment ~> Target '=' Exp ';' *> assign_ (0,, ,,"\t\tSTORE\n")
IfThen -> 'if' RelExp Then 'endif' *> if_ (0,,"if&0:\n",,"endif&0:\n" )
IfElse -> 'if' RelExp Else 'endif' *> if_ (0,,"if&0:\n",,"endif&0:\n" )
IfThenElse -> 'if' RelExp Then2 Else2 'endif' *> if_ (0,,"if&0:\n",,"endif&0:\n" )
Target -> <identifier> *> ident_ (1,,,,"\t\tLADR %s\n")
RelExp -> Exp '==' Exp *> eq_ (0,,,,"\t\tEQ\n" )
-> Exp '!=' Exp *> ne_ (0,,,,"\t\tNE\n" )
Exp -> Primary
-> Exp '+' Exp *> add_ (0,,,,"\t\tADD\n")
-> Exp '-' Exp *> sub_ (0,,,,"\t\tSUB\n")
-> Exp '*' Exp *> mul_ (0,,,,"\t\tMUL\n")
-> Exp '/' Exp *> div_ (0,,,,"\t\tDIV\n")
Primary -> <integer> *> intr_ (1,,,,"\t\tLOAD %s\n")
-> <identifier> *> ident_ (1,,,,"\t\tLOAD %s\n")
-> '(' Exp ')'
Then -> 'then' Stmt... *> then_ (0,,"\t\tBR NZ endif&1\nthen&1:\n",,)
Else -> 'else' Stmt... *> else_ (0,,"\t\tBR Z endif&1\nelse&1:\n" ,,)
Then2 -> 'then' Stmt... *> then2_ (0,,"\t\tBR NZ else&1\nthen&1:\n" ,,)
Else2 -> 'else' Stmt... *> else2_ (0,,"\t\tBR endif&1\nelse&1:\n" ,,)
/* End of Grammar. */
Given this input:
program test
{
if a == 0
then
if x == 0
then b = 10;
else b = 20;
endif
else
if x == 1
then b = 30;
else b = 40;
endif
endif
}
Running the translator generated from the above grammar would produce this output:
START
PROGRAM test
if1:
LOAD a
LOAD 0
EQ
BR NZ else1
then1:
if2:
LOAD x
LOAD 0
EQ
BR NZ else2
then2:
LOAD 10
LADR b
STORE
BR endif2
else2:
LOAD 20
LADR b
STORE
endif2:
BR endif1
else1:
if3:
LOAD x
LOAD 1
EQ
BR NZ else3
then3:
LOAD 30
LADR b
STORE
BR endif3
else3:
LOAD 40
LADR b
STORE
endif3:
endif1:
END PROGRAM test
EOF
References
[edit]- ^ Mann, Paul B (2006). "A Translational BNF Grammar Notation (TBNF)". SIGPLAN Notices. 41 (4): 16–23. doi:10.1145/1147214.1147218.