Mercurial > ~dholland > hg > ag > index.cgi
view tests/agcl/oldagsrc/asilbug1.syn @ 5:7661c1604e49
Add additional operator delete calls gcc 10 asked for.
| author | David A. Holland |
|---|---|
| date | Mon, 30 May 2022 23:32:56 -0400 |
| parents | 13d2b8934445 |
| children |
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{ /* VM.SYN Virtual Machine Compiler Copyright (c) 1997 Parsifal Software, All Rights Reserved. The expression syntax is borrowed from C but with the addition of the FORTRAN exponentiation operator (**). The cast, increment, and decrement operators are not implemented, nor are operations that are defined only for integers: Bitwise logical operators: &, |, ^, ~, &=, |=, ^= Remainder operators: %, %= Shift operators: <<, >>, >>=, <<= The supported operations are: Assignment operators: =, +=, -=, *=, /= Conditional expressions: ? : Logical operators: !, &&, || Comparison operators: ==, !=, <, <=, >, >= Binary arithmetic operators: +, -, *, / Exponentiation: ** Unary arithmetic operators: +, - Parentheses Function calls All arithmetic is double precision floating point. Statements may include expression statements, blocks, if/else statements or while statements, following the rules of C. The statement syntax has been written to avoid the conventional if/else ambiguity. There are no declarations. All variables are presumed to be double. Input strings may contain any number of statements. White space may be used freely, including both C and C++ style comments. vmCompile makes the following external calls: void pushChar(int character); Push the specified character onto a character stack. int locateVariable(int nameLength); Pop the last nameLength characters from the character stack and, treating them as the name of a variable, return an index into the variable array. Overrides for macros defined by AnaGram, such as SYNTAX_ERROR are included in VMDEFS.H VM.SYN is compiled with the AnaGram parser generator yielding VM.H and VM.CPP. To build VM, compile VM.CPP and VMDEMO.CPP and link them with your C++ compiler. For information about AnaGram, visit http://www.parsifalsoft.com. */ #include <math.h> #include "vmdefs.h" // defines external interface static VirtualMachine *vm; } // -- CONFIGURATION SECTION ---------------------------- [ default token type = double disregard white space lexeme {real, name} pointer input parser name = asil parser file name = "#.cpp" line numbers ] //parse option $ // -> parse script, statements?, eof // -> skip statement, statement text?, ';' // -> skip statement, balanced braces // -> skip condition, balanced parens // -> eval expression, expression // -> exec statement, statement //parse script, skip statement, skip condition, eval expression, exec statement // -> =asil_change_reduction(PCB, syntaxSelector); (void) input string $ // specify grammar token -> statements?, eof statement text -> statement char -> balanced parens -> statement text, statement char -> statement text, balanced parens -> statement text, balanced braces blank = ' ' + '\t' + '\f' + '\v' + '\r' + '\n' statement char = 32..126 - blank - ';' - '(' - ')' - '{' - '}' balanced parens -> '(', statement text?, ')' balanced braces -> '{', statement text?, '}' -> '{', balanced braces, '}' statement -> unconditional statement -> conditional statement statements -> statement:x =x; -> statements:x, statement =x; skip statement -> skip unconditional statement -> skip conditional statement /* An unconditional statement is any statement that does not involve an if statement */ unconditional statement -> expression:x, ';' -> ';' -> '{', '}' -> '{', statements:s, '}' -> gather unconditional while, while loop, false condition, skip statement gather unconditional while -> "while", balanced parens, skip unconditional statement while loop -> -> while loop, true condition, statement skip unconditional statement -> statement text?, ';' -> balanced braces -> "while", balanced parens, skip unconditional statement /* Any statement with an if in it is a conditional statement */ conditional statement -> gather conditional while, while loop, false condition, skip statement -> true if clause:x, statement -> false if clause:x, skip statement -> true if clause:x, unconditional statement:s1, "else", skip statement:s2 -> false if clause:x, skip unconditional statement:s1, "else", statement:s2 gather conditional while -> "while", balanced parens, skip conditional statement skip conditional statement -> "if", balanced parens, skip statement -> "if", balanced parens, skip unconditional statement, "else", skip statement -> "while", balanced parens, skip conditional statement false if clause, true if clause -> "if", '(', expression:x, ')' ={if (x) CHANGE_REDUCTION(true_if_clause);} expression -> conditional expression -> name:k, '=', expression:x =vm->code(STORE, k), x; -> name:k, "+=", expression:x =vm->code(ADDM,k), x; -> name:k, "-=", expression:x =vm->code(SUBM,k), x; -> name:k, "*=", expression:x =vm->code(MULM,k), x; -> name:k, "/=", expression:x =vm->code(DIVM,k), x; conditional expression -> logical or expression -> logical or expression:c, '?', expression:x, ':', conditional expression:y =vm->codeIfElse(c,x,y); logical or expression -> logical and expression -> logical or expression:x, "||", logical and expression:y =vm->insertCode(OR, vm->wx - y, y), x; logical and expression -> equality expression -> logical and expression:x, "&&", equality expression:y =vm->insertCode(AND, vm->wx - y, y), x; equality expression -> relational expression -> equality expression:x, "==", relational expression:y =vm->code(EQ), x; -> equality expression:x, "!=", relational expression:y =vm->code(NE), x; relational expression -> additive expression -> relational expression:x, '<', additive expression:y =vm->code(LT), x; -> relational expression:x, "<=", additive expression:y =vm->code(LE), x; -> relational expression:x, '>', additive expression:y =vm->code(GT), x; -> relational expression:x, ">=", additive expression:y =vm->code(GE), x; additive expression -> multiplicative expression -> additive expression:x, '+', multiplicative expression:y =vm->code(ADD), x; -> additive expression:x, '-', multiplicative expression:y =vm->code(SUB), x; multiplicative expression -> factor -> multiplicative expression:x, '*', factor: y =vm->code(MUL), x; -> multiplicative expression:x, '/', factor:y =vm->code(DIV), x; factor -> primary -> primary:x, "**", factor:y =vm->code(POW), x; primary -> real:x =vm->code(PUSHI, x); -> name:k =vm->code(PUSH, k); -> "log", '(', expression:x, ')' =vm->code(LOG), x; -> "exp", '(', expression:x, ')' =vm->code(EXP), x; -> '(', expression:x, ')' =x; -> '-', primary:x =vm->code(NEG), x; -> '+', primary:x =x; -> '!', primary:x =vm->code(NOT), x; // -- LEXICAL UNITS ------------------------------------------------ digit = '0-9' eof = 0 letter = 'a-z' + 'A-Z' + '_' (void) white space -> blank -> "/*", ~eof?..., "*/" // C style comment -> "//", ~(eof+'\n')?..., '\n' // C++ style comment (double) real -> simple real -> simple real:x, 'e'+'E', '+'?,exponent:e =x*pow(10,e); -> simple real:x, 'e'+'E', '-',exponent:e =x*pow(10,-e); (double) simple real -> integer part:i, '.', fraction part:f = i+f; -> integer part, '.'? -> '.', fraction part:f = f; (double) integer part -> digit:d = d-'0'; -> integer part:x, digit:d = 10*x + d-'0'; (double) fraction part -> digit:d =(d-'0')/10.; -> digit:d, fraction part:f =(d-'0' + f)/10.; (int) exponent -> digit:d = d-'0'; -> exponent:x, digit:d = 10*x + d-'0'; (int) name -> name string:k =locateVariable(k); (int) name string -> letter: c =pushChar(c), 1; -> name string:k, letter+digit: c =pushChar(c), k+1; { // begin embedded C int compileStatements(VirtualMachine *v, char *text) { vm = v; resetCharStack(); vmCompile_pcb.pointer = (unsigned char *) text; vmCompile(); return vmCompile_pcb.exit_flag != AG_SUCCESS_CODE; } } // end of embedded C /********************* End of VM.SYN ************************/