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Added an int type

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This commit is contained in:
Brandon Rozek 2018-09-20 21:29:08 -04:00
parent 0ddbe79d25
commit 16575da1dc
3 changed files with 392 additions and 63 deletions
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5
src/lexer.l
View file

@ -39,8 +39,9 @@ DIGIT [0-9]
"while" {return WHILE;}
"print" {return PRINT;}
"input" {return INPUT;}
{DIGIT}*"."?{DIGIT}+ {yylval.value = make_node(VALUE, atof(yytext), ""); return VALUE;}
[_a-zA-Z][_a-zA-Z0-9]* {yylval.value = make_node(IDENTIFIER, 0, strdup(yytext)); return IDENTIFIER;}
{DIGIT} {yylval.value = make_node(VALUE, make_value(LONG, atoi(yytext), 0), ""); return VALUE;}
{DIGIT}*"."?{DIGIT}+ {yylval.value = make_node(VALUE, make_value(DOUBLE, 0, atof(yytext)), ""); return VALUE;}
[_a-zA-Z][_a-zA-Z0-9]* {yylval.value = make_node(IDENTIFIER, NULL, strdup(yytext)); return IDENTIFIER;}
[\n] {linenum++;}
[ \t\r]+ {}
. {printf("Error: invlaid lexeme '%s'.\n", yytext); return 0;}

25
src/node.h
View file

@ -6,13 +6,16 @@
#define STATEMENT 200
#define MAX_VARIABLES 200
#define DOUBLE 300
#define LONG 301
// Share the line number between files
extern int linenum;
/* a tree node definition */
struct Node {
int type;
double value;
struct Value* value;
/* the id of the node (used for identifiers only) */
char id[ID_SIZE];
@ -23,7 +26,7 @@ struct Node {
};
// Abstract Syntax Tree Functions
struct Node* make_node(int type, double value, char* id);
struct Node* make_node(int type, struct Value* value, char* id);
void attach_node(struct Node* parent, struct Node* child);
void print_tree(struct Node* node, int tabs);
void delete_tree(struct Node* node);
@ -31,7 +34,7 @@ void delete_tree(struct Node* node);
struct Variable {
char id[ID_SIZE];
double value;
struct Value* value;
};
typedef union typeval {
@ -45,15 +48,17 @@ struct Value {
};
// Value functions
int get_int(struct Value* val);
struct Value* make_value(int type, long num, double dec);
void delete_value(struct Value* val);
long get_long(struct Value* val);
double get_double(struct Value* val);
void set_int(struct Value* val);
void set_double(struct Value* val);
void set_long(struct Value* val, long num);
void set_double(struct Value* val, double dec);
// Variable Functions
struct Variable* make_variable(char* id, double value);
void set_value(struct Variable* var, double value);
double get_value(struct Variable* var);
struct Variable* make_variable(char* id, struct Value* value);
void set_value(struct Variable* var, struct Value* value);
struct Value* get_value(struct Variable* var);
struct Environment {
int num_vars;
@ -69,6 +74,6 @@ void add_variable(struct Environment* env, struct Variable* var);
// Interpreting AST
void eval_statement(struct Node* node, struct Environment* env);
double eval_expression(struct Node* node, struct Environment* env);
struct Value* eval_expression(struct Node* node, struct Environment* env);
#endif

419
src/parser.y
View file

@ -70,32 +70,32 @@ statement: assignment { $$ = $1; }
| statements { $$ = $1; }
assignment: ident ASSIGN expression SEMICOLON {
$$ = make_node(ASSIGN, 0, "");
$$ = make_node(ASSIGN, NULL, "");
attach_node($$, $1);
attach_node($$, $3);
}
if-statement: IF expression THEN statement {
$$ = make_node(IF, 0, "");
$$ = make_node(IF, NULL, "");
attach_node($$, $2);
attach_node($$, $4);
}
if-else-statement: IF expression THEN statement ELSE statement {
$$ = make_node(IF, 0, "");
$$ = make_node(IF, NULL, "");
attach_node($$, $2);
attach_node($$, $4);
attach_node($$, $6);
}
while: WHILE expression DO statement {
$$ = make_node(WHILE, 0, "");
$$ = make_node(WHILE, NULL, "");
attach_node($$, $2);
attach_node($$, $4);
}
print: PRINT expression SEMICOLON {
$$ = make_node(PRINT, 0, "");
$$ = make_node(PRINT, NULL, "");
attach_node($$, $2);
}
@ -103,31 +103,31 @@ print: PRINT expression SEMICOLON {
statements: BEGINTOK substatements END { $$ = $2; }
| BEGINTOK END {}
substatements: statement substatements {$$ = make_node(STATEMENT, 0, ""); attach_node($$, $1); attach_node($$, $2); }
| statement {$$ = make_node(STATEMENT, 0, ""); attach_node($$, $1); }
substatements: statement substatements {$$ = make_node(STATEMENT, NULL, ""); attach_node($$, $1); attach_node($$, $2); }
| statement {$$ = make_node(STATEMENT, NULL, ""); attach_node($$, $1); }
expression : expression OR subexpression { $$ = make_node(OR, 0, ""); attach_node($$, $1); attach_node($$, $3);}
| expression AND subexpression { $$ = make_node(AND, 0, ""); attach_node($$, $1); attach_node($$, $3);}
expression : expression OR subexpression { $$ = make_node(OR, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| expression AND subexpression { $$ = make_node(AND, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression { $$ = $1; }
subexpression: subexpression LESS term { $$ = make_node(LESS, 0, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression LESSEQ term { $$ = make_node(LESSEQ, 0, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression GREATER term { $$ = make_node(GREATER, 0, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression GREATEREQ term { $$ = make_node(GREATEREQ, 0, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression EQUALS term { $$ = make_node(EQUALS, 0, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression NEQUALS term { $$ = make_node(NEQUALS, 0, ""); attach_node($$, $1); attach_node($$, $3);}
subexpression: subexpression LESS term { $$ = make_node(LESS, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression LESSEQ term { $$ = make_node(LESSEQ, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression GREATER term { $$ = make_node(GREATER, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression GREATEREQ term { $$ = make_node(GREATEREQ, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression EQUALS term { $$ = make_node(EQUALS, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| subexpression NEQUALS term { $$ = make_node(NEQUALS, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| term { $$ = $1; }
term : term PLUS subterm { $$ = make_node(PLUS, 0, ""); attach_node($$, $1); attach_node($$, $3);}
| term MINUS subterm { $$ = make_node(MINUS, 0, ""); attach_node($$, $1); attach_node($$, $3);}
term : term PLUS subterm { $$ = make_node(PLUS, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| term MINUS subterm { $$ = make_node(MINUS, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| subterm { $$ = $1; }
subterm: subterm TIMES factor { $$ = make_node(TIMES, 0, ""); attach_node($$, $1); attach_node($$, $3);}
| subterm DIVIDE factor { $$ = make_node(DIVIDE, 0, ""); attach_node($$, $1); attach_node($$, $3);}
subterm: subterm TIMES factor { $$ = make_node(TIMES, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| subterm DIVIDE factor { $$ = make_node(DIVIDE, NULL, ""); attach_node($$, $1); attach_node($$, $3);}
| factor { $$ = $1; }
factor : MINUS factor { $$ = make_node(MINUS, 0, ""); attach_node($$, $2); }
| NOT factor { $$ = make_node(NOT, 0, ""); attach_node($$, $2); }
factor : MINUS factor { $$ = make_node(MINUS, NULL, ""); attach_node($$, $2); }
| NOT factor { $$ = make_node(NOT, NULL, ""); attach_node($$, $2); }
| atom { $$ = $1; }
atom: OPENPAREM expression ENDPAREM { $$ = $2; }
@ -137,7 +137,7 @@ ident: IDENTIFIER { $$ = $1; }
identvalue: IDENTIFIER { $$ = $1; }
| VALUE { $$ = $1; }
| INPUT { $$ = make_node(INPUT, 0 , ""); }
| INPUT { $$ = make_node(INPUT, NULL , ""); }
@ -184,7 +184,7 @@ int main(int argc, char* argv[]) {
/* creates a new node and returns it */
struct Node* make_node(int type, double value, char* id) {
struct Node* make_node(int type, struct Value* value, char* id) {
int i;
/* allocate space */
@ -212,6 +212,7 @@ void attach_node(struct Node* parent, struct Node* child) {
}
void print_tree(struct Node* node, int tabs) {
int i;
/* base case */
if(!node) {
fprintf(stderr, "NO TREE STRUCTURE\n");
@ -219,13 +220,12 @@ void print_tree(struct Node* node, int tabs) {
}
/* print leading tabs */
for(int i = 0; i < tabs; i++) {
for(i = 0; i < tabs; i++) {
printf(" ");
}
switch(node->type) {
case IDENTIFIER: printf("IDENTIFIER: %s\n", node->id); break;
case VALUE: printf("VALUE: %lf\n", node->value); break;
case PLUS: printf("PLUS:\n"); break;
case MINUS: printf("MINUS:\n"); break;
case DIVIDE: printf("DIVIDE:\n"); break;
@ -245,6 +245,13 @@ void print_tree(struct Node* node, int tabs) {
case PRINT: printf("PRINT:\n"); break;
case INPUT: printf("INPUT:\n"); break;
case STATEMENT: printf("STATEMENT:\n"); break;
case VALUE:
if (node->value->type == LONG) {
printf("VALUE: %li\n", get_long(node->value));
} else { // Assume double
printf("VALUE: %lf\n", get_double(node->value));
}
break;
default:
printf("Error, %d not a valid node type.\n", node->type);
exit(1);
@ -265,7 +272,7 @@ void delete_tree(struct Node* node) {
}
/* creates a new variable and returns it */
struct Variable* make_variable(char* id, double value) {
struct Variable* make_variable(char* id, struct Value* value) {
/* allocate space */
struct Variable* var = malloc(sizeof(struct Variable));
@ -277,12 +284,12 @@ struct Variable* make_variable(char* id, double value) {
return var;
}
void set_value(struct Variable* var, double value) {
void set_value(struct Variable* var, struct Value* value) {
if (!var) { fprintf(stderr, "Error: Invalid Variable\n"); return; }
var->value = value;
}
double get_value(struct Variable* var) {
struct Value* get_value(struct Variable* var) {
if (!var) { fprintf(stderr, "Error: Invalid Variable\n"); return 0; }
return var->value;
}
@ -337,7 +344,281 @@ void check_num_nodes(struct Node* node, int num_children, char* error) {
}
}
double eval_expression(struct Node* node, struct Environment* env) {
struct Value* make_value(int type, long num, double dec) {
/* allocate space */
struct Value* val = malloc(sizeof(struct Value));
/* set properties */
val->type = type;
if (type == LONG) {
val->value.num = num;
} else { // Assume DOUBLE
val->value.dec = dec;
}
/* return new variable */
return val;
}
void delete_value(struct Value* val) {
free(val);
}
long get_long(struct Value* val) {
return val->value.num;
}
double get_double(struct Value* val) {
return val->value.dec;
}
void set_long(struct Value* val, long num) {
val->type = LONG;
val->value.num = num;
}
void set_double(struct Value* val, double dec) {
val->type = DOUBLE;
val->value.dec = dec;
}
struct Value* add(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in add.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) + get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) + get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) + get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) + get_double(y));
}
return ans;
}
struct Value* subtract(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in subtract.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) - get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) - get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) - get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) - get_double(y));
}
return ans;
}
struct Value* division(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in divide.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) / get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) / get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) / get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) / get_double(y));
}
return ans;
}
struct Value* multiplication(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in multiply.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) * get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) * get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) * get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) * get_double(y));
}
return ans;
}
struct Value* less(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in <.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) < get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) < get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) < get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) < get_double(y));
}
return ans;
}
struct Value* greater(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in greater.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) > get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) > get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) > get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) > get_double(y));
}
return ans;
}
struct Value* less_equal(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in <=.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) <= get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) <= get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) <= get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) <= get_double(y));
}
return ans;
}
struct Value* greater_equal(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in >=.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) >= get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) >= get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) >= get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) >= get_double(y));
}
return ans;
}
struct Value* equals(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in ==.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) == get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) == get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) == get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) == get_double(y));
}
return ans;
}
struct Value* not_equals(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in !=.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) != get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) != get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) != get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) != get_double(y));
}
return ans;
}
struct Value* and(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in &&.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) && get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) && get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) && get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) && get_double(y));
}
return ans;
}
struct Value* or(struct Value* x, struct Value* y) {
if (!x || !y) { fprintf(stderr, "Error, uninitialized values being used in ||.\n"); }
struct Value* ans;
// Destruct all four cases
if (x->type == LONG && y->type == LONG) {
ans = make_value(LONG, get_long(x) || get_long(y), 0);
} else if (x->type == LONG && y->type == DOUBLE) {
ans = make_value(DOUBLE, 0, get_long(x) || get_double(y));
} else if (x->type == DOUBLE && y->type == LONG) {
ans = make_value(DOUBLE, 0, get_double(x) || get_long(y));
} else { // Both are DOUBLE
ans = make_value(DOUBLE, 0, get_double(x) || get_double(y));
}
return ans;
}
struct Value* not(struct Value* x) {
if (!x) { fprintf(stderr, "Error, uninitialized values being used in !.\n"); }
struct Value* ans;
// Destruct all two cases
if (x->type == LONG) {
ans = make_value(LONG, !get_long(x), 0);
} else { // Assume it's a double
ans = make_value(DOUBLE, 0, !get_double(x));
}
return ans;
}
struct Value* eval_expression(struct Node* node, struct Environment* env) {
/* base case */
if(!node) {
fprintf(stderr, "Error: No tree structure to evaluate\n");
@ -349,13 +630,16 @@ double eval_expression(struct Node* node, struct Environment* env) {
struct Variable* var = NULL;
// Evaluate subexpressions if existent
double val1, val2, val3;
struct Value* val1 = NULL;
struct Value* val2 = NULL;
struct Value* val3 = NULL;
if (node->num_children > 0) {
val1 = eval_expression(node->children[0], env);
if (node->num_children > 1) {
val2 = eval_expression(node->children[1], env);
if (node->num_children > 2) {
val3 = eval_expression(node->children[2], env);
// delete_value(val3); // No code below uses val3 for now...
}
}
}
@ -363,73 +647,87 @@ double eval_expression(struct Node* node, struct Environment* env) {
switch(node->type) {
case PLUS:
check_num_nodes(node, 2, "cannot add more than two expressions.");
return val1 + val2;
return add(val1, val2);
// return val1 + val2;
break;
//----------
case MINUS:
check_num_nodes(node, 2, "cannot subtract more than two expressions.");
return val1 - val2;
return subtract(val1, val2);
// return val1 - val2;
break;
//----------
case DIVIDE:
check_num_nodes(node, 2, "cannot divide more than two expressions.");
return val1 / val2;
return division(val1, val2);
// return val1 / val2;
break;
//----------
case TIMES:
check_num_nodes(node, 2, "cannot multiply more than two expressions.");
return val1 * val2;
return multiplication(val1, val2);
// return val1 * val2;
break;
//----------
case LESS:
check_num_nodes(node, 2, "cannot compare more than two expressions.");
if (node->num_children != 2) { fprintf(stderr, "Error, cannot compare more than two expressions.\n"); }
return val1 < val2;
return less(val1, val2);
// return val1 < val2;
break;
//----------
case GREATER:
check_num_nodes(node, 2, "cannot compare more than two expressions.");
return val1 > val2;
return greater(val1, val2);
// return val1 > val2;
break;
//----------
case LESSEQ:
check_num_nodes(node, 2, "cannot compare more than two expressions.");
return val1 <= val2;
return less_equal(val1, val2);
// return val1 <= val2;
break;
//----------
case GREATEREQ:
check_num_nodes(node, 2, "cannot compare more than two expressions.");
return val1 >= val2;
return greater_equal(val1, val2);
// return val1 >= val2;
break;
//----------
case EQUALS:
check_num_nodes(node, 2, "cannot compare more than two expressions.");
return val1 == val2;
return equals(val1, val2);
// return val1 == val2;
break;
//----------
case NEQUALS:
check_num_nodes(node, 2, "cannot compare more than two expressions.");
return val1 != val2;
return not_equals(val1, val2);
// return val1 != val2;
break;
//----------
case AND:
check_num_nodes(node, 2, "cannot perform logical operators on more than two expressions.");
return val1 && val2;
return and(val1, val2);
// return val1 && val2;
break;
//----------
case OR:
check_num_nodes(node, 2, "cannot perform logical operators on more than two expressions.");
return val1 || val2;
return or(val1, val2);
// return val1 || val2;
break;
//----------
case NOT:
check_num_nodes(node, 1, "cannot negate more than one expressions.");
return !val1;
return not(val1);
// return !val1;
break;
//----------
case INPUT:
case INPUT: // We're only going to support reading in doubles
// Look into deleting possible values...?
scanf("%lf", &temp);
return temp;
return make_value(DOUBLE, 0, temp);
break;
//----------
case IDENTIFIER:
@ -459,6 +757,7 @@ void eval_statement(struct Node* node, struct Environment* env) {
fprintf(stderr, "Error: No tree structure to evaluate\n");
return;
}
struct Value* tempVal;
switch(node->type) {
case ASSIGN:
@ -472,23 +771,47 @@ void eval_statement(struct Node* node, struct Environment* env) {
if (node->num_children != 2 && node->num_children != 3) {
fprintf(stderr, "Error: The format of an if-statement is if expression statement with an optional else.\n");
}
if (eval_expression(node->children[0], env)) {
tempVal = eval_expression(node->children[0], env);
if (tempVal->type == LONG) {
if (get_long(tempVal)) {
eval_statement(node->children[1], env);
} else if (node->num_children == 3) {
eval_statement(node->children[2], env);
}
} else { // Assume DOUBLE
if (get_double(tempVal)) {
eval_statement(node->children[1], env);
} else if (node->num_children == 3) {
eval_statement(node->children[2], env);
}
}
break;
//------------
case WHILE:
check_num_nodes(node, 2, "the format of a while statement is: while expression statement(s)");
while (eval_expression(node->children[0], env)) {
tempVal = eval_expression(node->children[0], env);
if (tempVal->type == LONG) {
while (get_long(tempVal)) {
eval_statement(node->children[1], env);
tempVal = eval_expression(node->children[0], env);
}
} else { // Assume DOUBLE
while (get_double(tempVal)) {
eval_statement(node->children[1], env);
tempVal = eval_expression(node->children[0], env);
}
}
break;
//------------
case PRINT:
check_num_nodes(node, 1, "can only print out one expression at a time.");
printf("%lf\n", eval_expression(node->children[0], env));
tempVal = eval_expression(node->children[0], env);
if (tempVal->type == LONG) {
printf("%li\n", get_long(tempVal));
} else {
printf("%lf\n", get_double(tempVal));
}
break;
//------------
case STATEMENT: // Can have a maximum of two children statement nodes