-#include <malloc.h>
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
+#include "alloc.h"
+#include "argument.h"
#include "debug.h"
+#include "element.h"
+#include "format.h"
+#include "program.h"
+#include "stack.h"
+#include "storage.h"
#include "parser.h"
double answer = 0;
-#define DEFAULT_STORAGE_SIZE 10
-int storage_size = -1;
-
-double *storage = NULL;
-
-#define DEFAULT_FORMAT "=> %.6g\n"
-char *format = NULL;
-char *minform = NULL;
-
-workspace_t *programs = NULL;
-int nb_programs = 0;
-
/* compare codes */
int codecmp (char *ref, char *str)
return 0;
}
-/* allocate new element */
-
-element_t *newelement (func_t function, int nbops, int prio)
-{
- element_t *new = (element_t *) calloc (1, sizeof (element_t));
- if (new == NULL) {
- VERBOSE (ERROR, fprintf (stderr, "can't allocate memory\n"));
- exit (1);
- }
- if (nbops) {
- new->ops = (element_t **) calloc (nbops, sizeof (element_t *));
- if (new->ops == NULL) {
- VERBOSE (ERROR, fprintf (stderr, "can't allocate memory\n"));
- exit (1);
- }
- }
- new->func = function;
- new->nbops = nbops;
- new->prio = prio;
-
- return new;
-}
-
-/* desallocate element */
-
-void delelement (element_t *root)
-{
- if ((root != NULL) && (root != ERROR_OP)) {
- int i;
- for (i = 0; i < root->nbops; i++) {
- if ((root->ops[i] != NULL) && (root->ops[i] != ERROR_OP)) {
- delelement (root->ops[i]);
- }
- }
- if (root->nbops) {
- free (root->ops);
- }
- free (root);
- }
-}
-
-/* duplicate element */
-
-element_t *dupelement (element_t *root)
-{
- element_t *tmp = NULL;
- int i;
-
- if ((root == NULL) || (root == ERROR_OP)) {
- return root;
- }
- tmp = newelement (root->func, root->nbops, root->prio);
- tmp->value = root->value;
- for (i = 0; i < root->nbops; i++) {
- tmp->ops[i] = dupelement (root->ops[i]);
- }
- return tmp;
-}
-
/* functions */
+#define MAX_ARGS 100
+
#define NB_OPERATORS 14
keyword_t operators[NB_OPERATORS] = {
{ "+\t", Add, 2, 1, 1},
{ "|", Or, 2, 1, -2}
};
-#define NB_FUNCTIONS 31
+#define NB_FUNCTIONS 50
keyword_t functions[NB_FUNCTIONS] = {
{ "sqrt", Sqr, 1, 4, 5},
{ "pow", Pow, 2, 3, 5},
{ "acos", Acos, 1, 4, 5},
{ "asin", Asin, 1, 4, 5},
{ "atan", Atan, 1, 4, 5},
+ { "ln", Ln, 1, 2, 5},
{ "log", Log, 1, 3, 5},
{ "exp", Exp, 1, 3, 5},
+ { "erfc", Erfc, 1, 4, 5},
+ { "erf", Erf, 1, 3, 5},
{ "abs", Abs, 1, 3, 5},
{ "floor", Floor, 1, 5, 5},
{ "ceil", Ceil, 1, 4, 5},
{ "inc", Inc, 1, 3, 5},
{ "dec", Dec, 1, 3, 5},
{ "disp", Disp, 0, 4, 9},
- { "mem", Mem, 1, 3, 9},
+ { "mem", Mem, 1, 3, 5},
{ "clr", Clear, 0, 3, 9},
{ "quit", Quit, 0, 4, 9},
{ "help", Help, 0, 4, 9},
{ "cond", Cond, 3, 4, 5},
{ "while", While, 2, 5, 5},
{ "print", Print, 1, 5, 5},
- { "prog", Prog, 3, 4, 9},
- { "call", Call, 10, 4, 5},
+ { "prog", Prog, 2, 4, 9},
+ { "arg", Arg, 1, 3, 5},
+ { "call", Call, MAX_ARGS, 4, 5},
{ "ls", List, 0, 2, 9},
{ "edit", Edit, 1, 4, 9},
- { "del", Del, 1, 3, 9}
+ { "del", Del, 1, 3, 9},
+ { "get", Get, 1, 3, 5},
+ { "len", Length, 0, 3, 5},
+ { "pop", Pop, 0, 3, 5},
+ { "push", Push, 1, 4, 5},
+ { "put", Put, 2, 3, 5},
+ { "set", Set, MAX_ARGS, 3, 5},
+ { "show", Show, 0, 4, 5},
+ { "max", Max, 2, 3, 5},
+ { "mean", Mean, 2, 4, 5},
+ { "med", Median, 0, 3, 5},
+ { "min", Min, 2, 3, 5},
+ { "ord", Order, 0, 3, 5},
+ { "prod", Prod, 0, 4, 5},
+ { "sum", Sum, 0, 3, 5},
+ { "var", Variance, 2, 3, 5},
};
#define NB_CONSTANTS 3
element_t *parser (char *str, char **next, int prio)
{
element_t *root = NULL;
+ char *string = str;
int i;
VERBOSE (DEBUG, fprintf (stdout, "Starting parsing\n"));
delelement (root);
return ERROR_OP;
}
- element_t **prog = NULL;
- new = newelement (Code, 0, 5);
- root = new;
- prog = &root;
+ root = newelement (Code, 0, 5);
do {
new = parser (str + 1, &str, 0);
delelement (root);
return ERROR_OP;
}
- element_t *newprog = newelement (Code, (*prog)->nbops + 1, 5);
- for (i = 0; i < (*prog)->nbops; i++) {
- newprog->ops[i] = (*prog)->ops[i];
- (*prog)->ops[i] = NULL;
+ element_t *newcode = newelement (Code, root->nbops + 1, 5);
+ for (i = 0; i < root->nbops; i++) {
+ newcode->ops[i] = root->ops[i];
+ root->ops[i] = NULL;
}
- newprog->ops[(*prog)->nbops] = new;
- delelement (*prog);
- (*prog) = newprog;
+ newcode->ops[root->nbops] = new;
+ delelement (root);
+ root = newcode;
} while (*str == ',');
if (*str != '}') {
keyword_t *operator = operators + i;
if (codecmp (operator->keyword, str) == 0) {
VERBOSE (DEBUG, fprintf (stdout, "start processing operator\n"));
- if (root) {
+ if ((root) && (root->prio == 9)) {
+ VERBOSE (DEBUG, fprintf (stdout, "terminal function (%d)\n", root->func));
+ delelement (root);
+ return ERROR_OP;
+ } else if (root) {
if ((prio) && (prio > operator->prio)) {
VERBOSE (DEBUG, fprintf (stdout, "stop because operator priority\n"));
*next = str;
return ERROR_OP;
}
} else if (*str == '-') {
- root = newelement (Sig, 1, 9);
+ root = newelement (Sig, 1, 6);
} else {
return ERROR_OP;
}
*next = str;
}
+ /* save string */
+ if (root != NULL) {
+ root->string = string;
+ }
+
return root;
}
case Acos: func = "Arc Cosine"; break;
case Asin: func = "Arc Sine"; break;
case Atan: func = "Arc Tangent"; break;
- case Log: func = "Logarithm"; break;
+ case Ln: func = "Logarithm (natural)"; break;
+ case Log: func = "Logarithm (10 base)"; break;
case Exp: func = "Exponantial"; break;
+ case Erfc: func = "Complementary Error Function"; break;
+ case Erf: func = "Error Function"; break;
case Abs: func = "Absolute value"; break;
case Ceil: func = "Ceil value"; break;
case Floor: func = "Floor value"; break;
case Code: func = "Code"; break;
case Print: func = "Print"; break;
case Prog: func = "Program"; break;
+ case Arg: func = "Argument"; break;
case Call: func = "Call"; break;
case List: func = "List"; break;
case Edit: func = "Edit"; break;
case Del: func = "Del"; break;
+ case Get: func = "Get"; break;
+ case Length: func = "Length"; break;
+ case Pop: func = "Pop"; break;
+ case Push: func = "Push"; break;
+ case Put: func = "Put"; break;
+ case Set: func = "Set"; break;
+ case Show: func = "Show"; break;
+ case Max: func = "Maximum"; break;
+ case Mean: func = "Mean"; break;
+ case Median: func = "Median"; break;
+ case Min: func = "Minimum"; break;
+ case Order: func = "Order"; break;
+ case Prod: func = "Product"; break;
+ case Sum: func = "Sum"; break;
+ case Variance: func = "Variance"; break;
}
fprintf (stdout, "Function: %s\n", func);
}
}
-/* storage functions */
-
-void memory (int nb)
-{
- int i, l;
- double *tmp = NULL;
- if (nb != storage_size) {
- l = (nb < storage_size) ? nb : storage_size;
- tmp = (double *) calloc (nb, sizeof (double));
- if (tmp == NULL) {
- VERBOSE (ERROR, fprintf (stderr, "can't allocate memory\n"));
- exit (1);
- }
- for (i = 0; i < l; i++) {
- tmp[i] = storage[i];
- }
- if (storage != NULL) {
- free (storage);
- }
- storage = tmp;
- storage_size = nb;
- }
-}
-
-double store (int index, double value)
-{
- if (storage_size == -1) {
- memory (DEFAULT_STORAGE_SIZE);
- }
- if ((index > 0) && (index <= storage_size)) {
- storage[index - 1] = value;
- } else {
- VERBOSE (WARNING, fprintf (stdout, "invalid index (%d) [%d, %d]\n", index, (storage_size) ? 1 : 0, storage_size));
- }
- return value;
-}
-
-double recall (int index)
-{
- if (storage_size == -1) {
- memory (DEFAULT_STORAGE_SIZE);
- }
- if ((index > 0) && (index <= storage_size)) {
- return storage[index - 1];
- } else {
- VERBOSE (WARNING, fprintf (stdout, "invalid index (%d) [%d, %d]\n", index, (storage_size) ? 1 : 0, storage_size));
- }
- return 0;
-}
-
-double increase (int index)
-{
- if (storage_size == -1) {
- memory (DEFAULT_STORAGE_SIZE);
- }
- if ((index > 0) && (index <= storage_size)) {
- return storage[index - 1]++;
- } else {
- VERBOSE (WARNING, fprintf (stdout, "invalid index (%d) [%d, %d]\n", index, (storage_size) ? 1 : 0, storage_size));
- }
- return 0;
-}
-
-double decrease (int index)
-{
- if (storage_size == -1) {
- memory (DEFAULT_STORAGE_SIZE);
- }
- if ((index > 0) && (index <= storage_size)) {
- return storage[index - 1]--;
- } else {
- VERBOSE (WARNING, fprintf (stdout, "invalid index (%d) [%d, %d]\n", index, (storage_size) ? 1 : 0, storage_size));
- }
- return 0;
-}
-
-void display (void)
-{
- int i;
- if (storage_size == -1) {
- memory (DEFAULT_STORAGE_SIZE);
- }
- fprintf (stdout, "storage:");
- for (i = 0; i < storage_size; i++) {
- fprintf (stdout, " ");
- fprintf (stdout, minform, storage[i]);
- }
- fprintf (stdout, "\n");
-}
-
-void clear ()
-{
- int i;
- for (i = 0; i < storage_size; i++) {
- storage[i] = 0;
- }
-}
-
/* While do function */
double while_do (element_t *cond, element_t *action)
VERBOSE (DEBUG, fprintf (stdout, "loop...\n"));
temp = dupelement (cond);
- if (!evaluate_element (temp, 0)) {
+ double test = evaluate_element (temp, 0);
+ delelement (temp);
+ if (!test) {
break;
}
if (action) {
temp = dupelement (action);
ret = evaluate_element (temp, 0);
+ delelement (temp);
}
}
int i;
for (i = 0; i < nbcalls; i++) {
ret = evaluate_element (prog[i], 0);
- prog[i] = NULL;
}
return ret;
}
-/* print function */
-
-void set_format (char *prompt, int precision)
-{
- char buffer[128] = {0};
- free_format ();
- sprintf (buffer, "%s%%.%dg\n", prompt, precision);
- format = strdup (buffer);
- sprintf (buffer, "%%.%dg", precision);
- minform = strdup (buffer);
-}
-
-void free_format ()
-{
- if (format) {
- free (format);
- format = NULL;
- }
- if (minform) {
- free (minform);
- minform = NULL;
- }
-}
-
-double print (double value)
-{
- fprintf (stdout, format ? format : DEFAULT_FORMAT, value);
- fflush (stdout);
- return value;
-}
-
/* quit function */
void quit (void)
exit (0);
}
-/* program function */
-
-void prog (int id, int nbmems, element_t *root)
-{
- int i, n = -1;
-
- if (programs == NULL) {
-
- /* initial memory allocation */
- programs = (workspace_t *) calloc (1, sizeof (workspace_t));
- if (programs == NULL) {
- VERBOSE (ERROR, fprintf (stderr, "can't allocate memory\n"));
- exit (1);
- }
- nb_programs = 1;
- n = 0;
-
- } else {
-
- /* look for existing program */
- for (i = 0; i < nb_programs; i++) {
- if ((programs + i)->id == id) {
- n = i;
- break;
- }
- }
- if (n == -1) {
-
- /* new program */
- n = nb_programs++;
- programs = (workspace_t *) realloc (programs, nb_programs * sizeof (workspace_t));
- } else {
-
- /* clean old program */
- if ((programs + n)->storage) {
- free ((programs + n)->storage);
- }
- if ((programs + n)->root) {
- delelement ((programs + n)->root);
- }
- }
- }
-
- /* set program */
- (programs + n)->id = id;
- (programs + n)->answer = 0;
- (programs + n)->storage = (double *) calloc (nbmems, sizeof (double));
- if ((programs + n)->storage == NULL) {
- VERBOSE (ERROR, fprintf (stderr, "can't allocate memory\n"));
- exit (1);
- }
- (programs + n)->storage_size = nbmems;
- (programs + n)->root = dupelement (root);
-}
-
-double call (int id, int nbops, element_t **ops)
-{
- workspace_t tmp = {0};
- int i, n = -1;
- double ret = 0;
-
- if (programs) {
-
- /* look for program */
- for (i = 0; i < nb_programs; i++) {
- if ((programs + i)->id == id) {
- n = i;
- break;
- }
- }
- if (n == -1) {
- VERBOSE (WARNING, fprintf (stdout, "error unknown program (%d)\n", id));
- return 0;
- }
-
- /* store context */
- tmp.answer = answer;
- tmp.storage = storage;
- tmp.storage_size = storage_size;
-
- /* change context */
- answer = 0;
- storage = (programs + n)->storage;
- storage_size = (programs + n)->storage_size;
- if (nbops > storage_size) {
- storage = realloc (storage, nbops * sizeof (double));
- storage_size = nbops;
- }
- for (i = 0; i < nbops; i++) {
- double val = evaluate_element (ops[i], 0);
- store (i + 1, val);
- }
-
- /* evaluate program */
- element_t *elements = dupelement ((programs + n)->root);
- ret = evaluate_element (elements, 0);
-
- /* restore context */
- answer = tmp.answer;
- storage = tmp.storage;
- storage_size = tmp.storage_size;
- }
-
- return ret;
-}
-
-void list ()
-{
- int i;
- if (programs != NULL) {
- fprintf (stdout, "programs:");
- for (i = 0; i < nb_programs; i++) {
- fprintf (stdout, " %d", (programs + i)->id);
- }
- fprintf (stdout, "\n");
- }
-}
-
-void edit (int id)
-{ }
-
-void del (int id)
-{ }
-
/* help message */
void help (void)
{
fprintf (stdout, "calc is a simple calculator\n\n");
- fprintf (stdout, "supported operators:");
+ fprintf (stdout, "arithmetic op.:");
fprintf (stdout, " + - * / %% ^\n");
- fprintf (stdout, "camparison operators:");
+ fprintf (stdout, "comparison op.:");
fprintf (stdout, " == != >= <= > <\n");
- fprintf (stdout, "logical operators:");
+ fprintf (stdout, "logical op.:");
fprintf (stdout, " & | !\n");
- fprintf (stdout, "mathematic functions:");
- fprintf (stdout, " pow sqrt log exp\n");
- fprintf (stdout, "trig. func.:");
- fprintf (stdout, " cos sin tan acos asin atan\n");
- fprintf (stdout, "supported functions:");
+ fprintf (stdout, "mathematic func.:");
+ fprintf (stdout, " exp ln log pow sqrt\n");
+ fprintf (stdout, "trigonometric func.:");
+ fprintf (stdout, " acos asin atan cos sin tan\n");
+ fprintf (stdout, "error functions:");
+ fprintf (stdout, " erf erfc\n");
+ fprintf (stdout, "miscellaneous func.:");
fprintf (stdout, " abs ceil floor\n");
- fprintf (stdout, "storage functions:");
- fprintf (stdout, " mem sto rcl inc dec disp\n");
- fprintf (stdout, "prog. functions:");
- fprintf (stdout, " cond while print {} ;\n");
- fprintf (stdout, "misc. functions:");
- fprintf (stdout, " quit help\n");
- fprintf (stdout, "supported constants:");
- fprintf (stdout, " e pi\n");
+ fprintf (stdout, "storage func.:");
+ fprintf (stdout, " clear dec disp inc mem rcl sto\n");
+ fprintf (stdout, "control flow prim.:");
+ fprintf (stdout, " cond print while {} ;\n");
+ fprintf (stdout, "program management:");
+ fprintf (stdout, " arg call del edit ls prog\n");
+ fprintf (stdout, "stack management:");
+ fprintf (stdout, " get len pop push put set show\n");
+ fprintf (stdout, "stack func.:");
+ fprintf (stdout, " max mean med min ord prod sum var\n");
+ fprintf (stdout, "control management:");
+ fprintf (stdout, " help quit\n");
+ fprintf (stdout, "constants:");
+ fprintf (stdout, " ans e pi\n");
}
/* evaluate element tree */
case Lt:
case And:
case Or:
- case Prog:
if (root->ops[1]) {
op1 = evaluate_element (root->ops[1], nextmask);
} else if (root->func != Store) {
case Acos:
case Asin:
case Atan:
+ case Ln:
case Log:
case Exp:
+ case Erfc:
+ case Erf:
case Abs:
case Ceil:
case Floor:
case Not:
case Mem:
case Cond:
+ case Prog:
+ case Arg:
case Call:
case Edit:
case Del:
+ case Get:
if (root->ops[0]) {
op0 = evaluate_element (root->ops[0], 0);
} else {
case E:
case Code:
case List:
+ case Length:
+ case Pop:
+ case Set:
+ case Show:
+ case Median:
+ case Order:
+ case Prod:
+ case Sum:
break;
case While:
if (root->ops[0] == NULL) {
return 0;
}
break;
+ case Push:
case Print:
op0 = (root->ops[0]) ? evaluate_element (root->ops[0], 0) : answer;
break;
+ case Put:
+ if (root->ops[0]) {
+ op0 = evaluate_element (root->ops[0], 0);
+ } else {
+ VERBOSE (WARNING, fprintf (stdout, "error while evaluating (op[0])\n"));
+ return 0;
+ }
+ op1 = (root->ops[1]) ? evaluate_element (root->ops[1], 0) : answer;
+ break;
+ case Max:
+ case Mean:
+ case Min:
+ case Variance:
+ if (root->ops[0]) {
+ op0 = evaluate_element (root->ops[0], 0);
+ op1 = (root->ops[1]) ? evaluate_element (root->ops[1], 0) : answer;
+ }
}
switch (root->func) {
case Acos: return acos (op0);
case Asin: return asin (op0);
case Atan: return atan (op0);
- case Log: return log (op0);
+ case Ln: return log (op0);
+ case Log: return log10 (op0);
case Exp: return exp (op0);
+ case Erfc: return erfc (op0);
+ case Erf: return erf (op0);
case Abs: return fabs (op0);
case Ceil: return ceil (op0);
case Floor: return floor (op0);
case While: return while_do (root->ops[0], root->ops[1]);
case Code: return execute_code (root->ops, root->nbops);
case Print: return print (op0);
- case Prog: prog ((int)op0, (int)op1, root->ops[2]); break;
+ case Prog:
+ prog ((int)op0, root->ops[1]);
+ savestring ((int)op0, root->string);
+ break;
+ case Arg: return arg ((int)op0);
case Call:
for (i = 1, nb =0; i < root->nbops; i++) {
if (root->ops[i]) {
case List: list (); break;
case Edit: edit ((int)op0); break;
case Del: del ((int)op0); break;
+ case Get: return get ((int)op0);
+ case Length: return length ();
+ case Pop: return pop ();
+ case Push: return push (op0);
+ case Put: return put ((int)op0, op1);
+ case Set:
+ for (i = 0, nb =0; i < root->nbops; i++) {
+ if (root->ops[i]) {
+ nb++;
+ }
+ }
+ return set (nb, root->ops);
+ case Show: show (); break;
+ case Max:
+ if (root->ops[0]) {
+ return op0 > op1 ? op0 : op1;
+ }
+ return max ();
+ case Mean:
+ if (root->ops[0]) {
+ return (op0 + op1) / 2;
+ }
+ return mean ();
+ case Median: return median ();
+ case Min:
+ if (root->ops[0]) {
+ return op0 < op1 ? op0 : op1;
+ }
+ return min ();
+ case Order: order (); break;
+ case Prod: return prod ();
+ case Sum: return sum ();
+ case Variance:
+ if (root->ops[0]) {
+ double m = (op0 + op1) / 2;
+ op0 -= m;
+ op1 -= m;
+ return op0 * op0 + op1 * op1;
+ }
+ return variance ();
}
return 0;
char **generate_completion_list ()
{
int i, j, l = 0;
- char **list = (char **) calloc (NB_OPERATORS + NB_FUNCTIONS + NB_CONSTANTS + NB_SYMBOLS + 1, sizeof (char *));
- if (list == NULL) {
- VERBOSE (ERROR, fprintf (stderr, "can't allocate memory\n"));
- exit (1);
- }
+ char **list = (char **) callocordie (NB_OPERATORS + NB_FUNCTIONS + NB_CONSTANTS + NB_SYMBOLS + 1, sizeof (char *));
for (i = 0; i < NB_OPERATORS; i++) {
list[l] = strdup ((operators + i)->keyword);
int i;
if (list) {
- for (i = 0; i < NB_FUNCTIONS + NB_CONSTANTS; i++) {
+ for (i = 0; i < NB_OPERATORS + NB_FUNCTIONS + NB_CONSTANTS + NB_SYMBOLS + 1; i++) {
if (list[i] != NULL) {
free (list[i]);
}
}
}
-
/* vim: set ts=4 sw=4 et: */
Soft'N'Design Software / projects / calc.git / blobdiff