eigenmath/userfunc.cpp

352 lines
5.3 KiB
C++

#include "stdafx.h"
#include "defs.h"
extern U *formal_arg[6];
//-----------------------------------------------------------------------------
//
// Example: f(x) = x^2
//
// p1 *-------*---------------*
// | | |
// setq *-------* *-------*-------*
// | | | | |
// f x power x 2
//
//-----------------------------------------------------------------------------
#define NAME p2
#define ARGS p3
#define BODY p4
#define BODY2 p5
#define TMP p6
void
define_user_function(void)
{
int i, n;
NAME = caadr(p1);
ARGS = cdadr(p1);
BODY = caddr(p1);
if (!issymbol(NAME))
stop("in function definition, user symbol expected for function name");
n = length(ARGS);
if (n > 6)
stop("more than 6 formal args in function definition");
// subst args in body
push(BODY);
TMP = ARGS;
for (i = 0; i < n; i++) {
if (!issymbol(car(TMP)))
stop("in function definition, formal arg is not a user symbol");
push(car(TMP));
push(formal_arg[i]);
subst();
TMP = cdr(TMP);
}
BODY2 = pop();
// binding
NAME->u.sym.binding = BODY;
NAME->u.sym.binding2 = BODY2;
// do eval, maybe
if (car(BODY) == symbol(EVAL)) {
// remove eval
NAME->u.sym.binding = cadr(BODY);
NAME->u.sym.binding2 = cadr(BODY2);
// build function call with quoted symbols
push(NAME);
TMP = ARGS;
for (i = 0; i < n; i++) {
push_symbol(QUOTE);
push(car(TMP));
list(2);
TMP = cdr(TMP);
}
list(n + 1);
// eval
eval();
BODY = pop();
// subst args in body
push(BODY);
TMP = ARGS;
for (i = 0; i < n; i++) {
push(car(TMP));
push(formal_arg[i]);
subst();
TMP = cdr(TMP);
}
BODY2 = pop();
// update bindings
NAME->u.sym.binding = BODY;
NAME->u.sym.binding2 = BODY2;
}
push(symbol(NIL)); // return value
}
// Note: Tried doing func eval above using formal_arg and then back subst
// symbols from ARGLIST.
// The problem with this method is that the resulting BODY might be
// denormalized.
// In other words, the terms and factors are not sorted properly.
// This causes problems since add() and multiply() use a merge sort that
// requires sorted (normalized) terms and factors.
// The code above ensures a normalized BODY.
//-----------------------------------------------------------------------------
//
// Example: f(x,y)
//
// p1 -> (f x y)
//
// car(p1) -> f
//
//-----------------------------------------------------------------------------
#define FUNC_NAME p2
#define ACTUAL_ARGLIST p3
void
eval_user_function(void)
{
int h, i;
h = tos;
FUNC_NAME = car(p1);
ACTUAL_ARGLIST = cdr(p1);
// undefined function?
if (FUNC_NAME->u.sym.binding == FUNC_NAME) {
push(FUNC_NAME);
while (iscons(ACTUAL_ARGLIST)) {
push(car(ACTUAL_ARGLIST));
eval();
ACTUAL_ARGLIST = cdr(ACTUAL_ARGLIST);
}
list(tos - h);
return;
}
// is it a function?
if (FUNC_NAME->u.sym.binding2 == symbol(NIL))
stop("Attempt to call non-function");
// eval actual args in current formal arg context, don't modify formal args yet
for (i = 0; i < 6; i++) {
push(car(ACTUAL_ARGLIST));
eval();
ACTUAL_ARGLIST = cdr(ACTUAL_ARGLIST);
push(symbol(NIL)); // make room for saving binding2
}
// ok, now it's safe to modify formal args
for (i = 0; i < 6; i++) {
TMP = formal_arg[i]->u.sym.binding;
formal_arg[i]->u.sym.binding = stack[h + 2 * i];
stack[h + 2 * i] = TMP;
TMP = formal_arg[i]->u.sym.binding2;
formal_arg[i]->u.sym.binding2 = stack[h + 2 * i + 1];
stack[h + 2 * i + 1] = TMP;
}
// evaluate user-defined function
push(FUNC_NAME->u.sym.binding2);
eval();
// restore args
TMP = pop();
for (i = 0; i < 6; i++) {
formal_arg[5 - i]->u.sym.binding2 = pop();
formal_arg[5 - i]->u.sym.binding = pop();
}
push(TMP);
}
void
eval_binding2(void)
{
p1 = cadr(p1);
if (!issymbol(p1))
stop("symbol expected in binding2");
push(p1->u.sym.binding2);
}
//-----------------------------------------------------------------------------
//
// Evaluate an expression with a symbol set to a value.
//
// Input: tos-3 expr
//
// tos-2 symbol
//
// tos-1 value
//
// Output: Result on stack
//
//-----------------------------------------------------------------------------
#define F p1
#define X p2
#define VAL p3
void
evalat(void)
{
int mark;
save();
VAL = pop();
X = pop();
if (!issymbol(X)) {
push(X);
push(VAL);
subst();
eval();
restore();
return;
}
push(X);
mark = save_symbols(1);
X->u.sym.binding = VAL;
X->u.sym.binding2 = symbol(NIL);
eval();
restore_symbols(mark);
restore();
}
static char *s[] = {
"f=quote(f)",
"",
"x=quote(x)",
"",
"y=quote(y)",
"",
// args of generic functions should be evaluated
"f(1+2,3*4)",
"f(3,12)",
// simple func def
"f(x)=x^2",
"",
"f",
"x^2",
"binding2(f)",
"$1^2",
// symbols should be quoted in eval
"x=123",
"",
"f(x)=eval(x^3)",
"",
"f",
"x^3",
// bindings should be restored
"x=123",
"",
"y=345",
"",
"f(x,y)=x^2+y^3",
"",
"f(2,3)",
"31",
"x",
"123",
"y",
"345",
// as above but this time with function bindings
"x(a)=sin(a)",
"",
"y(b)=cos(b)",
"",
"f(x,y)=x^2+y^3",
"",
"f(2,3)",
"31",
"x",
"sin(a)",
"binding2(x)",
"sin($1)",
"y",
"cos(b)",
"binding2(y)",
"cos($1)",
// clean up
"f=quote(f)",
"",
"x=quote(x)",
"",
"y=quote(y)",
"",
};
void
test_user_func(void)
{
test(__FILE__, s, sizeof s / sizeof (char *));
}