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#include "exc.h"
#include "consts.h"
#include "builtin.h"
#include "model.h"
#include "exc.h"
#include <cstdio>
#include <sstream>
#include <cctype>
#include <cstdlib>
using std::stringstream;
extern EmptyList *empty_list;
static const int NUM_LVL_COMP = 0;
static const int NUM_LVL_REAL = 1;
static const int NUM_LVL_RAT = 2;
static const int NUM_LVL_INT = 3;
string double_to_str(double val, bool force_sign = false) {
stringstream ss;
if (force_sign) ss << std::showpos;
ss << val;
return ss.str();
}
string int_to_str(int val) {
stringstream ss;
ss << val;
return ss.str();
}
double str_to_double(string repr, bool &flag) {
const char *nptr = repr.c_str();
char *endptr;
double val = strtod(nptr, &endptr);
if (endptr != nptr + repr.length())
{
flag = false;
return 0;
}
flag = true;
return val;
}
int gcd(int a, int b) {
int t;
while (b) t = b, b = a % b, a = t;
return abs(a);
}
InexactNumObj::InexactNumObj(NumLvl level) : NumObj(level, false) {}
CompNumObj::CompNumObj(double _real, double _imag) :
InexactNumObj(NUM_LVL_COMP), real(_real), imag(_imag) {}
CompNumObj *CompNumObj::from_string(string repr) {
// spos: the position of the last sign
// ipos: the position of i
int spos = -1, ipos = -1,
len = repr.length();
bool sign;
for (int i = 0; i < len; i++)
if (repr[i] == '+' || repr[i] == '-')
{
spos = i;
sign = repr[i] == '-';
}
else if (repr[i] == 'i' || repr[i] == 'I')
ipos = i;
if (spos == -1 || ipos == -1 || !(spos < ipos))
return NULL;
bool flag;
double real = 0, imag = 1;
if (spos > 0)
{
real = str_to_double(repr.substr(0, spos), flag);
if (!flag) return NULL;
}
if (ipos > spos + 1)
{
imag = str_to_double(repr.substr(spos + 1, ipos - spos - 1), flag);
if (!flag) return NULL;
}
if (sign) imag = -imag;
return new CompNumObj(real, imag);
}
CompNumObj *CompNumObj::convert(NumObj *obj) {
switch (obj->level)
{
case NUM_LVL_COMP :
return static_cast<CompNumObj*>(obj); break;
case NUM_LVL_REAL :
return new CompNumObj(static_cast<RealNumObj*>(obj)->real, 0);
break;
case NUM_LVL_RAT :
{
RatNumObj *rat = static_cast<RatNumObj*>(obj);
return new CompNumObj(rat->a / double(rat->b), 0);
break;
}
case NUM_LVL_INT :
return new CompNumObj(static_cast<IntNumObj*>(obj)->val, 0);
}
throw NormalError(INT_ERR);
}
#define A (real)
#define B (imag)
#define C (r->real)
#define D (r->imag)
NumObj *CompNumObj::plus(NumObj *_r) {
CompNumObj *r = static_cast<CompNumObj*>(_r);
return new CompNumObj(A + C, B + D);
}
NumObj *CompNumObj::minus(NumObj *_r) {
CompNumObj *r = static_cast<CompNumObj*>(_r);
return new CompNumObj(A - C, B - D);
}
NumObj *CompNumObj::multi(NumObj *_r) {
CompNumObj *r = static_cast<CompNumObj*>(_r);
return new CompNumObj(A * C - B * D,
B * C + A * D);
}
NumObj *CompNumObj::div(NumObj *_r) {
CompNumObj *r = static_cast<CompNumObj*>(_r);
double f = 1.0 / (C * C + D * D);
return new CompNumObj((A * C + B * D) * f,
(B * C - A * D) * f);
}
bool CompNumObj::lt(NumObj *_r) {
throw TokenError("a comparable number", RUN_ERR_WRONG_TYPE);
}
bool CompNumObj::gt(NumObj *_r) {
throw TokenError("a comparable number", RUN_ERR_WRONG_TYPE);
}
bool CompNumObj::eq(NumObj *_r) {
CompNumObj *r = static_cast<CompNumObj*>(_r);
return A == C && B == D; // TODO: more proper judgement
}
string CompNumObj::ext_repr() {
return double_to_str(real) + double_to_str(imag, true) + "i";
}
#undef A
#undef B
#undef C
#undef D
RealNumObj::RealNumObj(double _real) : InexactNumObj(NUM_LVL_REAL), real(_real) {}
RealNumObj *RealNumObj::from_string(string repr) {
bool flag;
double real = str_to_double(repr, flag);
if (!flag) return NULL;
return new RealNumObj(real);
}
RealNumObj *RealNumObj::convert(NumObj *obj) {
switch (obj->level)
{
case NUM_LVL_REAL:
return static_cast<RealNumObj*>(obj); break;
case NUM_LVL_RAT:
{
RatNumObj *rat = static_cast<RatNumObj*>(obj);
return new RealNumObj(rat->a / double(rat->b));
break;
}
case NUM_LVL_INT:
return new RealNumObj(static_cast<IntNumObj*>(obj)->val);
}
throw NormalError(INT_ERR);
}
NumObj *RealNumObj::plus(NumObj *_r) {
return new RealNumObj(real + static_cast<RealNumObj*>(_r)->real);
}
NumObj *RealNumObj::minus(NumObj *_r) {
return new RealNumObj(real - static_cast<RealNumObj*>(_r)->real);
}
NumObj *RealNumObj::multi(NumObj *_r) {
return new RealNumObj(real * static_cast<RealNumObj*>(_r)->real);
}
NumObj *RealNumObj::div(NumObj *_r) {
return new RealNumObj(real / static_cast<RealNumObj*>(_r)->real);
}
bool RealNumObj::eq(NumObj *_r) {
return real == static_cast<RealNumObj*>(_r)->real;
}
bool RealNumObj::lt(NumObj *_r) {
return real < static_cast<RealNumObj*>(_r)->real;
}
bool RealNumObj::gt(NumObj *_r) {
return real > static_cast<RealNumObj*>(_r)->real;
}
string RealNumObj::ext_repr() {
return double_to_str(real);
}
ExactNumObj::ExactNumObj(NumLvl level) : NumObj(level, true) {}
RatNumObj::RatNumObj(int _a, int _b) :
ExactNumObj(NUM_LVL_RAT), a(_a), b(_b) {
int g = gcd(a, b);
a /= g;
b /= g;
}
RatNumObj *RatNumObj::from_string(string repr) {
int a, b;
if (sscanf(repr.c_str(), "%d/%d", &a, &b) != 2)
return NULL;
return new RatNumObj(a, b);
}
RatNumObj *RatNumObj::convert(NumObj *obj) {
switch (obj->level)
{
case NUM_LVL_RAT:
return static_cast<RatNumObj*>(obj); break;
case NUM_LVL_INT:
return new RatNumObj(static_cast<IntNumObj*>(obj)->val, 1);
}
throw NormalError(INT_ERR);
}
#define A (a)
#define B (b)
#define C (r->a)
#define D (r->b)
NumObj *RatNumObj::plus(NumObj *_r) {
RatNumObj *r = static_cast<RatNumObj*>(_r);
int na = A * D + B * C, nb = B * D;
int g = gcd(na, nb);
na /= g;
nb /= g;
return new RatNumObj(na, nb);
}
NumObj *RatNumObj::minus(NumObj *_r) {
RatNumObj *r = static_cast<RatNumObj*>(_r);
int na = A * D - B * C, nb = B * D;
int g = gcd(na, nb);
na /= g;
nb /= g;
return new RatNumObj(na, nb);
}
NumObj *RatNumObj::multi(NumObj *_r) {
RatNumObj *r = static_cast<RatNumObj*>(_r);
int na = A * C, nb = B * D;
int g = gcd(na, nb);
na /= g;
nb /= g;
return new RatNumObj(na, nb);
}
NumObj *RatNumObj::div(NumObj *_r) {
RatNumObj *r = static_cast<RatNumObj*>(_r);
int na = A * D, nb = B * C;
int g = gcd(na, nb);
na /= g;
nb /= g;
return new RatNumObj(na, nb);
}
bool RatNumObj::lt(NumObj *_r) {
RatNumObj *r = static_cast<RatNumObj*>(_r);
return A * D < C * B;
}
bool RatNumObj::gt(NumObj *_r) {
RatNumObj *r = static_cast<RatNumObj*>(_r);
return A * D > C * B;
}
bool RatNumObj::eq(NumObj *_r) {
RatNumObj *r = static_cast<RatNumObj*>(_r);
return A * D == C * B;
}
string RatNumObj::ext_repr() {
return int_to_str(A) + "/" + int_to_str(B);
}
IntNumObj::IntNumObj(int _val) : ExactNumObj(NUM_LVL_INT), val(_val) {}
IntNumObj *IntNumObj::from_string(string repr) {
int val = 0;
for (int i = 0; i < repr.length(); i++)
{
if (!('0' <= repr[i] && repr[i] <= '9'))
return NULL;
val = val * 10 + repr[i] - '0';
}
return new IntNumObj(val);
}
IntNumObj *IntNumObj::convert(NumObj *obj) {
switch (obj->level)
{
case NUM_LVL_INT :
return static_cast<IntNumObj*>(obj);
default:
throw NormalError(INT_ERR);
}
}
NumObj *IntNumObj::plus(NumObj *_r) {
return new IntNumObj(val + static_cast<IntNumObj*>(_r)->val);
}
NumObj *IntNumObj::minus(NumObj *_r) {
return new IntNumObj(val - static_cast<IntNumObj*>(_r)->val);
}
NumObj *IntNumObj::multi(NumObj *_r) {
return new IntNumObj(val * static_cast<IntNumObj*>(_r)->val);
}
NumObj *IntNumObj::div(NumObj *_r) {
return new IntNumObj(val / static_cast<IntNumObj*>(_r)->val);
}
bool IntNumObj::lt(NumObj *_r) {
return val < static_cast<IntNumObj*>(_r)->val;
}
bool IntNumObj::gt(NumObj *_r) {
return val > static_cast<IntNumObj*>(_r)->val;
}
bool IntNumObj::eq(NumObj *_r) {
return val == static_cast<IntNumObj*>(_r)->val;
}
string IntNumObj::ext_repr() {
return int_to_str(val);
}
SpecialOptIf::SpecialOptIf() : SpecialOptObj() {}
void SpecialOptIf::prepare(Cons *pc) {
state = 0; // Prepared
pc = TO_CONS(pc->cdr);
if (pc == empty_list)
throw TokenError("if", SYN_ERR_MISS_OR_EXTRA_EXP);
pc->skip = false;
pc = TO_CONS(pc->cdr);
if (pc == empty_list)
throw TokenError("if", SYN_ERR_MISS_OR_EXTRA_EXP);
pc->skip = true;
if (pc->cdr != empty_list)
TO_CONS(pc->cdr)->skip = true;
}
void SpecialOptIf::pre_call(ArgList *args, Cons *pc,
Environment *envt) {
// static_cast because it's a call invocation
pc = TO_CONS(TO_CONS(pc->car)->cdr);
// Condition evaluated and the decision is made
state = 1;
if (TO_CONS(args->cdr)->car->is_true())
{
pc->skip = true;
pc = TO_CONS(pc->cdr);
pc->skip = false;
if (pc->cdr != empty_list)
TO_CONS(pc->cdr)->skip = true; // Eval the former
}
else
{
pc->skip = true;
pc = TO_CONS(pc->cdr);
TO_CONS(pc->cdr)->skip = true;
if (pc->cdr != empty_list)
TO_CONS(pc->cdr)->skip = false; //Eval the latter
}
}
EvalObj *SpecialOptIf::post_call(ArgList *args, Cons *pc,
Environment *envt) {
// Value already evaluated, so just return it
return TO_CONS(args->cdr)->car;
}
Cons *SpecialOptIf::call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr) {
Cons *ret_addr = static_cast<RetAddr*>(*top_ptr)->addr;
if (state)
{
*top_ptr++ = post_call(args, ret_addr, envt);
return ret_addr->next; // Move to the next instruction
}
else
{
pre_call(args, ret_addr, envt);
top_ptr += 2;
// Undo pop and invoke again
// static_cast because it's a call invocation
return static_cast<Cons*>(ret_addr->car)->next;
}
}
string SpecialOptIf::ext_repr() { return string("#<Builtin Macro: if>"); }
SpecialOptLambda::SpecialOptLambda() : SpecialOptObj() {}
#define FILL_MARKS(pc, flag) \
for (Cons *ptr = TO_CONS(pc->cdr); \
ptr != empty_list; ptr = TO_CONS(ptr->cdr)) \
ptr->skip = flag
void SpecialOptLambda::prepare(Cons *pc) {
//TODO check number of arguments
// Do not evaluate anything
FILL_MARKS(pc, true);
}
Cons *SpecialOptLambda::call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr) {
Cons *ret_addr = static_cast<RetAddr*>(*top_ptr)->addr;
Cons *pc = static_cast<Cons*>(ret_addr->car);
if (pc->cdr == empty_list)
throw TokenError("lambda", SYN_ERR_EMPTY_PARA_LIST);
if (TO_CONS(pc->cdr)->cdr == empty_list)
throw TokenError("lambda", SYN_ERR_MISS_OR_EXTRA_EXP);
SymbolList *para_list = static_cast<SymbolList*>(TO_CONS(pc->cdr)->car);
// Clear the flag to avoid side-effects (e.g. proc calling)
FILL_MARKS(pc, false);
// store a list of expressions inside <body>
ASTList *body = TO_CONS(TO_CONS(pc->cdr)->cdr); // Truncate the expression list
for (Cons *ptr = body; ptr != empty_list; ptr = TO_CONS(ptr->cdr))
ptr->next = NULL; // Make each expression an orphan
*top_ptr++ = new ProcObj(body, envt, para_list);
return ret_addr->next; // Move to the next instruction
}
string SpecialOptLambda::ext_repr() { return string("#<Builtin Macro: lambda>"); }
SpecialOptDefine::SpecialOptDefine() : SpecialOptObj() {}
void SpecialOptDefine::prepare(Cons *pc) {
if (pc->cdr == empty_list)
throw TokenError("define", SYN_ERR_MISS_OR_EXTRA_EXP);
if (TO_CONS(pc->cdr)->car->is_simple_obj()) // Simple value assignment
{
pc = TO_CONS(pc->cdr);
if (pc->cdr == empty_list)
throw TokenError("define", SYN_ERR_MISS_OR_EXTRA_EXP);
pc->skip = true; // Skip the identifier
TO_CONS(pc->cdr)->skip = false;
} // Procedure definition
else FILL_MARKS(pc, true); // Skip all parts
}
Cons *SpecialOptDefine::call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr) {
Cons *ret_addr = static_cast<RetAddr*>(*top_ptr)->addr;
Cons *pc = static_cast<Cons*>(ret_addr->car);
EvalObj *obj;
SymObj *id;
// TODO: check identifier
EvalObj *first = TO_CONS(pc->cdr)->car;
if (first->is_simple_obj())
{
if (!first->is_sym_obj())
throw TokenError(first->ext_repr(), SYN_ERR_NOT_AN_ID);
id = static_cast<SymObj*>(first);
obj = TO_CONS(args->cdr)->car;
}
else
{
// static_cast because of is_simple_obj() is false
Cons *plst = static_cast<Cons*>(TO_CONS(pc->cdr)->car);
if (plst == empty_list)
throw TokenError("if", SYN_ERR_EMPTY_PARA_LIST);
if (!plst->car->is_sym_obj())
throw TokenError(first->ext_repr(), SYN_ERR_NOT_AN_ID);
id = static_cast<SymObj*>(plst->car);
ArgList *para_list = TO_CONS(plst->cdr);
// Clear the flag to avoid side-effects (e.g. proc calling)
FILL_MARKS(pc, false);
ASTList *body = TO_CONS(TO_CONS(pc->cdr)->cdr); // Truncate the expression list
if (body == empty_list)
throw TokenError("define", SYN_ERR_MISS_OR_EXTRA_EXP);
for (Cons *ptr = body; ptr != empty_list; ptr = TO_CONS(ptr->cdr))
ptr->next = NULL; // Make each expression a orphan
obj = new ProcObj(body, envt, para_list);
}
envt->add_binding(id, obj);
*top_ptr++ = new UnspecObj();
return ret_addr->next;
}
string SpecialOptDefine::ext_repr() { return string("#<Builtin Macro: define>"); }
void SpecialOptSet::prepare(Cons *pc) {
pc = TO_CONS(pc->cdr);
if (pc == empty_list)
throw TokenError("set!", SYN_ERR_MISS_OR_EXTRA_EXP);
pc->skip = true; // Skip the identifier
pc = TO_CONS(pc->cdr);
if (pc == empty_list)
throw TokenError("set!", SYN_ERR_MISS_OR_EXTRA_EXP);
pc->skip = false;
}
Cons *SpecialOptSet::call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr) {
Cons *ret_addr = static_cast<RetAddr*>(*top_ptr)->addr;
Cons *pc = static_cast<Cons*>(ret_addr->car);
EvalObj *first = TO_CONS(pc->cdr)->car;
if (!first->is_sym_obj())
throw TokenError(first->ext_repr(), SYN_ERR_NOT_AN_ID);
SymObj *id = static_cast<SymObj*>(first);
bool flag = envt->add_binding(id, TO_CONS(args->cdr)->car, false);
if (!flag) throw TokenError(id->ext_repr(), RUN_ERR_UNBOUND_VAR);
*top_ptr++ = new UnspecObj();
return ret_addr->next;
}
SpecialOptSet::SpecialOptSet() {}
string SpecialOptSet::ext_repr() { return string("#<Builtin Macro: set!>"); }
EvalObj *builtin_cons(ArgList *args) {
if (args == empty_list ||
args->cdr == empty_list ||
TO_CONS(args->cdr)->cdr != empty_list)
throw TokenError("cons", RUN_ERR_WRONG_NUM_OF_ARGS);
return new Cons(args->car, TO_CONS(args->cdr)->car);
}
EvalObj *builtin_car(ArgList *args) {
if (args == empty_list ||
args->cdr != empty_list)
throw TokenError("car", RUN_ERR_WRONG_NUM_OF_ARGS);
if (args->car == empty_list || !args->car->is_cons_obj())
throw TokenError("pair", RUN_ERR_WRONG_TYPE);
return TO_CONS(args->car)->car;
}
EvalObj *builtin_cdr(ArgList *args) {
if (args == empty_list ||
args->cdr != empty_list)
throw TokenError("cdr", RUN_ERR_WRONG_NUM_OF_ARGS);
if (args->car == empty_list || !args->car->is_cons_obj())
throw TokenError("pair", RUN_ERR_WRONG_TYPE);
return TO_CONS(args->car)->cdr;
}
EvalObj *builtin_list(ArgList *args) {
return args;
}
EvalObj *builtin_plus(ArgList *args) {
NumObj *res = new IntNumObj(0), *opr; // the most accurate type
for (Cons *ptr = args; ptr != empty_list; ptr = TO_CONS(ptr->cdr))
{
if (!ptr->car->is_num_obj()) // not a number
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
opr = static_cast<NumObj*>(ptr->car);
NumObj *_res = res;
if (_res->level < opr->level)
opr = _res->convert(opr);
else
_res = opr->convert(_res);
res = _res->plus(opr);
}
return res;
}
EvalObj *builtin_minus(ArgList *args) {
if (args == empty_list)
throw TokenError("-", RUN_ERR_WRONG_NUM_OF_ARGS);
if (!args->car->is_num_obj())
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
NumObj *res = static_cast<NumObj*>(args->car), *opr;
for (Cons *ptr = TO_CONS(args->cdr);
ptr != empty_list; ptr = TO_CONS(ptr->cdr))
{
if (!ptr->car->is_num_obj()) // not a number
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
opr = static_cast<NumObj*>(ptr->car);
// upper type conversion
NumObj *_res = res;
if (_res->level < opr->level)
opr = _res->convert(opr);
else
_res = opr->convert(_res);
res = _res->minus(opr);
}
return res;
}
EvalObj *builtin_multi(ArgList *args) {
NumObj *res = new IntNumObj(1), *opr; // the most accurate type
for (Cons *ptr = args; ptr != empty_list; ptr = TO_CONS(ptr->cdr))
{
if (!ptr->car->is_num_obj()) // not a number
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
opr = static_cast<NumObj*>(ptr->car);
NumObj *_res = res;
if (_res->level < opr->level)
opr = _res->convert(opr);
else
_res = opr->convert(_res);
res = _res->multi(opr);
}
return res;
}
EvalObj *builtin_div(ArgList *args) {
if (args == empty_list)
throw TokenError("/", RUN_ERR_WRONG_NUM_OF_ARGS);
if (!args->car->is_num_obj())
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
NumObj *res = static_cast<NumObj*>(args->car), *opr;
for (Cons *ptr = TO_CONS(args->cdr);
ptr != empty_list; ptr = TO_CONS(ptr->cdr))
{
if (!ptr->car->is_num_obj()) // not a number
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
opr = static_cast<NumObj*>(ptr->car);
// upper type conversion
NumObj *_res = res;
if (_res->level < opr->level)
opr = _res->convert(opr);
else
_res = opr->convert(_res);
res = _res->div(opr);
}
return res;
}
EvalObj *builtin_lt(ArgList *args) {
if (args == empty_list)
throw TokenError("<", RUN_ERR_WRONG_NUM_OF_ARGS);
if (!args->car->is_num_obj())
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
NumObj *last = static_cast<NumObj*>(args->car), *opr;
for (Cons *ptr = TO_CONS(args->cdr);
ptr != empty_list; ptr = TO_CONS(ptr->cdr), last = opr)
{
if (!ptr->car->is_num_obj()) // not a number
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
opr = static_cast<NumObj*>(ptr->car);
// upper type conversion
if (last->level < opr->level)
opr = last->convert(opr);
else
last = opr->convert(last);
if (!last->lt(opr))
return new BoolObj(false);
}
return new BoolObj(true);
}
EvalObj *builtin_gt(ArgList *args) {
if (args == empty_list)
throw TokenError(">", RUN_ERR_WRONG_NUM_OF_ARGS);
if (!args->car->is_num_obj())
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
NumObj *last = static_cast<NumObj*>(args->car), *opr;
for (Cons *ptr = TO_CONS(args->cdr);
ptr != empty_list; ptr = TO_CONS(ptr->cdr), last = opr)
{
if (!ptr->car->is_num_obj()) // not a number
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
opr = static_cast<NumObj*>(ptr->car);
// upper type conversion
if (last->level < opr->level)
opr = last->convert(opr);
else
last = opr->convert(last);
if (!last->gt(opr))
return new BoolObj(false);
}
return new BoolObj(true);
}
EvalObj *builtin_arithmetic_eq(ArgList *args) {
if (args == empty_list)
throw TokenError("=", RUN_ERR_WRONG_NUM_OF_ARGS);
if (!args->car->is_num_obj())
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
NumObj *last = static_cast<NumObj*>(args->car), *opr;
for (Cons *ptr = TO_CONS(args->cdr);
ptr != empty_list; ptr = TO_CONS(ptr->cdr), last = opr)
{
if (!ptr->car->is_num_obj()) // not a number
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
opr = static_cast<NumObj*>(ptr->car);
// upper type conversion
if (last->level < opr->level)
opr = last->convert(opr);
else
last = opr->convert(last);
if (!last->eq(opr))
return new BoolObj(false);
}
return new BoolObj(true);
}
EvalObj *builtin_exact(ArgList *args) {
if (args == empty_list ||
args->cdr != empty_list)
throw TokenError("(in)exact?", RUN_ERR_WRONG_NUM_OF_ARGS);
if (!args->car->is_num_obj())
throw TokenError("a number", RUN_ERR_WRONG_TYPE);
return new BoolObj(static_cast<NumObj*>(args->car)->is_exact());
}
EvalObj *builtin_inexact(ArgList *args) {
BoolObj *ret = static_cast<BoolObj*>(builtin_exact(args));
ret->val = !ret->val;
return ret;
}
EvalObj *builtin_display(ArgList *args) {
printf("%s\n", args->car->ext_repr().c_str());
return new UnspecObj();
}
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