#ifndef BUILTIN_H
#define BUILTIN_H
#include "model.h"
#include <string>
#include <gmpxx.h>
using std::string;
bool is_list(Cons *ptr);
/** @class InexactNumObj
* Inexact number implementation (using doubles)
*/
class InexactNumObj: public NumObj {
public:
InexactNumObj(NumLvl level);
};
/** @class CompNumObj
* Complex numbers
*/
class CompNumObj: public InexactNumObj {
public:
double real, imag;
/** Construct a complex number */
CompNumObj(double _real, double _imag);
/** Try to construct an CompNumObj object
* @return NULL if failed
*/
static CompNumObj *from_string(string repr);
/** Convert to a complex number from other numeric types */
CompNumObj *convert(NumObj* obj);
NumObj *add(NumObj *r);
NumObj *sub(NumObj *r);
NumObj *mul(NumObj *r);
NumObj *div(NumObj *r);
bool lt(NumObj *r);
bool gt(NumObj *r);
bool eq(NumObj *r);
string ext_repr();
};
/** @class RealNumObj
* Real numbers
*/
class RealNumObj: public InexactNumObj {
public:
double real;
/** Construct a real number */
RealNumObj(double _real);
/** Try to construct an RealNumObj object
* @return NULL if failed
*/
static RealNumObj *from_string(string repr);
/** Convert to a real number from other numeric types */
RealNumObj *convert(NumObj* obj);
NumObj *add(NumObj *r);
NumObj *sub(NumObj *r);
NumObj *mul(NumObj *r);
NumObj *div(NumObj *r);
bool lt(NumObj *r);
bool gt(NumObj *r);
bool eq(NumObj *r);
string ext_repr();
};
/** @class ExactNumObj
* Exact number implementation (using gmp)
*/
class ExactNumObj: public NumObj {
public:
ExactNumObj(NumLvl level);
};
/** @class RatNumObj
* Rational numbers
*/
class RatNumObj: public ExactNumObj {
public:
#ifndef GMP_SUPPORT
int a, b;
/** Construct a rational number */
RatNumObj(int _a, int _b);
#else
mpq_class val;
RatNumObj(mpq_class val);
#endif
/** Try to construct an RatNumObj object
* @return NULL if failed
*/
static RatNumObj *from_string(string repr);
/** Convert to a Rational number from other numeric types */
RatNumObj *convert(NumObj* obj);
NumObj *add(NumObj *r);
NumObj *sub(NumObj *r);
NumObj *mul(NumObj *r);
NumObj *div(NumObj *r);
bool lt(NumObj *r);
bool gt(NumObj *r);
bool eq(NumObj *r);
string ext_repr();
};
/** @class IntNumObj
* Integers
*/
class IntNumObj: public ExactNumObj {
public:
#ifndef GMP_SUPPORT
int val;
/** Construct a integer */
IntNumObj(int val);
#else
mpz_class val;
/** Construct a integer */
IntNumObj(mpz_class val);
#endif
/** Try to construct an IntNumObj object
* @return NULL if failed
*/
static IntNumObj *from_string(string repr);
/** Convert to a integer from other numeric types */
IntNumObj *convert(NumObj* obj);
NumObj *add(NumObj *r);
NumObj *sub(NumObj *r);
NumObj *mul(NumObj *r);
NumObj *div(NumObj *r);
bool lt(NumObj *r);
bool gt(NumObj *r);
bool eq(NumObj *r);
string ext_repr();
};
/** @class SpecialOptIf
* The implementation of `if` operator
*/
class SpecialOptIf: public SpecialOptObj {
private:
unsigned char state; /**< 0 for prepared, 1 for pre_called */
/**
* The evaluator will call this after the <condition> exp is evaluated.
* And this function tells the evaluator which of <consequence> and
* <alternative> should be evaluted. */
void pre_call(ArgList *args, Cons *pc,
Environment *envt);
/** The system will call this again after the desired result is
* evaluated, so just return it to let the evaluator know the it's the
* answer.
*/
EvalObj *post_call(ArgList *args, Cons *pc,
Environment *envt);
public:
SpecialOptIf();
void prepare(Cons *pc);
Cons *call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr);
string ext_repr();
};
/** @class SpecialOptLambda
* The implementation of `lambda` operator
*/
class SpecialOptLambda: public SpecialOptObj {
public:
SpecialOptLambda();
void prepare(Cons *pc);
Cons *call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr);
string ext_repr();
};
/** @class SpecialOptDefine
* The implementation of `define` operator
*/
class SpecialOptDefine: public SpecialOptObj {
public:
SpecialOptDefine();
void prepare(Cons *pc);
Cons *call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr);
string ext_repr();
};
/** @class SpecialOptSet
* The implementation of `set!` operator
*/
class SpecialOptSet: public SpecialOptObj {
public:
SpecialOptSet();
void prepare(Cons *pc);
Cons *call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr);
string ext_repr();
};
/** @class SpecialOptLambda
* The implementation of `lambda` operator
*/
class SpecialOptQuote: public SpecialOptObj {
public:
SpecialOptQuote();
void prepare(Cons *pc);
Cons *call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr);
string ext_repr();
};
/** @class SpecialOptEval
* The implementation of `eval` operator
*/
class SpecialOptEval: public SpecialOptObj {
private:
unsigned char state; /**< 0 for prepared, 1 for pre_called */
public:
SpecialOptEval();
void prepare(Cons *pc);
Cons *call(ArgList *args, Environment * &envt,
Continuation * &cont, FrameObj ** &top_ptr);
string ext_repr();
};
#define BUILTIN_PROC_DEF(func)\
EvalObj *(func)(ArgList *args, const string &name)
BUILTIN_PROC_DEF(num_add);
BUILTIN_PROC_DEF(num_sub);
BUILTIN_PROC_DEF(num_mul);
BUILTIN_PROC_DEF(num_div);
BUILTIN_PROC_DEF(num_lt);
BUILTIN_PROC_DEF(num_gt);
BUILTIN_PROC_DEF(num_eq);
BUILTIN_PROC_DEF(num_exact);
BUILTIN_PROC_DEF(num_inexact);
BUILTIN_PROC_DEF(bool_not);
BUILTIN_PROC_DEF(is_boolean);
BUILTIN_PROC_DEF(is_pair);
BUILTIN_PROC_DEF(make_pair);
BUILTIN_PROC_DEF(pair_car);
BUILTIN_PROC_DEF(pair_cdr);
BUILTIN_PROC_DEF(pair_set_car);
BUILTIN_PROC_DEF(pair_set_cdr);
BUILTIN_PROC_DEF(is_null);
BUILTIN_PROC_DEF(is_list);
BUILTIN_PROC_DEF(display);
BUILTIN_PROC_DEF(make_list);
#endif