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- /* arith.h Copyright (C) Codemist Ltd, 1990-1995 */
- /* Signature: 05ee46ce 07-Mar-2000 */
- #ifndef header_arith_h
- #define header_arith_h 1
- #define TWO_32 4294967296.0 /* 2^32 */
- #define TWO_31 2147483648.0 /* 2^31 */
- #define TWO_24 16777216.0 /* 2^24 */
- #define TWO_22 4194304.0 /* 2^22 */
- #define TWO_21 2097152.0 /* 2^21 */
- #define TWO_20 1048576.0 /* 2^20 */
- #define M2_31_1 -2147483649.0 /* -(2^31 + 1) */
- #define _pi 3.14159265358979323846
- #define _half_pi 1.57079632679489661923
- #define boole_clr 0
- #define boole_and 1
- #define boole_andc2 2
- #define boole_1 3
- #define boole_andc1 4
- #define boole_2 5
- #define boole_xor 6
- #define boole_ior 7
- #define boole_nor 8
- #define boole_eqv 9
- #define boole_c2 10
- #define boole_orc2 11
- #define boole_c1 12
- #define boole_orc1 13
- #define boole_nand 14
- #define boole_set 15
- /*
- * Bignums are represented as vectors of digits, where each digit
- * uses 31 bits, and all but the most significant digit are unsigned
- * (and thus do not use the 0x80000000L bit). The most significant
- * digit of a bignum is a signed 2-s complement value in 31 bits that
- * has been sign extended into the 0x80000000L bit, and thus its top
- * two bits (in the 32 bit word) will be either '00' or '11'.
- */
- #define top_bit_set(n) (((int32)(n)) < 0)
- #define top_bit(n) (((unsigned32)(n)) >> 31)
- #define set_top_bit(n) ((n) | (~0x7fffffff))
- #define clear_top_bit(n) ((n) & 0x7fffffff)
- #define signed_overflow(n) top_bit_set((n) ^ (((int32)(n))<<1))
- #ifdef MULDIV64
- /*
- * Here I do some arithmetic in-line. In the following macros I need to
- * take care that the names used for local variables do not clash with
- * those used in the body of the code. Hence the names r64 and c64, which
- * I must agree not to use elsewhere. Note also the "do {} while (0)" idiom
- * to avoid nasty problems with C syntax and the need for semicolons.
- */
- #define IMULTIPLY 1 /* External function not needed */
- #define Dmultiply(hi, lo, a, b, c) \
- do { unsigned64 r64 = (unsigned64)(a) * (unsigned64)(b) + \
- (unsigned32)(c); \
- (lo) = 0x7fffffffu & (unsigned32)r64; \
- (hi) = (unsigned32)(r64 >> 31); } while (0)
- #define IDIVIDE 1
- #define Ddivide(r, q, a, b, c) \
- do { unsigned64 r64 = (((unsigned64)(a)) << 31) | (unsigned64)(b); \
- unsigned64 c64 = (unsigned64)(unsigned32)(c); \
- q = (unsigned32)(r64 / c64); \
- r = (unsigned32)(r64 % c64); } while (0)
- #define Ddiv10_9(r, q, a, b) Ddivide(r, q, a, b, 1000000000u)
- #else
- #define Dmultiply(hi, lo, a, b, c) ((hi) = Imultiply(&(lo), (a), (b), (c)))
- #define Ddivide(r, q, a, b, c) ((r) = Idivide(&(q), (a), (b), (c)))
- #define Ddiv10_9(r, q, a, b) ((r) = Idiv10_9(&(q), (a), (b)))
- #endif
- #define fix_mask (-0x08000000)
- #define fixnum_minusp(a) ((int32)(a) < 0)
- #define bignum_minusp(a) ((int32)bignum_digits(a)[(bignum_length(a)>>2)-2]<0)
- extern Lisp_Object negateb(Lisp_Object);
- extern Lisp_Object copyb(Lisp_Object);
- extern Lisp_Object negate(Lisp_Object);
- extern Lisp_Object plus2(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object difference2(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object times2(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object quot2(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object CLquot2(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object quotbn(Lisp_Object a, int32 n);
- extern Lisp_Object quotbn1(Lisp_Object a, int32 n);
- extern Lisp_Object quotbb(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object Cremainder(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object rembi(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object rembb(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object shrink_bignum(Lisp_Object a, int32 lena);
- extern Lisp_Object modulus(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object rational(Lisp_Object a);
- extern Lisp_Object rationalize(Lisp_Object a);
- extern Lisp_Object lcm(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object lengthen_by_one_bit(Lisp_Object a, int32 msd);
- extern CSLbool numeq2(Lisp_Object a, Lisp_Object b);
- extern CSLbool zerop(Lisp_Object a);
- extern CSLbool onep(Lisp_Object a);
- extern CSLbool minusp(Lisp_Object a);
- extern CSLbool plusp(Lisp_Object a);
- extern CSLbool lesspbd(Lisp_Object a, double b);
- extern CSLbool lessprd(Lisp_Object a, double b);
- extern CSLbool lesspdb(double a, Lisp_Object b);
- extern CSLbool lesspdr(double a, Lisp_Object b);
- extern Lisp_Object make_one_word_bignum(int32 n);
- extern Lisp_Object make_two_word_bignum(int32 a, unsigned32 b);
- extern Lisp_Object make_n_word_bignum(int32 a1, unsigned32 a2,
- unsigned32 a3, int32 n);
- extern Lisp_Object make_sfloat(double d);
- extern double float_of_integer(Lisp_Object a);
- extern Lisp_Object add1(Lisp_Object p);
- extern Lisp_Object sub1(Lisp_Object p);
- extern Lisp_Object integerp(Lisp_Object p);
- extern double float_of_number(Lisp_Object a);
- extern Lisp_Object make_boxfloat(double a, int32 type);
- extern Lisp_Object make_complex(Lisp_Object r, Lisp_Object i);
- extern Lisp_Object make_ratio(Lisp_Object p, Lisp_Object q);
- extern Lisp_Object ash(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object lognot(Lisp_Object a);
- extern Lisp_Object logior2(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object logxor2(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object logand2(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object logeqv2(Lisp_Object a, Lisp_Object b);
- extern Lisp_Object rationalf(double d);
- extern int _reduced_exp(double, double *);
- extern CSLbool lesspbi(Lisp_Object a, Lisp_Object b);
- extern CSLbool lesspib(Lisp_Object a, Lisp_Object b);
- #ifdef COMMON
- typedef struct Complex
- {
- double real;
- double imag;
- } Complex;
- extern Complex MS_CDECL Cln(Complex a);
- extern Complex MS_CDECL Ccos(Complex a);
- extern Complex MS_CDECL Cexp(Complex a);
- extern Complex MS_CDECL Cpow(Complex a, Complex b);
- extern double MS_CDECL Cabs(Complex a);
- #endif
- #endif /* header_arith_h */
- /* end of arith.h */
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