-/* Copyright (C) 1995,1996,1997,1998,1999,2000 Free Software Foundation, Inc.
+/* Copyright (C) 1995,1996,1997,1998,1999,2000,2001 Free Software Foundation, Inc.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
\f
-#include <stdio.h>
#include <math.h>
#include "libguile/_scm.h"
#include "libguile/feature.h"
#include "libguile/validate.h"
#include "libguile/numbers.h"
+#include "libguile/deprecation.h"
\f
-static SCM scm_divbigbig (SCM_BIGDIG *x, scm_sizet nx, SCM_BIGDIG *y, scm_sizet ny, int sgn, int modes);
+static SCM scm_divbigbig (SCM_BIGDIG *x, size_t nx, SCM_BIGDIG *y, size_t ny, int sgn, int modes);
static SCM scm_divbigint (SCM x, long z, int sgn, int mode);
#define SCM_SWAP(x,y) do { SCM __t = x; x = y; y = __t; } while (0)
-#if (SCM_DEBUG_DEPRECATED == 1) /* not defined in header yet? */
-
-/* SCM_FLOBUFLEN is the maximum number of characters neccessary for the
+/* FLOBUFLEN is the maximum number of characters neccessary for the
* printed or scm_string representation of an inexact number.
*/
-#define SCM_FLOBUFLEN (10+2*(sizeof(double)/sizeof(char)*SCM_CHAR_BIT*3+9)/10)
-
-#endif /* SCM_DEBUG_DEPRECATED == 1 */
+#define FLOBUFLEN (10+2*(sizeof(double)/sizeof(char)*SCM_CHAR_BIT*3+9)/10)
/* IS_INF tests its floating point number for infiniteness
\f
+static SCM abs_most_negative_fixnum;
+
+\f
+
SCM_DEFINE (scm_exact_p, "exact?", 1, 0, 0,
(SCM x),
- "Return #t if X is an exact number, #f otherwise.")
+ "Return @code{#t} if @var{x} is an exact number, @code{#f}\n"
+ "otherwise.")
#define FUNC_NAME s_scm_exact_p
{
if (SCM_INUMP (x)) {
SCM_DEFINE (scm_odd_p, "odd?", 1, 0, 0,
(SCM n),
- "Return #t if N is an odd number, #f otherwise.")
+ "Return @code{#t} if @var{n} is an odd number, @code{#f}\n"
+ "otherwise.")
#define FUNC_NAME s_scm_odd_p
{
if (SCM_INUMP (n)) {
SCM_DEFINE (scm_even_p, "even?", 1, 0, 0,
(SCM n),
- "Return #t if N is an even number, #f otherwise.")
+ "Return @code{#t} if @var{n} is an even number, @code{#f}\n"
+ "otherwise.")
#define FUNC_NAME s_scm_even_p
{
if (SCM_INUMP (n)) {
SCM_GPROC (s_abs, "abs", 1, 0, 0, scm_abs, g_abs);
-
+/* "Return the absolute value of @var{x}."
+ */
SCM
scm_abs (SCM x)
{
return SCM_MAKINUM (-xx);
} else {
#ifdef SCM_BIGDIG
- return scm_long2big (-xx);
+ return scm_i_long2big (-xx);
#else
scm_num_overflow (s_abs);
#endif
if (!SCM_BIGSIGN (x)) {
return x;
} else {
- return scm_copybig (x, 0);
+ return scm_i_copybig (x, 0);
}
} else if (SCM_REALP (x)) {
return scm_make_real (fabs (SCM_REAL_VALUE (x)));
SCM_GPROC (s_quotient, "quotient", 2, 0, 0, scm_quotient, g_quotient);
-
+/* "Return the quotient of the numbers @var{x} and @var{y}."
+ */
SCM
scm_quotient (SCM x, SCM y)
{
return SCM_MAKINUM (z);
} else {
#ifdef SCM_BIGDIG
- return scm_long2big (z);
+ return scm_i_long2big (z);
#else
scm_num_overflow (s_quotient);
#endif
}
}
} else if (SCM_BIGP (y)) {
- return SCM_INUM0;
+ if (SCM_INUM (x) == SCM_MOST_NEGATIVE_FIXNUM
+ && scm_bigcomp (abs_most_negative_fixnum, y) == 0)
+ {
+ /* Special case: x == fixnum-min && y == abs (fixnum-min) */
+ return SCM_MAKINUM (-1);
+ }
+ else
+ return SCM_MAKINUM (0);
} else {
SCM_WTA_DISPATCH_2 (g_quotient, x, y, SCM_ARG2, s_quotient);
}
long z = yy < 0 ? -yy : yy;
if (z < SCM_BIGRAD) {
- SCM sw = scm_copybig (x, SCM_BIGSIGN (x) ? (yy > 0) : (yy < 0));
+ SCM sw = scm_i_copybig (x, SCM_BIGSIGN (x) ? (yy > 0) : (yy < 0));
scm_divbigdig (SCM_BDIGITS (sw), SCM_NUMDIGS (sw), (SCM_BIGDIG) z);
- return scm_normbig (sw);
+ return scm_i_normbig (sw);
} else {
#ifndef SCM_DIGSTOOBIG
long w = scm_pseudolong (z);
SCM_GPROC (s_remainder, "remainder", 2, 0, 0, scm_remainder, g_remainder);
-
+/* "Return the remainder of the numbers @var{x} and @var{y}.\n"
+ * "@lisp\n"
+ * "(remainder 13 4) @result{} 1\n"
+ * "(remainder -13 4) @result{} -1\n"
+ * "@end lisp"
+ */
SCM
scm_remainder (SCM x, SCM y)
{
return SCM_MAKINUM (z);
}
} else if (SCM_BIGP (y)) {
- return x;
+ if (SCM_INUM (x) == SCM_MOST_NEGATIVE_FIXNUM
+ && scm_bigcomp (abs_most_negative_fixnum, y) == 0)
+ {
+ /* Special case: x == fixnum-min && y == abs (fixnum-min) */
+ return SCM_MAKINUM (0);
+ }
+ else
+ return x;
} else {
SCM_WTA_DISPATCH_2 (g_remainder, x, y, SCM_ARG2, s_remainder);
}
SCM_GPROC (s_modulo, "modulo", 2, 0, 0, scm_modulo, g_modulo);
-
+/* "Return the modulo of the numbers @var{x} and @var{y}.\n"
+ * "@lisp\n"
+ * "(modulo 13 4) @result{} 1\n"
+ * "(modulo -13 4) @result{} 3\n"
+ * "@end lisp"
+ */
SCM
scm_modulo (SCM x, SCM y)
{
SCM_GPROC1 (s_gcd, "gcd", scm_tc7_asubr, scm_gcd, g_gcd);
-
+/* "Return the greatest common divisor of all arguments.\n"
+ * "If called without arguments, 0 is returned."
+ */
SCM
scm_gcd (SCM x, SCM y)
{
return SCM_MAKINUM (result);
} else {
#ifdef SCM_BIGDIG
- return scm_long2big (result);
+ return scm_i_long2big (result);
#else
scm_num_overflow (s_gcd);
#endif
} else if (SCM_BIGP (x)) {
big_gcd:
if (SCM_BIGSIGN (x))
- x = scm_copybig (x, 0);
+ x = scm_i_copybig (x, 0);
newy:
if (SCM_INUMP (y)) {
if (SCM_EQ_P (y, SCM_INUM0)) {
}
} else if (SCM_BIGP (y)) {
if (SCM_BIGSIGN (y))
- y = scm_copybig (y, 0);
+ y = scm_i_copybig (y, 0);
switch (scm_bigcomp (x, y))
{
case -1: /* x > y */
SCM_GPROC1 (s_lcm, "lcm", scm_tc7_asubr, scm_lcm, g_lcm);
-
+/* "Return the least common multiple of the arguments.\n"
+ * "If called without arguments, 1 is returned."
+ */
SCM
scm_lcm (SCM n1, SCM n2)
{
#ifdef SCM_BIGDIG
SCM scm_copy_big_dec(SCM b, int sign);
-SCM scm_copy_smaller(SCM_BIGDIG *x, scm_sizet nx, int zsgn);
-SCM scm_big_ior(SCM_BIGDIG *x, scm_sizet nx, int xsgn, SCM bigy);
-SCM scm_big_xor(SCM_BIGDIG *x, scm_sizet nx, int xsgn, SCM bigy);
-SCM scm_big_and(SCM_BIGDIG *x, scm_sizet nx, int xsgn, SCM bigy, int zsgn);
-SCM scm_big_test(SCM_BIGDIG *x, scm_sizet nx, int xsgn, SCM bigy);
+SCM scm_copy_smaller(SCM_BIGDIG *x, size_t nx, int zsgn);
+SCM scm_big_ior(SCM_BIGDIG *x, size_t nx, int xsgn, SCM bigy);
+SCM scm_big_xor(SCM_BIGDIG *x, size_t nx, int xsgn, SCM bigy);
+SCM scm_big_and(SCM_BIGDIG *x, size_t nx, int xsgn, SCM bigy, int zsgn);
+SCM scm_big_test(SCM_BIGDIG *x, size_t nx, int xsgn, SCM bigy);
SCM scm_copy_big_dec(SCM b, int sign)
{
long num = -1;
- scm_sizet nx = SCM_NUMDIGS(b);
- scm_sizet i = 0;
- SCM ans = scm_mkbig(nx, sign);
+ size_t nx = SCM_NUMDIGS(b);
+ size_t i = 0;
+ SCM ans = scm_i_mkbig(nx, sign);
SCM_BIGDIG *src = SCM_BDIGITS(b), *dst = SCM_BDIGITS(ans);
if SCM_BIGSIGN(b) do {
num += src[i];
return ans;
}
-SCM scm_copy_smaller(SCM_BIGDIG *x, scm_sizet nx, int zsgn)
+SCM scm_copy_smaller(SCM_BIGDIG *x, size_t nx, int zsgn)
{
long num = -1;
- scm_sizet i = 0;
- SCM z = scm_mkbig(nx, zsgn);
+ size_t i = 0;
+ SCM z = scm_i_mkbig(nx, zsgn);
SCM_BIGDIG *zds = SCM_BDIGITS(z);
if (zsgn) do {
num += x[i];
return z;
}
-SCM scm_big_ior(SCM_BIGDIG *x, scm_sizet nx, int xsgn, SCM bigy)
+SCM scm_big_ior(SCM_BIGDIG *x, size_t nx, int xsgn, SCM bigy)
/* Assumes nx <= SCM_NUMDIGS(bigy) */
/* Assumes xsgn equals either 0 or SCM_BIGSIGNFLAG */
{
long num = -1;
- scm_sizet i = 0, ny = SCM_NUMDIGS(bigy);
+ size_t i = 0, ny = SCM_NUMDIGS(bigy);
SCM z = scm_copy_big_dec (bigy, xsgn & SCM_BIGSIGN (bigy));
SCM_BIGDIG *zds = SCM_BDIGITS(z);
if (xsgn) {
num = SCM_BIGDN(num);
if (!num) return z;
}
- scm_adjbig(z, 1 + ny); /* OOPS, overflowed into next digit. */
+ scm_i_adjbig(z, 1 + ny); /* OOPS, overflowed into next digit. */
SCM_BDIGITS(z)[ny] = 1;
return z;
}
return z;
}
-SCM scm_big_xor(SCM_BIGDIG *x, scm_sizet nx, int xsgn, SCM bigy)
+SCM scm_big_xor(SCM_BIGDIG *x, size_t nx, int xsgn, SCM bigy)
/* Assumes nx <= SCM_NUMDIGS(bigy) */
/* Assumes xsgn equals either 0 or SCM_BIGSIGNFLAG */
{
long num = -1;
- scm_sizet i = 0, ny = SCM_NUMDIGS(bigy);
+ size_t i = 0, ny = SCM_NUMDIGS(bigy);
SCM z = scm_copy_big_dec(bigy, xsgn ^ SCM_BIGSIGN(bigy));
SCM_BIGDIG *zds = SCM_BDIGITS(z);
if (xsgn) do {
num += zds[i];
zds[i++] = SCM_BIGLO(num);
num = SCM_BIGDN(num);
- if (!num) return scm_normbig(z);
+ if (!num) return scm_i_normbig(z);
}
}
- return scm_normbig(z);
+ return scm_i_normbig(z);
}
-SCM scm_big_and(SCM_BIGDIG *x, scm_sizet nx, int xsgn, SCM bigy, int zsgn)
+SCM scm_big_and(SCM_BIGDIG *x, size_t nx, int xsgn, SCM bigy, int zsgn)
/* Assumes nx <= SCM_NUMDIGS(bigy) */
/* Assumes xsgn equals either 0 or SCM_BIGSIGNFLAG */
/* return sign equals either 0 or SCM_BIGSIGNFLAG */
{
long num = -1;
- scm_sizet i = 0;
+ size_t i = 0;
SCM z;
SCM_BIGDIG *zds;
if (xsgn==zsgn) {
num += zds[i];
zds[i++] = SCM_BIGLO(num);
num = SCM_BIGDN(num);
- if (!num) return scm_normbig(z);
+ if (!num) return scm_i_normbig(z);
}
}
- else if (xsgn) do {
- num += x[i];
- if (num < 0) {zds[i] &= num + SCM_BIGRAD; num = -1;}
- else {zds[i] &= ~SCM_BIGLO(num); num = 0;}
- } while (++i < nx);
- else do zds[i] = zds[i] & x[i]; while (++i < nx);
- return scm_normbig(z);
+ else if (xsgn) {
+ unsigned long int carry = 1;
+ do {
+ unsigned long int mask = (SCM_BIGDIG) ~x[i] + carry;
+ zds[i] = zds[i] & (SCM_BIGDIG) mask;
+ carry = (mask >= SCM_BIGRAD) ? 1 : 0;
+ } while (++i < nx);
+ } else do zds[i] = zds[i] & x[i]; while (++i < nx);
+ return scm_i_normbig(z);
}
-SCM scm_big_test(SCM_BIGDIG *x, scm_sizet nx, int xsgn, SCM bigy)
+SCM scm_big_test(SCM_BIGDIG *x, size_t nx, int xsgn, SCM bigy)
/* Assumes nx <= SCM_NUMDIGS(bigy) */
/* Assumes xsgn equals either 0 or SCM_BIGSIGNFLAG */
{
SCM_BIGDIG *y;
- scm_sizet i = 0;
+ size_t i = 0;
long num = -1;
if (SCM_BIGSIGN(bigy) & xsgn) return SCM_BOOL_T;
if (SCM_NUMDIGS(bigy) != nx && xsgn) return SCM_BOOL_T;
SCM_DEFINE1 (scm_logand, "logand", scm_tc7_asubr,
(SCM n1, SCM n2),
- "Returns the integer which is the bit-wise AND of the two integer\n"
- "arguments.\n\n"
- "Example:\n"
- "@lisp\n"
- "(number->string (logand #b1100 #b1010) 2)\n"
- " @result{} \"1000\"\n"
- "@end lisp")
+ "Return the integer which is the bit-wise AND of the two integer\n"
+ "arguments.\n"
+ "\n"
+ "@lisp\n"
+ "(number->string (logand #b1100 #b1010) 2)\n"
+ " @result{} \"1000\"\n"
+ "@end lisp")
#define FUNC_NAME s_scm_logand
{
long int nn1;
SCM_DEFINE1 (scm_logior, "logior", scm_tc7_asubr,
(SCM n1, SCM n2),
- "Returns the integer which is the bit-wise OR of the two integer\n"
- "arguments.\n\n"
- "Example:\n"
- "@lisp\n"
- "(number->string (logior #b1100 #b1010) 2)\n"
- " @result{} \"1110\"\n"
- "@end lisp")
+ "Return the integer which is the bit-wise OR of the two integer\n"
+ "arguments.\n"
+ "\n"
+ "@lisp\n"
+ "(number->string (logior #b1100 #b1010) 2)\n"
+ " @result{} \"1110\"\n"
+ "@end lisp")
#define FUNC_NAME s_scm_logior
{
long int nn1;
(nn1 < 0) ? SCM_BIGSIGNFLAG : 0, n2, SCM_BIGSIGNFLAG);
}
# else
- BIGDIG zdigs [DIGSPERLONG];
+ SCM_BIGDIG zdigs [SCM_DIGSPERLONG];
scm_longdigs (nn1, zdigs);
if ((!(nn1 < 0)) && !SCM_BIGSIGN (n2)) {
return scm_big_ior (zdigs, SCM_DIGSPERLONG,
SCM_DEFINE1 (scm_logxor, "logxor", scm_tc7_asubr,
(SCM n1, SCM n2),
- "Returns the integer which is the bit-wise XOR of the two integer\n"
- "arguments.\n\n"
- "Example:\n"
- "@lisp\n"
- "(number->string (logxor #b1100 #b1010) 2)\n"
- " @result{} \"110\"\n"
- "@end lisp")
+ "Return the integer which is the bit-wise XOR of the two integer\n"
+ "arguments.\n"
+ "\n"
+ "@lisp\n"
+ "(number->string (logxor #b1100 #b1010) 2)\n"
+ " @result{} \"110\"\n"
+ "@end lisp")
#define FUNC_NAME s_scm_logxor
{
long int nn1;
SCM_DEFINE (scm_logtest, "logtest", 2, 0, 0,
- (SCM n1, SCM n2),
- "@example\n"
+ (SCM j, SCM k),
+ "@lisp\n"
"(logtest j k) @equiv{} (not (zero? (logand j k)))\n\n"
"(logtest #b0100 #b1011) @result{} #f\n"
"(logtest #b0100 #b0111) @result{} #t\n"
- "@end example")
+ "@end lisp")
#define FUNC_NAME s_scm_logtest
{
- long int nn1;
+ long int nj;
- if (SCM_INUMP (n1)) {
- nn1 = SCM_INUM (n1);
- if (SCM_INUMP (n2)) {
- long nn2 = SCM_INUM (n2);
- return SCM_BOOL (nn1 & nn2);
- } else if (SCM_BIGP (n2)) {
+ if (SCM_INUMP (j)) {
+ nj = SCM_INUM (j);
+ if (SCM_INUMP (k)) {
+ long nk = SCM_INUM (k);
+ return SCM_BOOL (nj & nk);
+ } else if (SCM_BIGP (k)) {
intbig:
{
# ifndef SCM_DIGSTOOBIG
- long z = scm_pseudolong (nn1);
+ long z = scm_pseudolong (nj);
return scm_big_test ((SCM_BIGDIG *)&z, SCM_DIGSPERLONG,
- (nn1 < 0) ? SCM_BIGSIGNFLAG : 0, n2);
+ (nj < 0) ? SCM_BIGSIGNFLAG : 0, k);
# else
SCM_BIGDIG zdigs [SCM_DIGSPERLONG];
- scm_longdigs (nn1, zdigs);
+ scm_longdigs (nj, zdigs);
return scm_big_test (zdigs, SCM_DIGSPERLONG,
- (nn1 < 0) ? SCM_BIGSIGNFLAG : 0, n2);
+ (nj < 0) ? SCM_BIGSIGNFLAG : 0, k);
# endif
}
} else {
- SCM_WRONG_TYPE_ARG (SCM_ARG2, n2);
+ SCM_WRONG_TYPE_ARG (SCM_ARG2, k);
}
- } else if (SCM_BIGP (n1)) {
- if (SCM_INUMP (n2)) {
- SCM_SWAP (n1, n2);
- nn1 = SCM_INUM (n1);
+ } else if (SCM_BIGP (j)) {
+ if (SCM_INUMP (k)) {
+ SCM_SWAP (j, k);
+ nj = SCM_INUM (j);
goto intbig;
- } else if (SCM_BIGP (n2)) {
- if (SCM_NUMDIGS (n1) > SCM_NUMDIGS (n2)) {
- SCM_SWAP (n1, n2);
+ } else if (SCM_BIGP (k)) {
+ if (SCM_NUMDIGS (j) > SCM_NUMDIGS (k)) {
+ SCM_SWAP (j, k);
}
- return scm_big_test (SCM_BDIGITS (n1), SCM_NUMDIGS (n1),
- SCM_BIGSIGN (n1), n2);
+ return scm_big_test (SCM_BDIGITS (j), SCM_NUMDIGS (j),
+ SCM_BIGSIGN (j), k);
} else {
- SCM_WRONG_TYPE_ARG (SCM_ARG2, n2);
+ SCM_WRONG_TYPE_ARG (SCM_ARG2, k);
}
} else {
- SCM_WRONG_TYPE_ARG (SCM_ARG1, n1);
+ SCM_WRONG_TYPE_ARG (SCM_ARG1, j);
}
}
#undef FUNC_NAME
SCM_DEFINE (scm_logbit_p, "logbit?", 2, 0, 0,
(SCM index, SCM j),
- "@example\n"
+ "@lisp\n"
"(logbit? index j) @equiv{} (logtest (integer-expt 2 index) j)\n\n"
"(logbit? 0 #b1101) @result{} #t\n"
"(logbit? 1 #b1101) @result{} #f\n"
"(logbit? 2 #b1101) @result{} #t\n"
"(logbit? 3 #b1101) @result{} #t\n"
"(logbit? 4 #b1101) @result{} #f\n"
- "@end example")
+ "@end lisp")
#define FUNC_NAME s_scm_logbit_p
{
unsigned long int iindex;
return SCM_BOOL_F;
} else if (SCM_BIGSIGN (j)) {
long num = -1;
- scm_sizet i = 0;
+ size_t i = 0;
SCM_BIGDIG * x = SCM_BDIGITS (j);
- scm_sizet nx = iindex / SCM_BITSPERDIG;
+ size_t nx = iindex / SCM_BITSPERDIG;
while (1) {
num += x[i];
if (nx == i++) {
SCM_DEFINE (scm_lognot, "lognot", 1, 0, 0,
(SCM n),
- "Returns the integer which is the 2s-complement of the integer argument.\n\n"
- "Example:\n"
+ "Return the integer which is the 2s-complement of the integer\n"
+ "argument.\n"
+ "\n"
"@lisp\n"
"(number->string (lognot #b10000000) 2)\n"
" @result{} \"-10000001\"\n"
"(number->string (lognot #b0) 2)\n"
" @result{} \"-1\"\n"
- "@end lisp\n"
- "")
+ "@end lisp")
#define FUNC_NAME s_scm_lognot
{
return scm_difference (SCM_MAKINUM (-1L), n);
SCM_DEFINE (scm_integer_expt, "integer-expt", 2, 0, 0,
(SCM n, SCM k),
- "Returns @var{n} raised to the non-negative integer exponent @var{k}.\n\n"
- "Example:\n"
+ "Return @var{n} raised to the non-negative integer exponent\n"
+ "@var{k}.\n"
+ "\n"
"@lisp\n"
"(integer-expt 2 5)\n"
" @result{} 32\n"
SCM_DEFINE (scm_ash, "ash", 2, 0, 0,
(SCM n, SCM cnt),
- "The function ash performs an arithmetic shift left by CNT bits\n"
- "(or shift right, if CNT is negative). 'Arithmetic' means, that\n"
- "the function does not guarantee to keep the bit structure of N,\n"
- "but rather guarantees that the result will always be rounded\n"
- "towards minus infinity. Therefore, the results of ash and a\n"
- "corresponding bitwise shift will differ if N is negative.\n\n"
+ "The function ash performs an arithmetic shift left by @var{cnt}\n"
+ "bits (or shift right, if @var{cnt} is negative). 'Arithmetic'\n"
+ "means, that the function does not guarantee to keep the bit\n"
+ "structure of @var{n}, but rather guarantees that the result\n"
+ "will always be rounded towards minus infinity. Therefore, the\n"
+ "results of ash and a corresponding bitwise shift will differ if\n"
+ "@var{n} is negative.\n"
+ "\n"
"Formally, the function returns an integer equivalent to\n"
- "@code{(inexact->exact (floor (* N (expt 2 CNT))))}.@refill\n\n"
- "Example:\n"
+ "@code{(inexact->exact (floor (* @var{n} (expt 2 @var{cnt}))))}.\n"
+ "\n"
"@lisp\n"
- "(number->string (ash #b1 3) 2)\n"
- " @result{} \"1000\"\n"
- "(number->string (ash #b1010 -1) 2)\n"
- " @result{} \"101\"\n"
+ "(number->string (ash #b1 3) 2) @result{} \"1000\"\n"
+ "(number->string (ash #b1010 -1) 2) @result{} \"101\"\n"
"@end lisp")
#define FUNC_NAME s_scm_ash
{
SCM_DEFINE (scm_bit_extract, "bit-extract", 3, 0, 0,
(SCM n, SCM start, SCM end),
- "Returns the integer composed of the @var{start} (inclusive) through\n"
- "@var{end} (exclusive) bits of @var{n}. The @var{start}th bit becomes\n"
- "the 0-th bit in the result.@refill\n\n"
- "Example:\n"
+ "Return the integer composed of the @var{start} (inclusive)\n"
+ "through @var{end} (exclusive) bits of @var{n}. The\n"
+ "@var{start}th bit becomes the 0-th bit in the result.\n"
+ "\n"
"@lisp\n"
"(number->string (bit-extract #b1101101010 0 4) 2)\n"
" @result{} \"1010\"\n"
"@end lisp")
#define FUNC_NAME s_scm_bit_extract
{
- int istart, iend;
+ unsigned long int istart, iend;
SCM_VALIDATE_INUM_MIN_COPY (2,start,0,istart);
SCM_VALIDATE_INUM_MIN_COPY (3, end, 0, iend);
SCM_ASSERT_RANGE (3, end, (iend >= istart));
if (SCM_INUMP (n)) {
- return SCM_MAKINUM ((SCM_INUM (n) >> istart) & ((1L << (iend - istart)) - 1));
+ long int in = SCM_INUM (n);
+ unsigned long int bits = iend - istart;
+
+ if (in < 0 && bits >= SCM_I_FIXNUM_BIT)
+ {
+ /* Since we emulate two's complement encoded numbers, this special
+ * case requires us to produce a result that has more bits than can be
+ * stored in a fixnum. Thus, we fall back to the more general
+ * algorithm that is used for bignums.
+ */
+ goto generalcase;
+ }
+
+ if (istart < SCM_I_FIXNUM_BIT)
+ {
+ in = in >> istart;
+ if (bits < SCM_I_FIXNUM_BIT)
+ return SCM_MAKINUM (in & ((1L << bits) - 1));
+ else /* we know: in >= 0 */
+ return SCM_MAKINUM (in);
+ }
+ else if (in < 0)
+ {
+ return SCM_MAKINUM (-1L & ((1L << bits) - 1));
+ }
+ else
+ {
+ return SCM_MAKINUM (0);
+ }
} else if (SCM_BIGP (n)) {
- SCM num1 = SCM_MAKINUM (1L);
- SCM num2 = SCM_MAKINUM (2L);
- SCM bits = SCM_MAKINUM (iend - istart);
- SCM mask = scm_difference (scm_integer_expt (num2, bits), num1);
- return scm_logand (mask, scm_ash (n, SCM_MAKINUM (-istart)));
+ generalcase:
+ {
+ SCM num1 = SCM_MAKINUM (1L);
+ SCM num2 = SCM_MAKINUM (2L);
+ SCM bits = SCM_MAKINUM (iend - istart);
+ SCM mask = scm_difference (scm_integer_expt (num2, bits), num1);
+ return scm_logand (mask, scm_ash (n, SCM_MAKINUM (-istart)));
+ }
} else {
SCM_WRONG_TYPE_ARG (SCM_ARG1, n);
}
SCM_DEFINE (scm_logcount, "logcount", 1, 0, 0,
(SCM n),
- "Returns the number of bits in integer @var{n}. If integer is positive,\n"
- "the 1-bits in its binary representation are counted. If negative, the\n"
- "0-bits in its two's-complement binary representation are counted. If 0,\n"
- "0 is returned.\n\n"
- "Example:\n"
+ "Return the number of bits in integer @var{n}. If integer is\n"
+ "positive, the 1-bits in its binary representation are counted.\n"
+ "If negative, the 0-bits in its two's-complement binary\n"
+ "representation are counted. If 0, 0 is returned.\n"
+ "\n"
"@lisp\n"
"(logcount #b10101010)\n"
" @result{} 4\n"
return scm_logcount (scm_difference (SCM_MAKINUM (-1L), n));
} else {
unsigned long int c = 0;
- scm_sizet i = SCM_NUMDIGS (n);
+ size_t i = SCM_NUMDIGS (n);
SCM_BIGDIG * ds = SCM_BDIGITS (n);
while (i--) {
SCM_BIGDIG d;
SCM_DEFINE (scm_integer_length, "integer-length", 1, 0, 0,
(SCM n),
- "Returns the number of bits neccessary to represent @var{n}.\n\n"
- "Example:\n"
+ "Return the number of bits neccessary to represent @var{n}.\n"
+ "\n"
"@lisp\n"
"(integer-length #b10101010)\n"
" @result{} 8\n"
static const char s_bignum[] = "bignum";
SCM
-scm_mkbig (scm_sizet nlen, int sign)
+scm_i_mkbig (size_t nlen, int sign)
{
SCM v;
/* Cast to long int to avoid signed/unsigned comparison warnings. */
return v;
}
-
SCM
-scm_big2inum (SCM b, scm_sizet l)
+scm_i_big2inum (SCM b, size_t l)
{
unsigned long num = 0;
SCM_BIGDIG *tmp = SCM_BDIGITS (b);
return b;
}
-
-static const char s_adjbig[] = "scm_adjbig";
+static const char s_adjbig[] = "scm_i_adjbig";
SCM
-scm_adjbig (SCM b, scm_sizet nlen)
+scm_i_adjbig (SCM b, size_t nlen)
{
- scm_sizet nsiz = nlen;
+ size_t nsiz = nlen;
if (((nsiz << SCM_BIGSIZEFIELD) >> SCM_BIGSIZEFIELD) != nlen)
scm_memory_error (s_adjbig);
return b;
}
-
-
SCM
-scm_normbig (SCM b)
+scm_i_normbig (SCM b)
{
#ifndef _UNICOS
- scm_sizet nlen = SCM_NUMDIGS (b);
+ size_t nlen = SCM_NUMDIGS (b);
#else
int nlen = SCM_NUMDIGS (b); /* unsigned nlen breaks on Cray when nlen => 0 */
#endif
while (nlen-- && !zds[nlen]);
nlen++;
if (nlen * SCM_BITSPERDIG / SCM_CHAR_BIT <= sizeof (SCM))
- if (SCM_INUMP (b = scm_big2inum (b, (scm_sizet) nlen)))
+ if (SCM_INUMP (b = scm_i_big2inum (b, (size_t) nlen)))
return b;
if (SCM_NUMDIGS (b) == nlen)
return b;
- return scm_adjbig (b, (scm_sizet) nlen);
+ return scm_i_adjbig (b, (size_t) nlen);
}
-
-
SCM
-scm_copybig (SCM b, int sign)
+scm_i_copybig (SCM b, int sign)
{
- scm_sizet i = SCM_NUMDIGS (b);
- SCM ans = scm_mkbig (i, sign);
+ size_t i = SCM_NUMDIGS (b);
+ SCM ans = scm_i_mkbig (i, sign);
SCM_BIGDIG *src = SCM_BDIGITS (b), *dst = SCM_BDIGITS (ans);
while (i--)
dst[i] = src[i];
return ans;
}
-
-
-SCM
-scm_long2big (long n)
-{
- scm_sizet i = 0;
- SCM_BIGDIG *digits;
- SCM ans = scm_mkbig (SCM_DIGSPERLONG, n < 0);
- digits = SCM_BDIGITS (ans);
- if (n < 0)
- n = -n;
- while (i < SCM_DIGSPERLONG)
- {
- digits[i++] = SCM_BIGLO (n);
- n = SCM_BIGDN ((unsigned long) n);
- }
- return ans;
-}
-
-#ifdef HAVE_LONG_LONGS
-
-SCM
-scm_long_long2big (long_long n)
-{
- scm_sizet i;
- SCM_BIGDIG *digits;
- SCM ans;
- int n_digits;
-
- {
- long tn;
- tn = (long) n;
- if ((long long) tn == n)
- return scm_long2big (tn);
- }
-
- {
- long_long tn;
-
- for (tn = n, n_digits = 0;
- tn;
- ++n_digits, tn = SCM_BIGDN ((ulong_long) tn))
- ;
- }
-
- i = 0;
- ans = scm_mkbig (n_digits, n < 0);
- digits = SCM_BDIGITS (ans);
- if (n < 0)
- n = -n;
- while (i < n_digits)
- {
- digits[i++] = SCM_BIGLO (n);
- n = SCM_BIGDN ((ulong_long) n);
- }
- return ans;
-}
-#endif /* HAVE_LONG_LONGS */
-
-
-SCM
-scm_2ulong2big (unsigned long *np)
-{
- unsigned long n;
- scm_sizet i;
- SCM_BIGDIG *digits;
- SCM ans;
-
- ans = scm_mkbig (2 * SCM_DIGSPERLONG, 0);
- digits = SCM_BDIGITS (ans);
-
- n = np[0];
- for (i = 0; i < SCM_DIGSPERLONG; ++i)
- {
- digits[i] = SCM_BIGLO (n);
- n = SCM_BIGDN ((unsigned long) n);
- }
- n = np[1];
- for (i = 0; i < SCM_DIGSPERLONG; ++i)
- {
- digits[i + SCM_DIGSPERLONG] = SCM_BIGLO (n);
- n = SCM_BIGDN ((unsigned long) n);
- }
- return ans;
-}
-
-
-
-SCM
-scm_ulong2big (unsigned long n)
-{
- scm_sizet i = 0;
- SCM_BIGDIG *digits;
- SCM ans = scm_mkbig (SCM_DIGSPERLONG, 0);
- digits = SCM_BDIGITS (ans);
- while (i < SCM_DIGSPERLONG)
- {
- digits[i++] = SCM_BIGLO (n);
- n = SCM_BIGDN (n);
- }
- return ans;
-}
-
-
-
int
scm_bigcomp (SCM x, SCM y)
{
int xsign = SCM_BIGSIGN (x);
int ysign = SCM_BIGSIGN (y);
- scm_sizet xlen, ylen;
+ size_t xlen, ylen;
/* Look at the signs, first. */
if (ysign < xsign)
SCM_BIGDIG bd[SCM_DIGSPERLONG];
}
p;
- scm_sizet i = 0;
+ size_t i = 0;
if (x < 0)
x = -x;
while (i < SCM_DIGSPERLONG)
void
scm_longdigs (long x, SCM_BIGDIG digs[])
{
- scm_sizet i = 0;
+ size_t i = 0;
if (x < 0)
x = -x;
while (i < SCM_DIGSPERLONG)
SCM
-scm_addbig (SCM_BIGDIG *x, scm_sizet nx, int xsgn, SCM bigy, int sgny)
+scm_addbig (SCM_BIGDIG *x, size_t nx, int xsgn, SCM bigy, int sgny)
{
/* Assumes nx <= SCM_NUMDIGS(bigy) */
/* Assumes xsgn and sgny scm_equal either 0 or SCM_BIGSIGNFLAG */
long num = 0;
- scm_sizet i = 0, ny = SCM_NUMDIGS (bigy);
- SCM z = scm_copybig (bigy, SCM_BIGSIGN (bigy) ^ sgny);
+ size_t i = 0, ny = SCM_NUMDIGS (bigy);
+ SCM z = scm_i_copybig (bigy, SCM_BIGSIGN (bigy) ^ sgny);
SCM_BIGDIG *zds = SCM_BDIGITS (z);
if (xsgn ^ SCM_BIGSIGN (z))
{
}
if (num)
{
- z = scm_adjbig (z, ny + 1);
+ z = scm_i_adjbig (z, ny + 1);
SCM_BDIGITS (z)[ny] = num;
return z;
}
}
- return scm_normbig (z);
+ return scm_i_normbig (z);
}
SCM
-scm_mulbig (SCM_BIGDIG *x, scm_sizet nx, SCM_BIGDIG *y, scm_sizet ny, int sgn)
+scm_mulbig (SCM_BIGDIG *x, size_t nx, SCM_BIGDIG *y, size_t ny, int sgn)
{
- scm_sizet i = 0, j = nx + ny;
+ size_t i = 0, j = nx + ny;
unsigned long n = 0;
- SCM z = scm_mkbig (j, sgn);
+ SCM z = scm_i_mkbig (j, sgn);
SCM_BIGDIG *zds = SCM_BDIGITS (z);
while (j--)
zds[j] = 0;
}
}
while (++i < nx);
- return scm_normbig (z);
+ return scm_i_normbig (z);
}
unsigned int
-scm_divbigdig (SCM_BIGDIG * ds, scm_sizet h, SCM_BIGDIG div)
+scm_divbigdig (SCM_BIGDIG * ds, size_t h, SCM_BIGDIG div)
{
register unsigned long t2 = 0;
while (h--)
{
register unsigned long t2 = 0;
register SCM_BIGDIG *ds = SCM_BDIGITS (x);
- scm_sizet nd = SCM_NUMDIGS (x);
+ size_t nd = SCM_NUMDIGS (x);
while (nd--)
t2 = (SCM_BIGUP (t2) + ds[nd]) % z;
if (mode && t2)
static SCM
-scm_divbigbig (SCM_BIGDIG *x, scm_sizet nx, SCM_BIGDIG *y, scm_sizet ny, int sgn, int modes)
+scm_divbigbig (SCM_BIGDIG *x, size_t nx, SCM_BIGDIG *y, size_t ny, int sgn, int modes)
{
/* modes description
0 remainder
1 scm_modulo
2 quotient
3 quotient but returns SCM_UNDEFINED if division is not exact. */
- scm_sizet i = 0, j = 0;
+ size_t i = 0, j = 0;
long num = 0;
unsigned long t2 = 0;
SCM z, newy;
switch (modes)
{
case 0: /* remainder -- just return x */
- z = scm_mkbig (nx, sgn);
+ z = scm_i_mkbig (nx, sgn);
zds = SCM_BDIGITS (z);
do
{
while (++i < nx);
return z;
case 1: /* scm_modulo -- return y-x */
- z = scm_mkbig (ny, sgn);
+ z = scm_i_mkbig (ny, sgn);
zds = SCM_BDIGITS (z);
do
{
return SCM_UNDEFINED; /* the division is not exact */
}
- z = scm_mkbig (nx == ny ? nx + 2 : nx + 1, sgn);
+ z = scm_i_mkbig (nx == ny ? nx + 2 : nx + 1, sgn);
zds = SCM_BDIGITS (z);
if (nx == ny)
zds[nx + 1] = 0;
if (y[ny - 1] < (SCM_BIGRAD >> 1))
{ /* normalize operands */
d = SCM_BIGRAD / (y[ny - 1] + 1);
- newy = scm_mkbig (ny, 0);
+ newy = scm_i_mkbig (ny, 0);
yds = SCM_BDIGITS (newy);
while (j < ny)
{
doadj:
for (j = ny; j && !zds[j - 1]; --j);
if (j * SCM_BITSPERDIG <= sizeof (SCM) * SCM_CHAR_BIT)
- if (SCM_INUMP (z = scm_big2inum (z, j)))
+ if (SCM_INUMP (z = scm_i_big2inum (z, j)))
return z;
- return scm_adjbig (z, j);
+ return scm_i_adjbig (z, j);
}
#endif
\f
-static scm_sizet
+static size_t
idbl2str (double f, char *a)
{
int efmt, dpt, d, i, wp = scm_dblprec;
- scm_sizet ch = 0;
+ size_t ch = 0;
int exp = 0;
if (f == 0.0)
}
-static scm_sizet
+static size_t
iflo2str (SCM flt, char *str)
{
- scm_sizet i;
+ size_t i;
if (SCM_SLOPPY_REALP (flt))
i = idbl2str (SCM_REAL_VALUE (flt), str);
else
characters in the result.
rad is output base
p is destination: worst case (base 2) is SCM_INTBUFLEN */
-scm_sizet
+size_t
scm_iint2str (long num, int rad, char *p)
{
- scm_sizet j = 1;
- scm_sizet i;
+ size_t j = 1;
+ size_t i;
unsigned long n = (num < 0) ? -num : num;
for (n /= rad; n > 0; n /= rad)
static SCM
big2str (SCM b, unsigned int radix)
{
- SCM t = scm_copybig (b, 0); /* sign of temp doesn't matter */
+ SCM t = scm_i_copybig (b, 0); /* sign of temp doesn't matter */
register SCM_BIGDIG *ds = SCM_BDIGITS (t);
- scm_sizet i = SCM_NUMDIGS (t);
- scm_sizet j = radix == 16 ? (SCM_BITSPERDIG * i) / 4 + 2
+ size_t i = SCM_NUMDIGS (t);
+ size_t j = radix == 16 ? (SCM_BITSPERDIG * i) / 4 + 2
: radix >= 10 ? (SCM_BITSPERDIG * i * 241L) / 800 + 2
: (SCM_BITSPERDIG * i) + 2;
- scm_sizet k = 0;
- scm_sizet radct = 0;
+ size_t k = 0;
+ size_t radct = 0;
SCM_BIGDIG radpow = 1, radmod = 0;
- SCM ss = scm_makstr ((long) j, 0);
+ SCM ss = scm_allocate_string (j);
char *s = SCM_STRING_CHARS (ss), c;
while ((long) radpow * radix < SCM_BIGRAD)
{
SCM_DEFINE (scm_number_to_string, "number->string", 1, 1, 0,
(SCM n, SCM radix),
"Return a string holding the external representation of the\n"
- "number N in the given RADIX. If N is inexact, a radix of 10\n"
- "will be used.")
+ "number @var{n} in the given @var{radix}. If @var{n} is\n"
+ "inexact, a radix of 10 will be used.")
#define FUNC_NAME s_scm_number_to_string
{
int base;
if (SCM_INUMP (n)) {
char num_buf [SCM_INTBUFLEN];
- scm_sizet length = scm_iint2str (SCM_INUM (n), base, num_buf);
+ size_t length = scm_iint2str (SCM_INUM (n), base, num_buf);
return scm_makfromstr (num_buf, length, 0);
} else if (SCM_BIGP (n)) {
return big2str (n, (unsigned int) base);
} else if (SCM_INEXACTP (n)) {
- char num_buf [SCM_FLOBUFLEN];
+ char num_buf [FLOBUFLEN];
return scm_makfromstr (num_buf, iflo2str (n, num_buf), 0);
} else {
SCM_WRONG_TYPE_ARG (1, n);
int
scm_print_real (SCM sexp, SCM port, scm_print_state *pstate)
{
- char num_buf[SCM_FLOBUFLEN];
+ char num_buf[FLOBUFLEN];
scm_lfwrite (num_buf, iflo2str (sexp, num_buf), port);
return !0;
}
int
scm_print_complex (SCM sexp, SCM port, scm_print_state *pstate)
{
- char num_buf[SCM_FLOBUFLEN];
+ char num_buf[FLOBUFLEN];
scm_lfwrite (num_buf, iflo2str (sexp, num_buf), port);
return !0;
}
{
#ifdef SCM_BIGDIG
exp = big2str (exp, (unsigned int) 10);
- scm_lfwrite (SCM_STRING_CHARS (exp), (scm_sizet) SCM_STRING_LENGTH (exp), port);
+ scm_lfwrite (SCM_STRING_CHARS (exp), (size_t) SCM_STRING_LENGTH (exp), port);
#else
scm_ipruk ("bignum", exp, port);
#endif
SCM
scm_istr2int (char *str, long len, long radix)
{
- scm_sizet j;
- register scm_sizet k, blen = 1;
- scm_sizet i = 0;
+ size_t j;
+ register size_t k, blen = 1;
+ size_t i = 0;
int c;
SCM res;
register SCM_BIGDIG *ds;
if (++i == (unsigned) len)
return SCM_BOOL_F; /* bad if lone `+' or `-' */
}
- res = scm_mkbig (j, '-' == str[0]);
+ res = scm_i_mkbig (j, '-' == str[0]);
ds = SCM_BDIGITS (res);
for (k = j; k--;)
ds[k] = 0;
}
while (i < (unsigned) len);
if (blen * SCM_BITSPERDIG / SCM_CHAR_BIT <= sizeof (SCM))
- if (SCM_INUMP (res = scm_big2inum (res, blen)))
+ if (SCM_INUMP (res = scm_i_big2inum (res, blen)))
return res;
if (j == blen)
return res;
- return scm_adjbig (res, blen);
+ return scm_i_adjbig (res, blen);
}
SCM
SCM_DEFINE (scm_string_to_number, "string->number", 1, 1, 0,
(SCM string, SCM radix),
- "Returns a number of the maximally precise representation\n"
- "expressed by the given STRING. RADIX must be an exact integer,\n"
- "either 2, 8, 10, or 16. If supplied, RADIX is a default radix\n"
- "that may be overridden by an explicit radix prefix in STRING\n"
- "(e.g. \"#o177\"). If RADIX is not supplied, then the default\n"
- "radix is 10. If string is not a syntactically valid notation\n"
- "for a number, then `string->number' returns #f. (r5rs)")
+ "Return a number of the maximally precise representation\n"
+ "expressed by the given @var{string}. @var{radix} must be an\n"
+ "exact integer, either 2, 8, 10, or 16. If supplied, @var{radix}\n"
+ "is a default radix that may be overridden by an explicit radix\n"
+ "prefix in @var{string} (e.g. \"#o177\"). If @var{radix} is not\n"
+ "supplied, then the default radix is 10. If string is not a\n"
+ "syntactically valid notation for a number, then\n"
+ "@code{string->number} returns @code{#f}.")
#define FUNC_NAME s_scm_string_to_number
{
SCM answer;
SCM_REGISTER_PROC (s_number_p, "number?", 1, 0, 0, scm_number_p);
-
+/* "Return @code{#t} if @var{x} is a number, @code{#f}\n"
+ * "else. Note that the sets of complex, real, rational and\n"
+ * "integer values form subsets of the set of numbers, i. e. the\n"
+ * "predicate will be fulfilled for any number."
+ */
SCM_DEFINE (scm_number_p, "complex?", 1, 0, 0,
(SCM x),
- "Return #t if X is a complex number, #f else. Note that the\n"
- "sets of real, rational and integer values form subsets of the\n"
- "set of complex numbers, i. e. the predicate will also be\n"
- "fulfilled if X is a real, rational or integer number.")
+ "Return @code{#t} if @var{x} is a complex number, @code{#f}\n"
+ "else. Note that the sets of real, rational and integer\n"
+ "values form subsets of the set of complex numbers, i. e. the\n"
+ "predicate will also be fulfilled if @var{x} is a real,\n"
+ "rational or integer number.")
#define FUNC_NAME s_scm_number_p
{
return SCM_BOOL (SCM_NUMBERP (x));
SCM_REGISTER_PROC (s_real_p, "real?", 1, 0, 0, scm_real_p);
-
+/* "Return @code{#t} if @var{x} is a real number, @code{#f} else.\n"
+ * "Note that the sets of integer and rational values form a subset\n"
+ * "of the set of real numbers, i. e. the predicate will also\n"
+ * "be fulfilled if @var{x} is an integer or a rational number."
+ */
SCM_DEFINE (scm_real_p, "rational?", 1, 0, 0,
(SCM x),
- "Return #t if X is a rational number, #f else. Note that the\n"
- "set of integer values forms a subset of the set of rational\n"
- "numbers, i. e. the predicate will also be fulfilled if X is an\n"
- "integer number.")
+ "Return @code{#t} if @var{x} is a rational number, @code{#f}\n"
+ "else. Note that the set of integer values forms a subset of\n"
+ "the set of rational numbers, i. e. the predicate will also be\n"
+ "fulfilled if @var{x} is an integer number. Real numbers\n"
+ "will also satisfy this predicate, because of their limited\n"
+ "precision.")
#define FUNC_NAME s_scm_real_p
{
if (SCM_INUMP (x)) {
SCM_DEFINE (scm_integer_p, "integer?", 1, 0, 0,
(SCM x),
- "Return #t if X is an integer number, #f else.")
+ "Return @code{#t} if @var{x} is an integer number, @code{#f}\n"
+ "else.")
#define FUNC_NAME s_scm_integer_p
{
double r;
SCM_DEFINE (scm_inexact_p, "inexact?", 1, 0, 0,
(SCM x),
- "Return #t if X is an inexact number, #f else.")
+ "Return @code{#t} if @var{x} is an inexact number, @code{#f}\n"
+ "else.")
#define FUNC_NAME s_scm_inexact_p
{
return SCM_BOOL (SCM_INEXACTP (x));
SCM_GPROC1 (s_eq_p, "=", scm_tc7_rpsubr, scm_num_eq_p, g_eq_p);
-
+/* "Return @code{#t} if all parameters are numerically equal." */
SCM
scm_num_eq_p (SCM x, SCM y)
{
} else if (SCM_BIGP (y)) {
return SCM_BOOL (0 == scm_bigcomp (x, y));
} else if (SCM_REALP (y)) {
- return SCM_BOOL (scm_big2dbl (x) == SCM_REAL_VALUE (y));
+ return SCM_BOOL (scm_i_big2dbl (x) == SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
- return SCM_BOOL ((scm_big2dbl (x) == SCM_COMPLEX_REAL (y))
+ return SCM_BOOL ((scm_i_big2dbl (x) == SCM_COMPLEX_REAL (y))
&& (0.0 == SCM_COMPLEX_IMAG (y)));
} else {
SCM_WTA_DISPATCH_2 (g_eq_p, x, y, SCM_ARGn, s_eq_p);
if (SCM_INUMP (y)) {
return SCM_BOOL (SCM_REAL_VALUE (x) == (double) SCM_INUM (y));
} else if (SCM_BIGP (y)) {
- return SCM_BOOL (SCM_REAL_VALUE (x) == scm_big2dbl (y));
+ return SCM_BOOL (SCM_REAL_VALUE (x) == scm_i_big2dbl (y));
} else if (SCM_REALP (y)) {
return SCM_BOOL (SCM_REAL_VALUE (x) == SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
return SCM_BOOL ((SCM_COMPLEX_REAL (x) == (double) SCM_INUM (y))
&& (SCM_COMPLEX_IMAG (x) == 0.0));
} else if (SCM_BIGP (y)) {
- return SCM_BOOL ((SCM_COMPLEX_REAL (x) == scm_big2dbl (y))
+ return SCM_BOOL ((SCM_COMPLEX_REAL (x) == scm_i_big2dbl (y))
&& (SCM_COMPLEX_IMAG (x) == 0.0));
} else if (SCM_REALP (y)) {
return SCM_BOOL ((SCM_COMPLEX_REAL (x) == SCM_REAL_VALUE (y))
SCM_GPROC1 (s_less_p, "<", scm_tc7_rpsubr, scm_less_p, g_less_p);
-
+/* "Return @code{#t} if the list of parameters is monotonically\n"
+ * "increasing."
+ */
SCM
scm_less_p (SCM x, SCM y)
{
} else if (SCM_BIGP (y)) {
return SCM_BOOL (1 == scm_bigcomp (x, y));
} else if (SCM_REALP (y)) {
- return SCM_BOOL (scm_big2dbl (x) < SCM_REAL_VALUE (y));
+ return SCM_BOOL (scm_i_big2dbl (x) < SCM_REAL_VALUE (y));
} else {
SCM_WTA_DISPATCH_2 (g_less_p, x, y, SCM_ARGn, s_less_p);
}
if (SCM_INUMP (y)) {
return SCM_BOOL (SCM_REAL_VALUE (x) < (double) SCM_INUM (y));
} else if (SCM_BIGP (y)) {
- return SCM_BOOL (SCM_REAL_VALUE (x) < scm_big2dbl (y));
+ return SCM_BOOL (SCM_REAL_VALUE (x) < scm_i_big2dbl (y));
} else if (SCM_REALP (y)) {
return SCM_BOOL (SCM_REAL_VALUE (x) < SCM_REAL_VALUE (y));
} else {
SCM_GPROC1 (s_scm_gr_p, ">", scm_tc7_rpsubr, scm_gr_p, g_gr_p);
-/* "Return #t if the list of parameters is monotonically\n"
- * "increasing."
+/* "Return @code{#t} if the list of parameters is monotonically\n"
+ * "decreasing."
*/
#define FUNC_NAME s_scm_gr_p
SCM
SCM_GPROC1 (s_scm_leq_p, "<=", scm_tc7_rpsubr, scm_leq_p, g_leq_p);
-/* "Return #t if the list of parameters is monotonically\n"
+/* "Return @code{#t} if the list of parameters is monotonically\n"
* "non-decreasing."
*/
#define FUNC_NAME s_scm_leq_p
SCM_GPROC1 (s_scm_geq_p, ">=", scm_tc7_rpsubr, scm_geq_p, g_geq_p);
-/* "Return #t if the list of parameters is monotonically\n"
+/* "Return @code{#t} if the list of parameters is monotonically\n"
* "non-increasing."
*/
#define FUNC_NAME s_scm_geq_p
SCM_GPROC (s_zero_p, "zero?", 1, 0, 0, scm_zero_p, g_zero_p);
-
+/* "Return @code{#t} if @var{z} is an exact or inexact number equal to\n"
+ * "zero."
+ */
SCM
scm_zero_p (SCM z)
{
SCM_GPROC (s_positive_p, "positive?", 1, 0, 0, scm_positive_p, g_positive_p);
-
+/* "Return @code{#t} if @var{x} is an exact or inexact number greater than\n"
+ * "zero."
+ */
SCM
scm_positive_p (SCM x)
{
SCM_GPROC (s_negative_p, "negative?", 1, 0, 0, scm_negative_p, g_negative_p);
-
+/* "Return @code{#t} if @var{x} is an exact or inexact number less than\n"
+ * "zero."
+ */
SCM
scm_negative_p (SCM x)
{
SCM_GPROC1 (s_max, "max", scm_tc7_asubr, scm_max, g_max);
-
+/* "Return the maximum of all parameter values."
+ */
SCM
scm_max (SCM x, SCM y)
{
if (SCM_UNBNDP (y)) {
if (SCM_UNBNDP (x)) {
- SCM_WTA_DISPATCH_0 (g_max, x, SCM_ARG1, s_max);
+ SCM_WTA_DISPATCH_0 (g_max, s_max);
} else if (SCM_NUMBERP (x)) {
return x;
} else {
} else if (SCM_BIGP (y)) {
return (1 == scm_bigcomp (x, y)) ? y : x;
} else if (SCM_REALP (y)) {
- double z = scm_big2dbl (x);
+ double z = scm_i_big2dbl (x);
return (z <= SCM_REAL_VALUE (y)) ? y : scm_make_real (z);
} else {
SCM_WTA_DISPATCH_2 (g_max, x, y, SCM_ARGn, s_max);
double z = SCM_INUM (y);
return (SCM_REAL_VALUE (x) < z) ? scm_make_real (z) : x;
} else if (SCM_BIGP (y)) {
- double z = scm_big2dbl (y);
+ double z = scm_i_big2dbl (y);
return (SCM_REAL_VALUE (x) < z) ? scm_make_real (z) : x;
} else if (SCM_REALP (y)) {
return (SCM_REAL_VALUE (x) < SCM_REAL_VALUE (y)) ? y : x;
SCM_GPROC1 (s_min, "min", scm_tc7_asubr, scm_min, g_min);
-
+/* "Return the minium of all parameter values."
+ */
SCM
scm_min (SCM x, SCM y)
{
if (SCM_UNBNDP (y)) {
if (SCM_UNBNDP (x)) {
- SCM_WTA_DISPATCH_0 (g_min, x, SCM_ARG1, s_min);
+ SCM_WTA_DISPATCH_0 (g_min, s_min);
} else if (SCM_NUMBERP (x)) {
return x;
} else {
} else if (SCM_BIGP (y)) {
return (-1 == scm_bigcomp (x, y)) ? y : x;
} else if (SCM_REALP (y)) {
- double z = scm_big2dbl (x);
+ double z = scm_i_big2dbl (x);
return (z < SCM_REAL_VALUE (y)) ? scm_make_real (z) : y;
} else {
SCM_WTA_DISPATCH_2 (g_min, x, y, SCM_ARGn, s_min);
double z = SCM_INUM (y);
return (SCM_REAL_VALUE (x) <= z) ? x : scm_make_real (z);
} else if (SCM_BIGP (y)) {
- double z = scm_big2dbl (y);
+ double z = scm_i_big2dbl (y);
return (SCM_REAL_VALUE (x) <= z) ? x : scm_make_real (z);
} else if (SCM_REALP (y)) {
return (SCM_REAL_VALUE (x) < SCM_REAL_VALUE (y)) ? x : y;
SCM_GPROC1 (s_sum, "+", scm_tc7_asubr, scm_sum, g_sum);
-
+/* "Return the sum of all parameter values. Return 0 if called without\n"
+ * "any parameters."
+ */
SCM
scm_sum (SCM x, SCM y)
{
return SCM_MAKINUM (z);
} else {
#ifdef SCM_BIGDIG
- return scm_long2big (z);
+ return scm_i_long2big (z);
#else /* SCM_BIGDIG */
return scm_make_real ((double) z);
#endif /* SCM_BIGDIG */
return scm_addbig (SCM_BDIGITS (x), SCM_NUMDIGS (x),
SCM_BIGSIGN (x), y, 0);
} else if (SCM_REALP (y)) {
- return scm_make_real (scm_big2dbl (x) + SCM_REAL_VALUE (y));
+ return scm_make_real (scm_i_big2dbl (x) + SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
- return scm_make_complex (scm_big2dbl (x) + SCM_COMPLEX_REAL (y),
+ return scm_make_complex (scm_i_big2dbl (x) + SCM_COMPLEX_REAL (y),
SCM_COMPLEX_IMAG (y));
} else {
SCM_WTA_DISPATCH_2 (g_sum, x, y, SCM_ARGn, s_sum);
if (SCM_INUMP (y)) {
return scm_make_real (SCM_REAL_VALUE (x) + SCM_INUM (y));
} else if (SCM_BIGP (y)) {
- return scm_make_real (SCM_REAL_VALUE (x) + scm_big2dbl (y));
+ return scm_make_real (SCM_REAL_VALUE (x) + scm_i_big2dbl (y));
} else if (SCM_REALP (y)) {
return scm_make_real (SCM_REAL_VALUE (x) + SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
return scm_make_complex (SCM_COMPLEX_REAL (x) + SCM_INUM (y),
SCM_COMPLEX_IMAG (x));
} else if (SCM_BIGP (y)) {
- return scm_make_complex (SCM_COMPLEX_REAL (x) + scm_big2dbl (y),
+ return scm_make_complex (SCM_COMPLEX_REAL (x) + scm_i_big2dbl (y),
SCM_COMPLEX_IMAG (x));
} else if (SCM_REALP (y)) {
return scm_make_complex (SCM_COMPLEX_REAL (x) + SCM_REAL_VALUE (y),
SCM_GPROC1 (s_difference, "-", scm_tc7_asubr, scm_difference, g_difference);
-
+/* "If called without arguments, 0 is returned. Otherwise the sum of\n"
+ * "all but the first argument are subtracted from the first\n"
+ * "argument."
+ */
+#define FUNC_NAME s_difference
SCM
scm_difference (SCM x, SCM y)
{
if (SCM_UNBNDP (y)) {
- if (SCM_INUMP (x)) {
+ if (SCM_UNBNDP (x)) {
+ SCM_WTA_DISPATCH_0 (g_difference, s_difference);
+ } else if (SCM_INUMP (x)) {
long xx = -SCM_INUM (x);
if (SCM_FIXABLE (xx)) {
return SCM_MAKINUM (xx);
} else {
#ifdef SCM_BIGDIG
- return scm_long2big (xx);
+ return scm_i_long2big (xx);
#else
return scm_make_real ((double) xx);
#endif
}
} else if (SCM_BIGP (x)) {
- SCM z = scm_copybig (x, !SCM_BIGSIGN (x));
+ SCM z = scm_i_copybig (x, !SCM_BIGSIGN (x));
unsigned int digs = SCM_NUMDIGS (z);
unsigned int size = digs * SCM_BITSPERDIG / SCM_CHAR_BIT;
- return size <= sizeof (SCM) ? scm_big2inum (z, digs) : z;
+ return size <= sizeof (SCM) ? scm_i_big2inum (z, digs) : z;
} else if (SCM_REALP (x)) {
return scm_make_real (-SCM_REAL_VALUE (x));
} else if (SCM_COMPLEXP (x)) {
return SCM_MAKINUM (z);
} else {
#ifdef SCM_BIGDIG
- return scm_long2big (z);
+ return scm_i_long2big (z);
#else
return scm_make_real ((double) z);
#endif
: scm_addbig (SCM_BDIGITS (y), SCM_NUMDIGS (y),
SCM_BIGSIGN (y) ^ SCM_BIGSIGNFLAG, x, 0);
} else if (SCM_REALP (y)) {
- return scm_make_real (scm_big2dbl (x) - SCM_REAL_VALUE (y));
+ return scm_make_real (scm_i_big2dbl (x) - SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
- return scm_make_complex (scm_big2dbl (x) - SCM_COMPLEX_REAL (y),
+ return scm_make_complex (scm_i_big2dbl (x) - SCM_COMPLEX_REAL (y),
- SCM_COMPLEX_IMAG (y));
} else {
SCM_WTA_DISPATCH_2 (g_difference, x, y, SCM_ARGn, s_difference);
if (SCM_INUMP (y)) {
return scm_make_real (SCM_REAL_VALUE (x) - SCM_INUM (y));
} else if (SCM_BIGP (y)) {
- return scm_make_real (SCM_REAL_VALUE (x) - scm_big2dbl (y));
+ return scm_make_real (SCM_REAL_VALUE (x) - scm_i_big2dbl (y));
} else if (SCM_REALP (y)) {
return scm_make_real (SCM_REAL_VALUE (x) - SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
return scm_make_complex (SCM_COMPLEX_REAL (x) - SCM_INUM (y),
SCM_COMPLEX_IMAG (x));
} else if (SCM_BIGP (y)) {
- return scm_make_complex (SCM_COMPLEX_REAL (x) - scm_big2dbl (y),
+ return scm_make_complex (SCM_COMPLEX_REAL (x) - scm_i_big2dbl (y),
SCM_COMPLEX_IMAG (x));
} else if (SCM_REALP (y)) {
return scm_make_complex (SCM_COMPLEX_REAL (x) - SCM_REAL_VALUE (y),
SCM_WTA_DISPATCH_2 (g_difference, x, y, SCM_ARG1, s_difference);
}
}
-
+#undef FUNC_NAME
SCM_GPROC1 (s_product, "*", scm_tc7_asubr, scm_product, g_product);
-
+/* "Return the product of all arguments. If called without arguments,\n"
+ * "1 is returned."
+ */
SCM
scm_product (SCM x, SCM y)
{
SCM_BDIGITS (y), SCM_NUMDIGS (y),
SCM_BIGSIGN (x) ^ SCM_BIGSIGN (y));
} else if (SCM_REALP (y)) {
- return scm_make_real (scm_big2dbl (x) * SCM_REAL_VALUE (y));
+ return scm_make_real (scm_i_big2dbl (x) * SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
- double z = scm_big2dbl (x);
+ double z = scm_i_big2dbl (x);
return scm_make_complex (z * SCM_COMPLEX_REAL (y),
z * SCM_COMPLEX_IMAG (y));
} else {
if (SCM_INUMP (y)) {
return scm_make_real (SCM_INUM (y) * SCM_REAL_VALUE (x));
} else if (SCM_BIGP (y)) {
- return scm_make_real (scm_big2dbl (y) * SCM_REAL_VALUE (x));
+ return scm_make_real (scm_i_big2dbl (y) * SCM_REAL_VALUE (x));
} else if (SCM_REALP (y)) {
return scm_make_real (SCM_REAL_VALUE (x) * SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
return scm_make_complex (SCM_INUM (y) * SCM_COMPLEX_REAL (x),
SCM_INUM (y) * SCM_COMPLEX_IMAG (x));
} else if (SCM_BIGP (y)) {
- double z = scm_big2dbl (y);
+ double z = scm_i_big2dbl (y);
return scm_make_complex (z * SCM_COMPLEX_REAL (x),
z * SCM_COMPLEX_IMAG (x));
} else if (SCM_REALP (y)) {
if (SCM_INUMP (a)) {
return (double) SCM_INUM (a);
} else if (SCM_BIGP (a)) {
- return scm_big2dbl (a);
+ return scm_i_big2dbl (a);
} else if (SCM_REALP (a)) {
return (SCM_REAL_VALUE (a));
} else {
SCM_GPROC1 (s_divide, "/", scm_tc7_asubr, scm_divide, g_divide);
-
+/* "Divide the first argument by the product of the remaining arguments."
+ */
+#define FUNC_NAME s_divide
SCM
scm_divide (SCM x, SCM y)
{
if (SCM_UNBNDP (y)) {
if (SCM_UNBNDP (x)) {
- SCM_WTA_DISPATCH_0 (g_divide, x, SCM_ARG1, s_divide);
+ SCM_WTA_DISPATCH_0 (g_divide, s_divide);
} else if (SCM_INUMP (x)) {
if (SCM_EQ_P (x, SCM_MAKINUM (1L)) || SCM_EQ_P (x, SCM_MAKINUM (-1L))) {
return x;
return scm_make_real (1.0 / (double) SCM_INUM (x));
}
} else if (SCM_BIGP (x)) {
- return scm_make_real (1.0 / scm_big2dbl (x));
+ return scm_make_real (1.0 / scm_i_big2dbl (x));
} else if (SCM_REALP (x)) {
return scm_make_real (1.0 / SCM_REAL_VALUE (x));
} else if (SCM_COMPLEXP (x)) {
return SCM_MAKINUM (z);
} else {
#ifdef SCM_BIGDIG
- return scm_long2big (z);
+ return scm_i_long2big (z);
#else
return scm_make_real ((double) xx / (double) yy);
#endif
}
}
} else if (SCM_BIGP (y)) {
- return scm_make_real ((double) xx / scm_big2dbl (y));
+ return scm_make_real ((double) xx / scm_i_big2dbl (y));
} else if (SCM_REALP (y)) {
return scm_make_real ((double) xx / SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
} else {
long z = yy < 0 ? -yy : yy;
if (z < SCM_BIGRAD) {
- SCM w = scm_copybig (x, SCM_BIGSIGN (x) ? (yy > 0) : (yy < 0));
+ SCM w = scm_i_copybig (x, SCM_BIGSIGN (x) ? (yy > 0) : (yy < 0));
return scm_divbigdig (SCM_BDIGITS (w), SCM_NUMDIGS (w),
(SCM_BIGDIG) z)
- ? scm_make_real (scm_big2dbl (x) / (double) yy)
- : scm_normbig (w);
+ ? scm_make_real (scm_i_big2dbl (x) / (double) yy)
+ : scm_i_normbig (w);
} else {
SCM w;
#ifndef SCM_DIGSTOOBIG
#endif
return (!SCM_UNBNDP (w))
? w
- : scm_make_real (scm_big2dbl (x) / (double) yy);
+ : scm_make_real (scm_i_big2dbl (x) / (double) yy);
}
}
} else if (SCM_BIGP (y)) {
SCM_BIGSIGN (x) ^ SCM_BIGSIGN (y), 3);
return (!SCM_UNBNDP (w))
? w
- : scm_make_real (scm_big2dbl (x) / scm_big2dbl (y));
+ : scm_make_real (scm_i_big2dbl (x) / scm_i_big2dbl (y));
} else if (SCM_REALP (y)) {
- return scm_make_real (scm_big2dbl (x) / SCM_REAL_VALUE (y));
+ return scm_make_real (scm_i_big2dbl (x) / SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
- a = scm_big2dbl (x);
+ a = scm_i_big2dbl (x);
goto complex_div;
} else {
SCM_WTA_DISPATCH_2 (g_divide, x, y, SCM_ARGn, s_divide);
if (SCM_INUMP (y)) {
return scm_make_real (rx / (double) SCM_INUM (y));
} else if (SCM_BIGP (y)) {
- return scm_make_real (rx / scm_big2dbl (y));
+ return scm_make_real (rx / scm_i_big2dbl (y));
} else if (SCM_REALP (y)) {
return scm_make_real (rx / SCM_REAL_VALUE (y));
} else if (SCM_COMPLEXP (y)) {
double d = SCM_INUM (y);
return scm_make_complex (rx / d, ix / d);
} else if (SCM_BIGP (y)) {
- double d = scm_big2dbl (y);
+ double d = scm_i_big2dbl (y);
return scm_make_complex (rx / d, ix / d);
} else if (SCM_REALP (y)) {
double d = SCM_REAL_VALUE (y);
SCM_WTA_DISPATCH_2 (g_divide, x, y, SCM_ARG1, s_divide);
}
}
-
+#undef FUNC_NAME
SCM_GPROC1 (s_asinh, "$asinh", scm_tc7_cxr, (SCM (*)()) scm_asinh, g_asinh);
-
+/* "Return the inverse hyperbolic sine of @var{x}."
+ */
double
scm_asinh (double x)
{
SCM_GPROC1 (s_acosh, "$acosh", scm_tc7_cxr, (SCM (*)()) scm_acosh, g_acosh);
-
+/* "Return the inverse hyperbolic cosine of @var{x}."
+ */
double
scm_acosh (double x)
{
SCM_GPROC1 (s_atanh, "$atanh", scm_tc7_cxr, (SCM (*)()) scm_atanh, g_atanh);
-
+/* "Return the inverse hyperbolic tangent of @var{x}."
+ */
double
scm_atanh (double x)
{
SCM_GPROC1 (s_truncate, "truncate", scm_tc7_cxr, (SCM (*)()) scm_truncate, g_truncate);
-
+/* "Round the inexact number @var{x} towards zero."
+ */
double
scm_truncate (double x)
{
SCM_GPROC1 (s_round, "round", scm_tc7_cxr, (SCM (*)()) scm_round, g_round);
-
+/* "Round the inexact number @var{x}. If @var{x} is halfway between two\n"
+ * "numbers, round towards even."
+ */
double
scm_round (double x)
{
SCM_GPROC1 (s_exact_to_inexact, "exact->inexact", scm_tc7_cxr, (SCM (*)()) scm_exact_to_inexact, g_exact_to_inexact);
-
+/* Convert the number @var{x} to its inexact representation.\n"
+ */
double
scm_exact_to_inexact (double z)
{
SCM_GPROC1 (s_i_floor, "floor", scm_tc7_cxr, (SCM (*)()) floor, g_i_floor);
+/* "Round the number @var{x} towards minus infinity."
+ */
SCM_GPROC1 (s_i_ceil, "ceiling", scm_tc7_cxr, (SCM (*)()) ceil, g_i_ceil);
+/* "Round the number @var{x} towards infinity."
+ */
SCM_GPROC1 (s_i_sqrt, "$sqrt", scm_tc7_cxr, (SCM (*)()) sqrt, g_i_sqrt);
+/* "Return the square root of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_abs, "$abs", scm_tc7_cxr, (SCM (*)()) fabs, g_i_abs);
+/* "Return the absolute value of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_exp, "$exp", scm_tc7_cxr, (SCM (*)()) exp, g_i_exp);
+/* "Return the @var{x}th power of e."
+ */
SCM_GPROC1 (s_i_log, "$log", scm_tc7_cxr, (SCM (*)()) log, g_i_log);
+/* "Return the natural logarithm of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_sin, "$sin", scm_tc7_cxr, (SCM (*)()) sin, g_i_sin);
+/* "Return the sine of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_cos, "$cos", scm_tc7_cxr, (SCM (*)()) cos, g_i_cos);
+/* "Return the cosine of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_tan, "$tan", scm_tc7_cxr, (SCM (*)()) tan, g_i_tan);
+/* "Return the tangent of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_asin, "$asin", scm_tc7_cxr, (SCM (*)()) asin, g_i_asin);
+/* "Return the arc sine of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_acos, "$acos", scm_tc7_cxr, (SCM (*)()) acos, g_i_acos);
+/* "Return the arc cosine of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_atan, "$atan", scm_tc7_cxr, (SCM (*)()) atan, g_i_atan);
+/* "Return the arc tangent of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_sinh, "$sinh", scm_tc7_cxr, (SCM (*)()) sinh, g_i_sinh);
+/* "Return the hyperbolic sine of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_cosh, "$cosh", scm_tc7_cxr, (SCM (*)()) cosh, g_i_cosh);
+/* "Return the hyperbolic cosine of the real number @var{x}."
+ */
SCM_GPROC1 (s_i_tanh, "$tanh", scm_tc7_cxr, (SCM (*)()) tanh, g_i_tanh);
+/* "Return the hyperbolic tangent of the real number @var{x}."
+ */
struct dpair
{
double x, y;
};
-static void scm_two_doubles (SCM z1,
- SCM z2,
+static void scm_two_doubles (SCM x,
+ SCM y,
const char *sstring,
struct dpair * xy);
static void
-scm_two_doubles (SCM z1, SCM z2, const char *sstring, struct dpair *xy)
+scm_two_doubles (SCM x, SCM y, const char *sstring, struct dpair *xy)
{
- if (SCM_INUMP (z1)) {
- xy->x = SCM_INUM (z1);
- } else if (SCM_BIGP (z1)) {
- xy->x = scm_big2dbl (z1);
- } else if (SCM_REALP (z1)) {
- xy->x = SCM_REAL_VALUE (z1);
+ if (SCM_INUMP (x)) {
+ xy->x = SCM_INUM (x);
+ } else if (SCM_BIGP (x)) {
+ xy->x = scm_i_big2dbl (x);
+ } else if (SCM_REALP (x)) {
+ xy->x = SCM_REAL_VALUE (x);
} else {
- scm_wrong_type_arg (sstring, SCM_ARG1, z1);
+ scm_wrong_type_arg (sstring, SCM_ARG1, x);
}
- if (SCM_INUMP (z2)) {
- xy->y = SCM_INUM (z2);
- } else if (SCM_BIGP (z2)) {
- xy->y = scm_big2dbl (z2);
- } else if (SCM_REALP (z2)) {
- xy->y = SCM_REAL_VALUE (z2);
+ if (SCM_INUMP (y)) {
+ xy->y = SCM_INUM (y);
+ } else if (SCM_BIGP (y)) {
+ xy->y = scm_i_big2dbl (y);
+ } else if (SCM_REALP (y)) {
+ xy->y = SCM_REAL_VALUE (y);
} else {
- scm_wrong_type_arg (sstring, SCM_ARG2, z2);
+ scm_wrong_type_arg (sstring, SCM_ARG2, y);
}
}
SCM_DEFINE (scm_sys_expt, "$expt", 2, 0, 0,
- (SCM z1, SCM z2),
- "")
+ (SCM x, SCM y),
+ "Return @var{x} raised to the power of @var{y}. This\n"
+ "procedure does not accept complex arguments.")
#define FUNC_NAME s_scm_sys_expt
{
struct dpair xy;
- scm_two_doubles (z1, z2, FUNC_NAME, &xy);
+ scm_two_doubles (x, y, FUNC_NAME, &xy);
return scm_make_real (pow (xy.x, xy.y));
}
#undef FUNC_NAME
SCM_DEFINE (scm_sys_atan2, "$atan2", 2, 0, 0,
- (SCM z1, SCM z2),
- "")
+ (SCM x, SCM y),
+ "Return the arc tangent of the two arguments @var{x} and\n"
+ "@var{y}. This is similar to calculating the arc tangent of\n"
+ "@var{x} / @var{y}, except that the signs of both arguments\n"
+ "are used to determine the quadrant of the result. This\n"
+ "procedure does not accept complex arguments.")
#define FUNC_NAME s_scm_sys_atan2
{
struct dpair xy;
- scm_two_doubles (z1, z2, FUNC_NAME, &xy);
+ scm_two_doubles (x, y, FUNC_NAME, &xy);
return scm_make_real (atan2 (xy.x, xy.y));
}
#undef FUNC_NAME
SCM_DEFINE (scm_make_rectangular, "make-rectangular", 2, 0, 0,
(SCM real, SCM imaginary),
- "Return a complex number constructed of the given REAL and\n"
- "IMAGINARY parts.")
+ "Return a complex number constructed of the given @var{real} and\n"
+ "@var{imaginary} parts.")
#define FUNC_NAME s_scm_make_rectangular
{
struct dpair xy;
SCM_DEFINE (scm_make_polar, "make-polar", 2, 0, 0,
- (SCM z1, SCM z2),
- "Return the complex number Z1 * e^(i * Z2).")
+ (SCM x, SCM y),
+ "Return the complex number @var{x} * e^(i * @var{y}).")
#define FUNC_NAME s_scm_make_polar
{
struct dpair xy;
- scm_two_doubles (z1, z2, FUNC_NAME, &xy);
+ scm_two_doubles (x, y, FUNC_NAME, &xy);
return scm_make_complex (xy.x * cos (xy.y), xy.x * sin (xy.y));
}
#undef FUNC_NAME
SCM_GPROC (s_real_part, "real-part", 1, 0, 0, scm_real_part, g_real_part);
-
+/* "Return the real part of the number @var{z}."
+ */
SCM
scm_real_part (SCM z)
{
SCM_GPROC (s_imag_part, "imag-part", 1, 0, 0, scm_imag_part, g_imag_part);
-
+/* "Return the imaginary part of the number @var{z}."
+ */
SCM
scm_imag_part (SCM z)
{
SCM_GPROC (s_magnitude, "magnitude", 1, 0, 0, scm_magnitude, g_magnitude);
-
+/* "Return the magnitude of the number @var{z}. This is the same as\n"
+ * "@code{abs} for real arguments, but also allows complex numbers."
+ */
SCM
scm_magnitude (SCM z)
{
return SCM_MAKINUM (-zz);
} else {
#ifdef SCM_BIGDIG
- return scm_long2big (-zz);
+ return scm_i_long2big (-zz);
#else
scm_num_overflow (s_magnitude);
#endif
if (!SCM_BIGSIGN (z)) {
return z;
} else {
- return scm_copybig (z, 0);
+ return scm_i_copybig (z, 0);
}
} else if (SCM_REALP (z)) {
return scm_make_real (fabs (SCM_REAL_VALUE (z)));
SCM_GPROC (s_angle, "angle", 1, 0, 0, scm_angle, g_angle);
-
+/* "Return the angle of the complex number @var{z}."
+ */
SCM
scm_angle (SCM z)
{
SCM_DEFINE (scm_inexact_to_exact, "inexact->exact", 1, 0, 0,
(SCM z),
- "Returns an exact number that is numerically closest to Z.")
+ "Return an exact number that is numerically closest to @var{z}.")
#define FUNC_NAME s_scm_inexact_to_exact
{
if (SCM_INUMP (z)) {
return SCM_MAKINUM (lu);
#ifdef SCM_BIGDIG
} else if (isfinite (u)) {
- return scm_dbl2big (u);
+ return scm_i_dbl2big (u);
#endif
} else {
scm_num_overflow (s_scm_inexact_to_exact);
/* d must be integer */
SCM
-scm_dbl2big (double d)
+scm_i_dbl2big (double d)
{
- scm_sizet i = 0;
+ size_t i = 0;
long c;
SCM_BIGDIG *digits;
SCM ans;
u /= SCM_BIGRAD;
i++;
}
- ans = scm_mkbig (i, d < 0);
+ ans = scm_i_mkbig (i, d < 0);
digits = SCM_BDIGITS (ans);
while (i--)
{
return ans;
}
-
-
double
-scm_big2dbl (SCM b)
+scm_i_big2dbl (SCM b)
{
double ans = 0.0;
- scm_sizet i = SCM_NUMDIGS (b);
+ size_t i = SCM_NUMDIGS (b);
SCM_BIGDIG *digits = SCM_BDIGITS (b);
while (i--)
ans = digits[i] + SCM_BIGRAD * ans;
return - ans;
return ans;
}
-#endif
-
-SCM
-scm_long2num (long sl)
-{
- if (!SCM_FIXABLE (sl))
- {
-#ifdef SCM_BIGDIG
- return scm_long2big (sl);
-#else
- return scm_make_real ((double) sl);
#endif
- }
- return SCM_MAKINUM (sl);
-}
-
#ifdef HAVE_LONG_LONGS
-
-SCM
-scm_long_long2num (long_long sl)
-{
- if (!SCM_FIXABLE (sl))
- {
-#ifdef SCM_BIGDIG
- return scm_long_long2big (sl);
-#else
- return scm_make_real ((double) sl);
+# ifndef LLONG_MAX
+# define ULLONG_MAX ((unsigned long long) (-1))
+# define LLONG_MAX ((long long) (ULLONG_MAX >> 1))
+# define LLONG_MIN (~LLONG_MAX)
+# endif
#endif
- }
- else
- {
- /* we know that sl fits into an inum */
- return SCM_MAKINUM ((scm_bits_t) sl);
- }
-}
-#endif /* HAVE_LONG_LONGS */
+#define SIZE_MAX ((size_t) (-1))
+/* the below is not really guaranteed to work (I think), but probably does: */
+#define PTRDIFF_MIN ((ptrdiff_t) ((ptrdiff_t)1 << (sizeof (ptrdiff_t) * 8 - 1)))
+#define PTRDIFF_MAX (~ PTRDIFF_MIN)
+
+#define NUM2INTEGRAL scm_num2short
+#define INTEGRAL2NUM scm_short2num
+#define INTEGRAL2BIG scm_i_short2big
+#define ITYPE short
+#define MIN_VALUE SHRT_MIN
+#define MAX_VALUE SHRT_MAX
+#include "libguile/num2integral.i.c"
+
+#define NUM2INTEGRAL scm_num2ushort
+#define INTEGRAL2NUM scm_ushort2num
+#define INTEGRAL2BIG scm_i_ushort2big
+#define UNSIGNED
+#define ITYPE unsigned short
+#define MAX_VALUE USHRT_MAX
+#include "libguile/num2integral.i.c"
+
+#define NUM2INTEGRAL scm_num2int
+#define INTEGRAL2NUM scm_int2num
+#define INTEGRAL2BIG scm_i_int2big
+#define ITYPE int
+#define MIN_VALUE INT_MIN
+#define MAX_VALUE INT_MAX
+#include "libguile/num2integral.i.c"
+
+#define NUM2INTEGRAL scm_num2uint
+#define INTEGRAL2NUM scm_uint2num
+#define INTEGRAL2BIG scm_i_uint2big
+#define UNSIGNED
+#define ITYPE unsigned int
+#define MAX_VALUE UINT_MAX
+#include "libguile/num2integral.i.c"
+
+#define NUM2INTEGRAL scm_num2long
+#define INTEGRAL2NUM scm_long2num
+#define INTEGRAL2BIG scm_i_long2big
+#define ITYPE long
+#define MIN_VALUE LONG_MIN
+#define MAX_VALUE LONG_MAX
+#include "libguile/num2integral.i.c"
+
+#define NUM2INTEGRAL scm_num2ulong
+#define INTEGRAL2NUM scm_ulong2num
+#define INTEGRAL2BIG scm_i_ulong2big
+#define UNSIGNED
+#define ITYPE unsigned long
+#define MAX_VALUE ULONG_MAX
+#include "libguile/num2integral.i.c"
+
+#define NUM2INTEGRAL scm_num2ptrdiff
+#define INTEGRAL2NUM scm_ptrdiff2num
+#define INTEGRAL2BIG scm_i_ptrdiff2big
+#define ITYPE ptrdiff_t
+#define MIN_VALUE PTRDIFF_MIN
+#define MAX_VALUE PTRDIFF_MAX
+#include "libguile/num2integral.i.c"
+
+#define NUM2INTEGRAL scm_num2size
+#define INTEGRAL2NUM scm_size2num
+#define INTEGRAL2BIG scm_i_size2big
+#define UNSIGNED
+#define ITYPE size_t
+#define MAX_VALUE SIZE_MAX
+#include "libguile/num2integral.i.c"
+#ifdef HAVE_LONG_LONGS
-SCM
-scm_ulong2num (unsigned long sl)
-{
- if (!SCM_POSFIXABLE (sl))
- {
-#ifdef SCM_BIGDIG
- return scm_ulong2big (sl);
-#else
- return scm_make_real ((double) sl);
+#ifndef ULONG_LONG_MAX
+#define ULONG_LONG_MAX (~0ULL)
#endif
- }
- return SCM_MAKINUM (sl);
-}
+#define NUM2INTEGRAL scm_num2long_long
+#define INTEGRAL2NUM scm_long_long2num
+#define INTEGRAL2BIG scm_i_long_long2big
+#define ITYPE long long
+#define MIN_VALUE LLONG_MIN
+#define MAX_VALUE LLONG_MAX
+#include "libguile/num2integral.i.c"
+
+#define NUM2INTEGRAL scm_num2ulong_long
+#define INTEGRAL2NUM scm_ulong_long2num
+#define INTEGRAL2BIG scm_i_ulong_long2big
+#define UNSIGNED
+#define ITYPE unsigned long long
+#define MAX_VALUE ULLONG_MAX
+#include "libguile/num2integral.i.c"
-long
-scm_num2long (SCM num, char *pos, const char *s_caller)
-{
- if (SCM_INUMP (num)) {
- return SCM_INUM (num);
- } else if (SCM_BIGP (num)) {
- long int res;
- /* can't use res directly in case num is -2^31. */
- unsigned long int pos_res = 0;
- unsigned long int old_res = 0;
- scm_sizet l;
-
- for (l = SCM_NUMDIGS (num); l--;) {
- pos_res = SCM_BIGUP (pos_res) + SCM_BDIGITS (num)[l];
- if (pos_res >= old_res) {
- old_res = pos_res;
- } else {
- /* overflow. */
- scm_out_of_range (s_caller, num);
- }
- }
- if (SCM_BIGSIGN (num)) {
- res = -pos_res;
- if (res <= 0) {
- return res;
- } else {
- scm_out_of_range (s_caller, num);
- }
- } else {
- res = pos_res;
- if (res >= 0) {
- return res;
- } else {
- scm_out_of_range (s_caller, num);
- }
- }
- } else if (SCM_REALP (num)) {
- double u = SCM_REAL_VALUE (num);
- long int res = u;
- if ((double) res == u) {
- return res;
- } else {
- scm_out_of_range (s_caller, num);
- }
- } else {
- scm_wrong_type_arg (s_caller, (int) pos, num);
- }
-}
+#endif /* HAVE_LONG_LONGS */
+#ifdef GUILE_DEBUG
-#ifdef HAVE_LONG_LONGS
+#define CHECK(type, v) \
+ do { \
+ if ((v) != scm_num2##type (scm_##type##2num (v), 1, "check_sanity")) \
+ abort (); \
+ } while (0);
-long_long
-scm_num2long_long (SCM num, char *pos, const char *s_caller)
+static void
+check_sanity ()
{
- if (SCM_INUMP (num)) {
- return SCM_INUM (num);
- } else if (SCM_BIGP (num)) {
- long long res;
- /* can't use res directly in case num is -2^63. */
- unsigned long long int pos_res = 0;
- unsigned long long int old_res = 0;
- scm_sizet l;
-
- for (l = SCM_NUMDIGS (num); l--;) {
- pos_res = SCM_LONGLONGBIGUP (pos_res) + SCM_BDIGITS (num)[l];
- if (pos_res >= old_res) {
- old_res = pos_res;
- } else {
- /* overflow. */
- scm_out_of_range (s_caller, num);
- }
- }
- if (SCM_BIGSIGN (num)) {
- res = -pos_res;
- if (res <= 0) {
- return res;
- } else {
- scm_out_of_range (s_caller, num);
- }
- } else {
- res = pos_res;
- if (res >= 0) {
- return res;
- } else {
- scm_out_of_range (s_caller, num);
- }
- }
- } else if (SCM_REALP (num)) {
- double u = SCM_REAL_VALUE (num);
- long long int res = u;
- if ((double) res == u) {
- return res;
- } else {
- scm_out_of_range (s_caller, num);
- }
- } else {
- scm_wrong_type_arg (s_caller, (int) pos, num);
- }
-}
+ CHECK (short, 0);
+ CHECK (ushort, 0U);
+ CHECK (int, 0);
+ CHECK (uint, 0U);
+ CHECK (long, 0L);
+ CHECK (ulong, 0UL);
+ CHECK (size, 0);
+ CHECK (ptrdiff, 0);
+
+ CHECK (short, -1);
+ CHECK (int, -1);
+ CHECK (long, -1L);
+ CHECK (ptrdiff, -1);
+
+ CHECK (short, SHRT_MAX);
+ CHECK (short, SHRT_MIN);
+ CHECK (ushort, USHRT_MAX);
+ CHECK (int, INT_MAX);
+ CHECK (int, INT_MIN);
+ CHECK (uint, UINT_MAX);
+ CHECK (long, LONG_MAX);
+ CHECK (long, LONG_MIN);
+ CHECK (ulong, ULONG_MAX);
+ CHECK (size, SIZE_MAX);
+ CHECK (ptrdiff, PTRDIFF_MAX);
+ CHECK (ptrdiff, PTRDIFF_MIN);
-#endif /* HAVE_LONG_LONGS */
+#ifdef HAVE_LONG_LONGS
+ CHECK (long_long, 0LL);
+ CHECK (ulong_long, 0ULL);
+ CHECK (long_long, -1LL);
-unsigned long
-scm_num2ulong (SCM num, char *pos, const char *s_caller)
-{
- if (SCM_INUMP (num)) {
- long nnum = SCM_INUM (num);
- if (nnum >= 0) {
- return nnum;
- } else {
- scm_out_of_range (s_caller, num);
- }
- } else if (SCM_BIGP (num)) {
- unsigned long int res = 0;
- unsigned long int old_res = 0;
- scm_sizet l;
-
- for (l = SCM_NUMDIGS (num); l--;) {
- res = SCM_BIGUP (res) + SCM_BDIGITS (num)[l];
- if (res >= old_res) {
- old_res = res;
- } else {
- scm_out_of_range (s_caller, num);
- }
- }
- return res;
- } else if (SCM_REALP (num)) {
- double u = SCM_REAL_VALUE (num);
- unsigned long int res = u;
- if ((double) res == u) {
- return res;
- } else {
- scm_out_of_range (s_caller, num);
- }
- } else {
- scm_wrong_type_arg (s_caller, (int) pos, num);
- }
+ CHECK (long_long, LLONG_MAX);
+ CHECK (long_long, LLONG_MIN);
+ CHECK (ulong_long, ULLONG_MAX);
+#endif
}
+#endif
void
scm_init_numbers ()
{
+ abs_most_negative_fixnum = scm_i_long2big (- SCM_MOST_NEGATIVE_FIXNUM);
+ scm_permanent_object (abs_most_negative_fixnum);
+
+ /* It may be possible to tune the performance of some algorithms by using
+ * the following constants to avoid the creation of bignums. Please, before
+ * using these values, remember the two rules of program optimization:
+ * 1st Rule: Don't do it. 2nd Rule (experts only): Don't do it yet. */
+ scm_c_define ("most-positive-fixnum",
+ SCM_MAKINUM (SCM_MOST_POSITIVE_FIXNUM));
+ scm_c_define ("most-negative-fixnum",
+ SCM_MAKINUM (SCM_MOST_NEGATIVE_FIXNUM));
+
scm_add_feature ("complex");
scm_add_feature ("inexact");
scm_flo0 = scm_make_real (0.0);
scm_dblprec = scm_dblprec - 1;
}
#endif /* DBL_DIG */
+
+#ifdef GUILE_DEBUG
+ check_sanity ();
+#endif
+
#ifndef SCM_MAGIC_SNARFER
#include "libguile/numbers.x"
#endif
}
+#if (SCM_DEBUG_DEPRECATED == 0)
+
+SCM
+scm_mkbig (size_t len, int sign)
+{
+ scm_c_issue_deprecation_warning ("`scm_mkbig' is deprecated. "
+ "Use `scm_i_mkbig' instead.");
+ return scm_i_mkbig (len, sign);
+}
+
+SCM
+scm_big2inum (SCM b, size_t l)
+{
+ scm_c_issue_deprecation_warning ("`scm_big2inum' is deprecated. "
+ "Use `scm_i_big2num' instead.");
+ return scm_i_big2inum (b, l);
+}
+
+SCM
+scm_adjbig (SCM b, size_t nlen)
+{
+ scm_c_issue_deprecation_warning ("`scm_adjbig' is deprecated. "
+ "Use `scm_i_adjbig' instead.");
+ return scm_i_adjbig (b, nlen);
+}
+
+SCM
+scm_normbig (SCM b)
+{
+ scm_c_issue_deprecation_warning ("`scm_normbig' is deprecated. "
+ "Use `scm_i_normbig' instead.");
+ return scm_i_normbig (b);
+}
+
+SCM
+scm_copybig (SCM b, int sign)
+{
+ scm_c_issue_deprecation_warning ("`scm_copybig' is deprecated. "
+ "Use `scm_i_copybig' instead.");
+ return scm_i_copybig (b, sign);
+}
+
+SCM
+scm_2ulong2big (unsigned long *np)
+{
+ unsigned long n;
+ size_t i;
+ SCM_BIGDIG *digits;
+ SCM ans;
+
+ ans = scm_i_mkbig (2 * SCM_DIGSPERLONG, 0);
+ digits = SCM_BDIGITS (ans);
+
+ n = np[0];
+ for (i = 0; i < SCM_DIGSPERLONG; ++i)
+ {
+ digits[i] = SCM_BIGLO (n);
+ n = SCM_BIGDN ((unsigned long) n);
+ }
+ n = np[1];
+ for (i = 0; i < SCM_DIGSPERLONG; ++i)
+ {
+ digits[i + SCM_DIGSPERLONG] = SCM_BIGLO (n);
+ n = SCM_BIGDN ((unsigned long) n);
+ }
+ return ans;
+}
+
+SCM
+scm_dbl2big (double d)
+{
+ scm_c_issue_deprecation_warning ("`scm_dbl2big' is deprecated. "
+ "Use `scm_dbl2num' instead,"
+ "or `scm_i_dbl2big'.");
+ return scm_i_dbl2big (d);
+}
+
+double
+scm_big2dbl (SCM b)
+{
+ scm_c_issue_deprecation_warning ("`scm_big2dbl' is deprecated. "
+ "Use `scm_num2dbl' instead,"
+ "or `scm_i_big2dbl'.");
+ return scm_i_big2dbl (b);
+}
+
+#endif
+
/*
Local Variables:
c-file-style: "gnu"