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authorBryan Newbold <bnewbold@robocracy.org>2017-02-20 00:05:23 -0800
committerBryan Newbold <bnewbold@robocracy.org>2017-02-20 00:05:23 -0800
commit5ca6e8e6a4e5c022a6fb5d28f30219c22c99eda8 (patch)
tree9b744b9dbf39e716e56daa620e2f3041968caf19 /scl.c
downloadscm-5ca6e8e6a4e5c022a6fb5d28f30219c22c99eda8.tar.gz
scm-5ca6e8e6a4e5c022a6fb5d28f30219c22c99eda8.zip
Import Upstream version 4e6upstream/4e6
Diffstat (limited to 'scl.c')
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diff --git a/scl.c b/scl.c
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+/* Copyright (C) 1990, 1991, 1992, 1993, 1994, 1995 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
+ * the Free Software Foundation; either version 2, or (at your option)
+ * any later version.
+ *
+ * This program is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
+ * GNU General Public License for more details.
+ *
+ * You should have received a copy of the GNU General Public License
+ * along with this software; see the file COPYING. If not, write to
+ * the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.
+ *
+ * As a special exception, the Free Software Foundation gives permission
+ * for additional uses of the text contained in its release of GUILE.
+ *
+ * The exception is that, if you link the GUILE library with other files
+ * to produce an executable, this does not by itself cause the
+ * resulting executable to be covered by the GNU General Public License.
+ * Your use of that executable is in no way restricted on account of
+ * linking the GUILE library code into it.
+ *
+ * This exception does not however invalidate any other reasons why
+ * the executable file might be covered by the GNU General Public License.
+ *
+ * This exception applies only to the code released by the
+ * Free Software Foundation under the name GUILE. If you copy
+ * code from other Free Software Foundation releases into a copy of
+ * GUILE, as the General Public License permits, the exception does
+ * not apply to the code that you add in this way. To avoid misleading
+ * anyone as to the status of such modified files, you must delete
+ * this exception notice from them.
+ *
+ * If you write modifications of your own for GUILE, it is your choice
+ * whether to permit this exception to apply to your modifications.
+ * If you do not wish that, delete this exception notice.
+ */
+
+/* "scl.c" non-IEEE utility functions and non-integer arithmetic.
+ Authors: Jerry D. Hedden and Aubrey Jaffer */
+
+#include "scm.h"
+
+#ifdef FLOATS
+# include <math.h>
+
+static char s_makrect[] = "make-rectangular", s_makpolar[] = "make-polar",
+ s_magnitude[] = "magnitude", s_angle[] = "angle",
+ s_real_part[] = "real-part", s_imag_part[] = "imag-part",
+ s_in2ex[] = "inexact->exact";
+static char s_expt[] = "$expt", s_atan2[] = "$atan2";
+static char s_memv[] = "memv", s_assv[] = "assv";
+#endif
+
+SCM sys_protects[NUM_PROTECTS];
+sizet num_protects = NUM_PROTECTS;
+
+char s_inexactp[] = "inexact?";
+static char s_zerop[] = "zero?",
+ s_positivep[] = "positive?", s_negativep[] = "negative?";
+static char s_eqp[] = "=", s_lessp[] = "<", s_grp[] = ">";
+static char s_leqp[] = "<=", s_greqp[] = ">=";
+static char s_max[] = "max", s_min[] = "min";
+char s_sum[] = "+", s_difference[] = "-", s_product[] = "*",
+ s_divide[] = "/";
+static char s_number2string[] = "number->string",
+ s_str2number[] = "string->number";
+
+static char s_list_tail[] = "list-tail";
+static char s_str2list[] = "string->list";
+static char s_st_copy[] = "string-copy", s_st_fill[] = "string-fill!";
+static char s_vect2list[] = "vector->list", s_ve_fill[] = "vector-fill!";
+
+/*** NUMBERS -> STRINGS ***/
+#ifdef FLOATS
+int dblprec;
+static double fx[] = {0.0, 5e-1, 5e-2, 5e-3, 5e-4, 5e-5,
+ 5e-6, 5e-7, 5e-8, 5e-9, 5e-10,
+ 5e-11,5e-12,5e-13,5e-14,5e-15,
+ 5e-16,5e-17,5e-18,5e-19,5e-20};
+
+static sizet idbl2str(f, a)
+ double f;
+char *a;
+{
+ int efmt, dpt, d, i, wp = dblprec;
+ sizet ch = 0;
+ int exp = 0;
+
+ if (f==0.0) goto zero; /*{a[0]='0'; a[1]='.'; a[2]='0'; return 3;}*/
+ if (f < 0.0) {f = -f;a[ch++]='-';}
+ else if (f > 0.0) ;
+ else goto funny;
+ if IS_INF(f) {
+ if (ch==0) a[ch++]='+';
+ funny: a[ch++]='#'; a[ch++]='.'; a[ch++]='#'; return ch;
+ }
+# ifdef DBL_MIN_10_EXP /* Prevent unnormalized values, as from
+ make-uniform-vector, from causing infinite loops. */
+ while (f < 1.0) {f *= 10.0; if (exp-- < DBL_MIN_10_EXP) goto funny;}
+ while (f > 10.0) {f *= 0.10; if (exp++ > DBL_MAX_10_EXP) goto funny;}
+# else
+ while (f < 1.0) {f *= 10.0; exp--;}
+ while (f > 10.0) {f /= 10.0; exp++;}
+# endif
+ if (f+fx[wp] >= 10.0) {f = 1.0; exp++;}
+ zero:
+# ifdef ENGNOT
+ dpt = (exp+9999)%3;
+ exp -= dpt++;
+ efmt = 1;
+# else
+ efmt = (exp < -3) || (exp > wp+2);
+ if (!efmt)
+ if (exp < 0) {
+ a[ch++] = '0';
+ a[ch++] = '.';
+ dpt = exp;
+ while (++dpt) a[ch++] = '0';
+ } else
+ dpt = exp+1;
+ else
+ dpt = 1;
+# endif
+
+ do {
+ d = f;
+ f -= d;
+ a[ch++] = d+'0';
+ if (f < fx[wp]) break;
+ if (f+fx[wp] >= 1.0) {
+ a[ch-1]++;
+ break;
+ }
+ f *= 10.0;
+ if (!(--dpt)) a[ch++] = '.';
+ } while (wp--);
+
+ if (dpt > 0)
+# ifndef ENGNOT
+ if ((dpt > 4) && (exp > 6)) {
+ d = (a[0]=='-'?2:1);
+ for (i = ch++; i > d; i--)
+ a[i] = a[i-1];
+ a[d] = '.';
+ efmt = 1;
+ } else
+# endif
+ {
+ while (--dpt) a[ch++] = '0';
+ a[ch++] = '.';
+ }
+ if (a[ch-1]=='.') a[ch++]='0'; /* trailing zero */
+ if (efmt && exp) {
+ a[ch++] = 'e';
+ if (exp < 0) {
+ exp = -exp;
+ a[ch++] = '-';
+ }
+ for (i = 10; i <= exp; i *= 10);
+ for (i /= 10; i; i /= 10) {
+ a[ch++] = exp/i + '0';
+ exp %= i;
+ }
+ }
+ return ch;
+}
+
+static sizet iflo2str(flt, str)
+ SCM flt;
+ char *str;
+{
+ sizet i;
+# ifdef SINGLES
+ if SINGP(flt) i = idbl2str(FLO(flt), str);
+ else
+# endif
+ i = idbl2str(REAL(flt), str);
+ if CPLXP(flt) {
+ if(0 <= IMAG(flt)) /* jeh */
+ str[i++] = '+'; /* jeh */
+ i += idbl2str(IMAG(flt), &str[i]);
+ str[i++] = 'i';
+ }
+ return i;
+}
+#endif /* FLOATS */
+
+sizet iint2str(num, rad, p)
+ long num;
+ int rad;
+ char *p;
+{
+ sizet j;
+ register int i = 1, d;
+ register long n = num;
+ if (n < 0) {n = -n; i++;}
+ for (n /= rad;n > 0;n /= rad) i++;
+ j = i;
+ n = num;
+ if (n < 0) {n = -n; *p++ = '-'; i--;}
+ while (i--) {
+ d = n % rad;
+ n /= rad;
+ p[i] = d + ((d < 10) ? '0' : 'a' - 10);
+ }
+ return j;
+}
+#ifdef BIGDIG
+static SCM big2str(b, radix)
+ SCM b;
+ register unsigned int radix;
+{
+ SCM t = copybig(b, 0); /* sign of temp doesn't matter */
+ register BIGDIG *ds = BDIGITS(t);
+ sizet i = NUMDIGS(t);
+ sizet j = radix==16 ? (BITSPERDIG*i)/4+2
+ : radix >= 10 ? (BITSPERDIG*i*241L)/800+2
+ : (BITSPERDIG*i)+2;
+ sizet k = 0;
+ sizet radct = 0;
+ sizet ch; /* jeh */
+ BIGDIG radpow = 1, radmod = 0;
+ SCM ss = makstr((long)j);
+ char *s = CHARS(ss), c;
+ while ((long) radpow * radix < BIGRAD) {
+ radpow *= radix;
+ radct++;
+ }
+ s[0] = tc16_bigneg==TYP16(b) ? '-' : '+';
+ while ((i || radmod) && j) {
+ if (k==0) {
+ radmod = (BIGDIG)divbigdig(ds, i, radpow);
+ k = radct;
+ if (!ds[i-1]) i--;
+ }
+ c = radmod % radix; radmod /= radix; k--;
+ s[--j] = c < 10 ? c + '0' : c + 'a' - 10;
+ }
+ ch = s[0]=='-' ? 1 : 0; /* jeh */
+ if (ch < j) { /* jeh */
+ for(i = j;j < LENGTH(ss);j++) s[ch+j-i] = s[j]; /* jeh */
+ resizuve(ss, (SCM)MAKINUM(ch+LENGTH(ss)-i)); /* jeh */
+ }
+ return ss;
+}
+#endif
+SCM number2string(x, radix)
+ SCM x, radix;
+{
+ if UNBNDP(radix) radix=MAKINUM(10L);
+ else ASSERT(INUMP(radix), radix, ARG2, s_number2string);
+#ifdef FLOATS
+ if NINUMP(x) {
+ char num_buf[FLOBUFLEN];
+# ifdef BIGDIG
+ ASRTGO(NIMP(x), badx);
+ if BIGP(x) return big2str(x, (unsigned int)INUM(radix));
+# ifndef RECKLESS
+ if (!(INEXP(x)))
+ badx: wta(x, (char *)ARG1, s_number2string);
+# endif
+# else
+ ASSERT(NIMP(x) && INEXP(x), x, ARG1, s_number2string);
+# endif
+ return makfromstr(num_buf, iflo2str(x, num_buf));
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ ASSERT(NIMP(x) && BIGP(x), x, ARG1, s_number2string);
+ return big2str(x, (unsigned int)INUM(radix));
+ }
+# else
+ ASSERT(INUMP(x), x, ARG1, s_number2string);
+# endif
+#endif
+ {
+ char num_buf[INTBUFLEN];
+ return makfromstr(num_buf, iint2str(INUM(x), (int)INUM(radix), num_buf));
+ }
+}
+/* These print routines are stubbed here so that repl.c doesn't need
+ FLOATS or BIGDIGs conditionals */
+int floprint(sexp, port, writing)
+ SCM sexp;
+ SCM port;
+ int writing;
+{
+#ifdef FLOATS
+ char num_buf[FLOBUFLEN];
+ lfwrite(num_buf, (sizet)sizeof(char), iflo2str(sexp, num_buf), port);
+#else
+ ipruk("float", sexp, port);
+#endif
+ return !0;
+}
+int bigprint(exp, port, writing)
+ SCM exp;
+ SCM port;
+ int writing;
+{
+#ifdef BIGDIG
+ exp = big2str(exp, (unsigned int)10);
+ lfwrite(CHARS(exp), (sizet)sizeof(char), (sizet)LENGTH(exp), port);
+#else
+ ipruk("bignum", exp, port);
+#endif
+ return !0;
+}
+/*** END nums->strs ***/
+
+/*** STRINGS -> NUMBERS ***/
+#ifdef BIGDIG
+SCM istr2int(str, len, radix)
+ char *str;
+ long len;
+ register long radix;
+{
+ sizet j;
+ register sizet k, blen = 1;
+ sizet i = 0;
+ int c;
+ SCM res;
+ register BIGDIG *ds;
+ register unsigned long t2;
+
+ if (0 >= len) return BOOL_F; /* zero length */
+ if (10==radix) j = 1+(84*len)/(BITSPERDIG*25);
+ else j = (8 < radix) ? 1+(4*len)/BITSPERDIG : 1+(3*len)/BITSPERDIG;
+ switch (str[0]) { /* leading sign */
+ case '-':
+ case '+': if (++i==len) return BOOL_F; /* bad if lone `+' or `-' */
+ }
+ res = mkbig(j, '-'==str[0]);
+ ds = BDIGITS(res);
+ for (k = j;k--;) ds[k] = 0;
+ do {
+ switch (c = str[i++]) {
+ case DIGITS:
+ c = c - '0';
+ goto accumulate;
+ case 'A': case 'B': case 'C': case 'D': case 'E': case 'F':
+ c = c-'A'+10;
+ goto accumulate;
+ case 'a': case 'b': case 'c': case 'd': case 'e': case 'f':
+ c = c-'a'+10;
+ accumulate:
+ if (c >= radix) return BOOL_F; /* bad digit for radix */
+ k = 0;
+ t2 = c;
+ moretodo:
+ while(k < blen) {
+/* printf("k = %d, blen = %d, t2 = %ld, ds[k] = %d\n", k, blen, t2, ds[k]);*/
+ t2 += ds[k]*radix;
+ ds[k++] = BIGLO(t2);
+ t2 = BIGDN(t2);
+ }
+ ASSERT(blen <= j, (SCM)MAKINUM(blen), OVFLOW, "bignum");
+ if (t2) {blen++; goto moretodo;}
+ break;
+ default:
+ return BOOL_F; /* not a digit */
+ }
+ } while (i < len);
+ if (blen * BITSPERDIG/CHAR_BIT <= sizeof(SCM))
+ if INUMP(res = big2inum(res, blen)) return res;
+ if (j==blen) return res;
+ return adjbig(res, blen);
+}
+#else
+SCM istr2int(str, len, radix)
+ register char *str;
+ long len;
+ register long radix;
+{
+ register long n = 0, ln;
+ register int c;
+ register int i = 0;
+ int lead_neg = 0;
+ if (0 >= len) return BOOL_F; /* zero length */
+ switch (*str) { /* leading sign */
+ case '-': lead_neg = 1;
+ case '+': if (++i==len) return BOOL_F; /* bad if lone `+' or `-' */
+ }
+
+ do {
+ switch (c = str[i++]) {
+ case DIGITS:
+ c = c - '0';
+ goto accumulate;
+ case 'A': case 'B': case 'C': case 'D': case 'E': case 'F':
+ c = c-'A'+10;
+ goto accumulate;
+ case 'a': case 'b': case 'c': case 'd': case 'e': case 'f':
+ c = c-'a'+10;
+ accumulate:
+ if (c >= radix) return BOOL_F; /* bad digit for radix */
+ ln = n;
+ n = n * radix - c;
+ /* Negation is a workaround for HP700 cc bug */
+ if (n > ln || (-n > -MOST_NEGATIVE_FIXNUM)) goto ovfl;
+ break;
+ default:
+ return BOOL_F; /* not a digit */
+ }
+ } while (i < len);
+ if (!lead_neg) if ((n = -n) > MOST_POSITIVE_FIXNUM) goto ovfl;
+ return MAKINUM(n);
+ ovfl: /* overflow scheme integer */
+ return BOOL_F;
+}
+#endif
+
+#ifdef FLOATS
+SCM istr2flo(str, len, radix)
+ register char *str;
+ register long len;
+ register long radix;
+{
+ register int c, i = 0;
+ double lead_sgn;
+ double res = 0.0, tmp = 0.0;
+ int flg = 0;
+ int point = 0;
+ SCM second;
+
+ if (i >= len) return BOOL_F; /* zero length */
+
+ switch (*str) { /* leading sign */
+ case '-': lead_sgn = -1.0; i++; break;
+ case '+': lead_sgn = 1.0; i++; break;
+ default : lead_sgn = 0.0;
+ }
+ if (i==len) return BOOL_F; /* bad if lone `+' or `-' */
+
+ if (str[i]=='i' || str[i]=='I') { /* handle `+i' and `-i' */
+ if (lead_sgn==0.0) return BOOL_F; /* must have leading sign */
+ if (++i < len) return BOOL_F; /* `i' not last character */
+ return makdbl(0.0, lead_sgn);
+ }
+ do { /* check initial digits */
+ switch (c = str[i]) {
+ case DIGITS:
+ c = c - '0';
+ goto accum1;
+ case 'D': case 'E': case 'F':
+ if (radix==10) goto out1; /* must be exponent */
+ case 'A': case 'B': case 'C':
+ c = c-'A'+10;
+ goto accum1;
+ case 'd': case 'e': case 'f':
+ if (radix==10) goto out1;
+ case 'a': case 'b': case 'c':
+ c = c-'a'+10;
+ accum1:
+ if (c >= radix) return BOOL_F; /* bad digit for radix */
+ res = res * radix + c;
+ flg = 1; /* res is valid */
+ break;
+ default:
+ goto out1;
+ }
+ } while (++i < len);
+ out1:
+
+ /* if true, then we did see a digit above, and res is valid */
+ if (i==len) goto done;
+
+ /* By here, must have seen a digit,
+ or must have next char be a `.' with radix==10 */
+ if (!flg)
+ if (!(str[i]=='.' && radix==10))
+ return BOOL_F;
+
+ while (str[i]=='#') { /* optional sharps */
+ res *= radix;
+ if (++i==len) goto done;
+ }
+
+ if (str[i]=='/') {
+ while (++i < len) {
+ switch (c = str[i]) {
+ case DIGITS:
+ c = c - '0';
+ goto accum2;
+ case 'A': case 'B': case 'C': case 'D': case 'E': case 'F':
+ c = c-'A'+10;
+ goto accum2;
+ case 'a': case 'b': case 'c': case 'd': case 'e': case 'f':
+ c = c-'a'+10;
+ accum2:
+ if (c >= radix) return BOOL_F;
+ tmp = tmp * radix + c;
+ break;
+ default:
+ goto out2;
+ }
+ }
+ out2:
+ if (tmp==0.0) return BOOL_F; /* `slash zero' not allowed */
+ if (i < len)
+ while (str[i]=='#') { /* optional sharps */
+ tmp *= radix;
+ if (++i==len) break;
+ }
+ res /= tmp;
+ goto done;
+ }
+
+ if (str[i]=='.') { /* decimal point notation */
+ if (radix != 10) return BOOL_F; /* must be radix 10 */
+ while (++i < len) {
+ switch (c = str[i]) {
+ case DIGITS:
+ point--;
+ res = res*10.0 + c-'0';
+ flg = 1;
+ break;
+ default:
+ goto out3;
+ }
+ }
+ out3:
+ if (!flg) return BOOL_F; /* no digits before or after decimal point */
+ if (i==len) goto adjust;
+ while (str[i]=='#') { /* ignore remaining sharps */
+ if (++i==len) goto adjust;
+ }
+ }
+
+ switch (str[i]) { /* exponent */
+ case 'd': case 'D':
+ case 'e': case 'E':
+ case 'f': case 'F':
+ case 'l': case 'L':
+ case 's': case 'S': {
+ int expsgn = 1, expon = 0;
+ if (radix != 10) return BOOL_F; /* only in radix 10 */
+ if (++i==len) return BOOL_F; /* bad exponent */
+ switch (str[i]) {
+ case '-': expsgn=(-1);
+ case '+': if (++i==len) return BOOL_F; /* bad exponent */
+ }
+ if (str[i] < '0' || str[i] > '9') return BOOL_F; /* bad exponent */
+ do {
+ switch (c = str[i]) {
+ case DIGITS:
+ expon = expon*10 + c-'0';
+ if (expon > MAXEXP) return BOOL_F; /* exponent too large */
+ break;
+ default:
+ goto out4;
+ }
+ } while (++i < len);
+ out4:
+ point += expsgn*expon;
+ }
+ }
+
+ adjust:
+ if (point >= 0)
+ while (point--) res *= 10.0;
+ else
+# ifdef _UNICOS
+ while (point++) res *= 0.1;
+# else
+ while (point++) res /= 10.0;
+# endif
+
+ done:
+ /* at this point, we have a legitimate floating point result */
+ if (lead_sgn==-1.0) res = -res;
+ if (i==len) return makdbl(res, 0.0);
+
+ if (str[i]=='i' || str[i]=='I') { /* pure imaginary number */
+ if (lead_sgn==0.0) return BOOL_F; /* must have leading sign */
+ if (++i < len) return BOOL_F; /* `i' not last character */
+ return makdbl(0.0, res);
+ }
+
+ switch (str[i++]) {
+ case '-': lead_sgn = -1.0; break;
+ case '+': lead_sgn = 1.0; break;
+ case '@': { /* polar input for complex number */
+ /* get a `real' for angle */
+ second = istr2flo(&str[i], (long)(len-i), radix);
+ if (!(INEXP(second))) return BOOL_F; /* not `real' */
+ if (CPLXP(second)) return BOOL_F; /* not `real' */
+ tmp = REALPART(second);
+ return makdbl(res*cos(tmp), res*sin(tmp));
+ }
+ default: return BOOL_F;
+ }
+
+ /* at this point, last char must be `i' */
+ if (str[len-1] != 'i' && str[len-1] != 'I') return BOOL_F;
+ /* handles `x+i' and `x-i' */
+ if (i==(len-1)) return makdbl(res, lead_sgn);
+ /* get a `ureal' for complex part */
+ second = istr2flo(&str[i], (long)((len-i)-1), radix);
+ if (!(INEXP(second))) return BOOL_F; /* not `ureal' */
+ if (CPLXP(second)) return BOOL_F; /* not `ureal' */
+ tmp = REALPART(second);
+ if (tmp < 0.0) return BOOL_F; /* not `ureal' */
+ return makdbl(res, (lead_sgn*tmp));
+}
+#endif /* FLOATS */
+
+
+SCM istring2number(str, len, radix)
+ char *str;
+ long len;
+ long radix;
+{
+ int i = 0;
+ char ex = 0;
+ char ex_p = 0, rx_p = 0; /* Only allow 1 exactness and 1 radix prefix */
+ SCM res;
+ if (len==1)
+ if (*str=='+' || *str=='-') /* Catches lone `+' and `-' for speed */
+ return BOOL_F;
+
+ while ((len-i) >= 2 && str[i]=='#' && ++i)
+ switch (str[i++]) {
+ case 'b': case 'B': if (rx_p++) return BOOL_F; radix = 2; break;
+ case 'o': case 'O': if (rx_p++) return BOOL_F; radix = 8; break;
+ case 'd': case 'D': if (rx_p++) return BOOL_F; radix = 10; break;
+ case 'x': case 'X': if (rx_p++) return BOOL_F; radix = 16; break;
+ case 'i': case 'I': if (ex_p++) return BOOL_F; ex = 2; break;
+ case 'e': case 'E': if (ex_p++) return BOOL_F; ex = 1; break;
+ default: return BOOL_F;
+ }
+
+ switch (ex) {
+ case 1:
+ return istr2int(&str[i], len-i, radix);
+ case 0:
+ res = istr2int(&str[i], len-i, radix);
+ if NFALSEP(res) return res;
+#ifdef FLOATS
+ case 2: return istr2flo(&str[i], len-i, radix);
+#endif
+ }
+ return BOOL_F;
+}
+
+
+SCM string2number(str, radix)
+ SCM str, radix;
+{
+ if UNBNDP(radix) radix=MAKINUM(10L);
+ else ASSERT(INUMP(radix), radix, ARG2, s_str2number);
+ ASSERT(NIMP(str) && STRINGP(str), str, ARG1, s_str2number);
+ return istring2number(CHARS(str), LENGTH(str), INUM(radix));
+}
+/*** END strs->nums ***/
+
+#ifdef FLOATS
+SCM makdbl (x, y)
+ double x, y;
+{
+ SCM z;
+ if ((y==0.0) && (x==0.0)) return flo0;
+ NEWCELL(z);
+ DEFER_INTS;
+ if (y==0.0) {
+# ifdef SINGLES
+ float fx;
+# ifndef SINGLESONLY
+ if ((-FLTMAX < x) && (x < FLTMAX) && ((fx=x)==x))
+# endif
+ {
+ CAR(z) = tc_flo;
+ FLO(z) = x;
+ ALLOW_INTS;
+ return z;
+ }
+# endif /* def SINGLES */
+ CDR(z) = (SCM)must_malloc(1L*sizeof(double), "real");
+ CAR(z) = tc_dblr;
+ }
+ else {
+ CDR(z) = (SCM)must_malloc(2L*sizeof(double), "complex");
+ CAR(z) = tc_dblc;
+ IMAG(z) = y;
+ }
+ REAL(z) = x;
+ ALLOW_INTS;
+ return z;
+}
+
+SCM eqv(x, y)
+ SCM x, y;
+{
+ if (x==y) return BOOL_T;
+ if IMP(x) return BOOL_F;
+ if IMP(y) return BOOL_F;
+ /* this ensures that types and length are the same. */
+ if (CAR(x) != CAR(y)) return BOOL_F;
+ if NUMP(x) {
+# ifdef BIGDIG
+ if BIGP(x) return (0==bigcomp(x, y)) ? BOOL_T : BOOL_F;
+# endif
+ if (REALPART(x) != REALPART(y)) return BOOL_F;
+ if (CPLXP(x) && (IMAG(x) != IMAG(y))) return BOOL_F;
+ return BOOL_T;
+ }
+ return BOOL_F;
+}
+SCM memv(x, lst) /* m.borza 12.2.91 */
+SCM x, lst;
+{
+ for(;NIMP(lst);lst = CDR(lst)) {
+ ASRTGO(CONSP(lst), badlst);
+ if NFALSEP(eqv(CAR(lst), x)) return lst;
+ }
+# ifndef RECKLESS
+ if (!(NULLP(lst)))
+ badlst: wta(lst, (char *)ARG2, s_memv);
+# endif
+ return BOOL_F;
+}
+SCM assv(x, alist) /* m.borza 12.2.91 */
+SCM x, alist;
+{
+ SCM tmp;
+ for(;NIMP(alist);alist = CDR(alist)) {
+ ASRTGO(CONSP(alist), badlst);
+ tmp = CAR(alist);
+ ASRTGO(NIMP(tmp) && CONSP(tmp), badlst);
+ if NFALSEP(eqv(CAR(tmp), x)) return tmp;
+ }
+# ifndef RECKLESS
+ if (!(NULLP(alist)))
+ badlst: wta(alist, (char *)ARG2, s_assv);
+# endif
+ return BOOL_F;
+}
+#endif /* FLOATS */
+
+SCM list_tail(lst, k)
+ SCM lst, k;
+{
+ register long i;
+ ASSERT(INUMP(k), k, ARG2, s_list_tail);
+ i = INUM(k);
+ while (i-- > 0) {
+ ASSERT(NIMP(lst) && CONSP(lst), lst, ARG1, s_list_tail);
+ lst = CDR(lst);
+ }
+ return lst;
+}
+
+SCM string2list(str)
+ SCM str;
+{
+ long i;
+ SCM res = EOL;
+ unsigned char *src;
+ ASSERT(NIMP(str) && STRINGP(str), str, ARG1, s_str2list);
+ src = UCHARS(str);
+ for(i = LENGTH(str)-1;i >= 0;i--) res = cons((SCM)MAKICHR(src[i]), res);
+ return res;
+}
+SCM string_copy(str)
+ SCM str;
+{
+ ASSERT(NIMP(str) && STRINGP(str), str, ARG1, s_st_copy);
+ return makfromstr(CHARS(str), (sizet)LENGTH(str));
+}
+SCM string_fill(str, chr)
+ SCM str, chr;
+{
+ register char *dst, c;
+ register long k;
+ ASSERT(NIMP(str) && STRINGP(str), str, ARG1, s_st_fill);
+ ASSERT(ICHRP(chr), chr, ARG2, s_st_fill);
+ c = ICHR(chr);
+ dst = CHARS(str);
+ for(k = LENGTH(str)-1;k >= 0;k--) dst[k] = c;
+ return UNSPECIFIED;
+}
+SCM vector2list(v)
+ SCM v;
+{
+ SCM res = EOL;
+ long i;
+ SCM *data;
+ ASSERT(NIMP(v) && VECTORP(v), v, ARG1, s_vect2list);
+ data = VELTS(v);
+ for(i = LENGTH(v)-1;i >= 0;i--) res = cons(data[i], res);
+ return res;
+}
+SCM vector_fill(v, fill)
+ SCM v, fill;
+{
+ register long i;
+ register SCM *data;
+ ASSERT(NIMP(v) && VECTORP(v), v, ARG1, s_ve_fill);
+ data = VELTS(v);
+ for(i = LENGTH(v)-1;i >= 0;i--) data[i] = fill;
+ return UNSPECIFIED;
+}
+static SCM vector_equal(x, y)
+ SCM x, y;
+{
+ long i;
+ for(i = LENGTH(x)-1;i >= 0;i--)
+ if FALSEP(equal(VELTS(x)[i], VELTS(y)[i])) return BOOL_F;
+ return BOOL_T;
+}
+SCM bigequal(x, y)
+ SCM x, y;
+{
+#ifdef BIGDIG
+ if (0==bigcomp(x, y)) return BOOL_T;
+#endif
+ return BOOL_F;
+}
+SCM floequal(x, y)
+ SCM x, y;
+{
+#ifdef FLOATS
+ if (REALPART(x) != REALPART(y)) return BOOL_F;
+ if (!(CPLXP(x) && (IMAG(x) != IMAG(y)))) return BOOL_T;
+#endif
+ return BOOL_F;
+}
+SCM equal(x, y)
+ SCM x, y;
+{
+ CHECK_STACK;
+ tailrecurse: POLL;
+ if (x==y) return BOOL_T;
+ if IMP(x) return BOOL_F;
+ if IMP(y) return BOOL_F;
+ if (CONSP(x) && CONSP(y)) {
+ if FALSEP(equal(CAR(x), CAR(y))) return BOOL_F;
+ x = CDR(x);
+ y = CDR(y);
+ goto tailrecurse;
+ }
+ /* this ensures that types and length are the same. */
+ if (CAR(x) != CAR(y)) return BOOL_F;
+ switch (TYP7(x)) {
+ default: return BOOL_F;
+ case tc7_string: return st_equal(x, y);
+ case tc7_vector: return vector_equal(x, y);
+ case tc7_smob: {
+ int i = SMOBNUM(x);
+ if (!(i < numsmob)) return BOOL_F;
+ if (smobs[i].equalp) return (smobs[i].equalp)(x, y);
+ else return BOOL_F;
+ }
+ case tc7_bvect: case tc7_uvect: case tc7_ivect:
+ case tc7_fvect: case tc7_cvect: case tc7_dvect: {
+ SCM (*pred)() = smobs[0x0ff & (tc16_array>>8)].equalp;
+ if (pred) return (*pred)(x, y);
+ else return BOOL_F;
+ }
+ }
+ return BOOL_F;
+}
+
+SCM numberp(x)
+ SCM x;
+{
+ if INUMP(x) return BOOL_T;
+#ifdef FLOATS
+ if (NIMP(x) && NUMP(x)) return BOOL_T;
+#else
+# ifdef BIGDIG
+ if (NIMP(x) && NUMP(x)) return BOOL_T;
+# endif
+#endif
+ return BOOL_F;
+}
+#ifdef FLOATS
+SCM realp(x)
+ SCM x;
+{
+ if INUMP(x) return BOOL_T;
+ if IMP(x) return BOOL_F;
+ if REALP(x) return BOOL_T;
+# ifdef BIGDIG
+ if BIGP(x) return BOOL_T;
+# endif
+ return BOOL_F;
+}
+SCM intp(x)
+ SCM x;
+{
+ double r;
+ if INUMP(x) return BOOL_T;
+ if IMP(x) return BOOL_F;
+# ifdef BIGDIG
+ if BIGP(x) return BOOL_T;
+# endif
+ if (!INEXP(x)) return BOOL_F;
+ if CPLXP(x) return BOOL_F;
+ r = REALPART(x);
+ if (r==floor(r)) return BOOL_T;
+ return BOOL_F;
+}
+#endif /* FLOATS */
+
+SCM inexactp(x)
+ SCM x;
+{
+#ifdef FLOATS
+ if (NIMP(x) && INEXP(x)) return BOOL_T;
+#endif
+ return BOOL_F;
+}
+SCM eqp(x, y)
+ SCM x, y;
+{
+#ifdef FLOATS
+ SCM t;
+ if NINUMP(x) {
+# ifdef BIGDIG
+# ifndef RECKLESS
+ if (!(NIMP(x)))
+ badx: wta(x, (char *)ARG1, s_eqp);
+# endif
+ if BIGP(x) {
+ if INUMP(y) return BOOL_F;
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return (0==bigcomp(x, y)) ? BOOL_T : BOOL_F;
+ ASRTGO(INEXP(y), bady);
+ bigreal:
+ return (REALP(y) && (big2dbl(x)==REALPART(y))) ? BOOL_T : BOOL_F;
+ }
+ ASRTGO(INEXP(x), badx);
+# else
+ ASSERT(NIMP(x) && INEXP(x), x, ARG1, s_eqp);
+# endif
+ if INUMP(y) {t = x; x = y; y = t; goto realint;}
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) {t = x; x = y; y = t; goto bigreal;}
+ ASRTGO(INEXP(y), bady);
+# else
+ ASRTGO(NIMP(y) && INEXP(y), bady);
+# endif
+ if (REALPART(x) != REALPART(y)) return BOOL_F;
+ if CPLXP(x)
+ return (CPLXP(y) && (IMAG(x)==IMAG(y))) ? BOOL_T : BOOL_F;
+ return CPLXP(y) ? BOOL_F : BOOL_T;
+ }
+ if NINUMP(y) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return BOOL_F;
+# ifndef RECKLESS
+ if (!(INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_eqp);
+# endif
+# else
+# ifndef RECKLESS
+ if (!(NIMP(y) && INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_eqp);
+# endif
+# endif
+ realint:
+ return (REALP(y) && (((double)INUM(x))==REALPART(y))) ? BOOL_T : BOOL_F;
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ ASSERT(NIMP(x) && BIGP(x), x, ARG1, s_eqp);
+ if INUMP(y) return BOOL_F;
+ ASRTGO(NIMP(y) && BIGP(y), bady);
+ return (0==bigcomp(x, y)) ? BOOL_T : BOOL_F;
+ }
+ if NINUMP(y) {
+# ifndef RECKLESS
+ if (!(NIMP(y) && BIGP(y)))
+ bady: wta(y, (char *)ARG2, s_eqp);
+# endif
+ return BOOL_F;
+ }
+# else
+ ASSERT(INUMP(x), x, ARG1, s_eqp);
+ ASSERT(INUMP(y), y, ARG2, s_eqp);
+# endif
+#endif
+ return ((long)x==(long)y) ? BOOL_T : BOOL_F;
+}
+SCM lessp(x, y)
+ SCM x, y;
+{
+#ifdef FLOATS
+ if NINUMP(x) {
+# ifdef BIGDIG
+# ifndef RECKLESS
+ if (!(NIMP(x)))
+ badx: wta(x, (char *)ARG1, s_lessp);
+# endif
+ if BIGP(x) {
+ if INUMP(y) return BIGSIGN(x) ? BOOL_T : BOOL_F;
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return (1==bigcomp(x, y)) ? BOOL_T : BOOL_F;
+ ASRTGO(REALP(y), bady);
+ return (big2dbl(x) < REALPART(y)) ? BOOL_T : BOOL_F;
+ }
+ ASRTGO(REALP(x), badx);
+# else
+ ASSERT(NIMP(x) && REALP(x), x, ARG1, s_lessp);
+# endif
+ if INUMP(y) return (REALPART(x) < ((double)INUM(y))) ? BOOL_T : BOOL_F;
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return (REALPART(x) < big2dbl(y)) ? BOOL_T : BOOL_F;
+ ASRTGO(REALP(y), bady);
+# else
+ ASRTGO(NIMP(y) && REALP(y), bady);
+# endif
+ return (REALPART(x) < REALPART(y)) ? BOOL_T : BOOL_F;
+ }
+ if NINUMP(y) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return BIGSIGN(y) ? BOOL_F : BOOL_T;
+# ifndef RECKLESS
+ if (!(REALP(y)))
+ bady: wta(y, (char *)ARG2, s_lessp);
+# endif
+# else
+# ifndef RECKLESS
+ if (!(NIMP(y) && REALP(y)))
+ bady: wta(y, (char *)ARG2, s_lessp);
+# endif
+# endif
+ return (((double)INUM(x)) < REALPART(y)) ? BOOL_T : BOOL_F;
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ ASSERT(NIMP(x) && BIGP(x), x, ARG1, s_lessp);
+ if INUMP(y) return BIGSIGN(x) ? BOOL_T : BOOL_F;
+ ASRTGO(NIMP(y) && BIGP(y), bady);
+ return (1==bigcomp(x, y)) ? BOOL_T : BOOL_F;
+ }
+ if NINUMP(y) {
+# ifndef RECKLESS
+ if (!(NIMP(y) && BIGP(y)))
+ bady: wta(y, (char *)ARG2, s_lessp);
+# endif
+ return BIGSIGN(y) ? BOOL_F : BOOL_T;
+ }
+# else
+ ASSERT(INUMP(x), x, ARG1, s_lessp);
+ ASSERT(INUMP(y), y, ARG2, s_lessp);
+# endif
+#endif
+ return ((long)x < (long)y) ? BOOL_T : BOOL_F;
+}
+SCM greaterp(x, y)
+ SCM x, y;
+{
+ return lessp(y, x);
+}
+SCM leqp(x, y)
+ SCM x, y;
+{
+ return BOOL_NOT(lessp(y, x));
+}
+SCM greqp(x, y)
+ SCM x, y;
+{
+ return BOOL_NOT(lessp(x, y));
+}
+SCM zerop(z)
+ SCM z;
+{
+#ifdef FLOATS
+ if NINUMP(z) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(z), badz);
+ if BIGP(z) return BOOL_F;
+# ifndef RECKLESS
+ if (!(INEXP(z)))
+ badz: wta(z, (char *)ARG1, s_zerop);
+# endif
+# else
+ ASSERT(NIMP(z) && INEXP(z), z, ARG1, s_zerop);
+# endif
+ return (z==flo0) ? BOOL_T : BOOL_F;
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(z) {
+ ASSERT(NIMP(z) && BIGP(z), z, ARG1, s_zerop);
+ return BOOL_F;
+ }
+# else
+ ASSERT(INUMP(z), z, ARG1, s_zerop);
+# endif
+#endif
+ return (z==INUM0) ? BOOL_T: BOOL_F;
+}
+SCM positivep(x)
+ SCM x;
+{
+#ifdef FLOATS
+ if NINUMP(x) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(x), badx);
+ if BIGP(x) return TYP16(x)==tc16_bigpos ? BOOL_T : BOOL_F;
+# ifndef RECKLESS
+ if (!(REALP(x)))
+ badx: wta(x, (char *)ARG1, s_positivep);
+# endif
+# else
+ ASSERT(NIMP(x) && REALP(x), x, ARG1, s_positivep);
+# endif
+ return (REALPART(x) > 0.0) ? BOOL_T : BOOL_F;
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ ASSERT(NIMP(x) && BIGP(x), x, ARG1, s_positivep);
+ return TYP16(x)==tc16_bigpos ? BOOL_T : BOOL_F;
+ }
+# else
+ ASSERT(INUMP(x), x, ARG1, s_positivep);
+# endif
+#endif
+ return (x > INUM0) ? BOOL_T : BOOL_F;
+}
+SCM negativep(x)
+ SCM x;
+{
+#ifdef FLOATS
+ if NINUMP(x) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(x), badx);
+ if BIGP(x) return TYP16(x)==tc16_bigpos ? BOOL_F : BOOL_T;
+# ifndef RECKLESS
+ if (!(REALP(x)))
+ badx: wta(x, (char *)ARG1, s_negativep);
+# endif
+# else
+ ASSERT(NIMP(x) && REALP(x), x, ARG1, s_negativep);
+# endif
+ return (REALPART(x) < 0.0) ? BOOL_T : BOOL_F;
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ ASSERT(NIMP(x) && BIGP(x), x, ARG1, s_negativep);
+ return (TYP16(x)==tc16_bigneg) ? BOOL_T : BOOL_F;
+ }
+# else
+ ASSERT(INUMP(x), x, ARG1, s_negativep);
+# endif
+#endif
+ return (x < INUM0) ? BOOL_T : BOOL_F;
+}
+
+SCM lmax(x, y)
+ SCM x, y;
+{
+#ifdef FLOATS
+ double z;
+#endif
+ if UNBNDP(y) {
+#ifndef RECKLESS
+ if (!(NUMBERP(x)))
+ badx: wta(x, (char *)ARG1, s_max);
+#endif
+ return x;
+ }
+#ifdef FLOATS
+ if NINUMP(x) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(x), badx);
+ if BIGP(x) {
+ if INUMP(y) return BIGSIGN(x) ? y : x;
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return (1==bigcomp(x, y)) ? y : x;
+ ASRTGO(REALP(y), bady);
+ z = big2dbl(x);
+ return (z < REALPART(y)) ? y : makdbl(z, 0.0);
+ }
+ ASRTGO(REALP(x), badx);
+# else
+ ASSERT(NIMP(x) && REALP(x), x, ARG1, s_max);
+# endif
+ if INUMP(y) return (REALPART(x) < (z = INUM(y))) ? makdbl(z, 0.0) : x;
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return (REALPART(x) < (z = big2dbl(y))) ? makdbl(z, 0.0) : x;
+ ASRTGO(REALP(y), bady);
+# else
+ ASRTGO(NIMP(y) && REALP(y), bady);
+# endif
+ return (REALPART(x) < REALPART(y)) ? y : x;
+ }
+ if NINUMP(y) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return BIGSIGN(y) ? x : y;
+# ifndef RECKLESS
+ if (!(REALP(y)))
+ bady: wta(y, (char *)ARG2, s_max);
+# endif
+# else
+# ifndef RECKLESS
+ if (!(NIMP(y) && REALP(y)))
+ bady: wta(y, (char *)ARG2, s_max);
+# endif
+# endif
+ return ((z = INUM(x)) < REALPART(y)) ? y : makdbl(z, 0.0);
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ ASSERT(NIMP(x) && BIGP(x), x, ARG1, s_max);
+ if INUMP(y) return BIGSIGN(x) ? y : x;
+ ASRTGO(NIMP(y) && BIGP(y), bady);
+ return (1==bigcomp(x, y)) ? y : x;
+ }
+ if NINUMP(y) {
+# ifndef RECKLESS
+ if (!(NIMP(y) && BIGP(y)))
+ bady: wta(y, (char *)ARG2, s_max);
+# endif
+ return BIGSIGN(y) ? x : y;
+ }
+# else
+ ASSERT(INUMP(x), x, ARG1, s_max);
+ ASSERT(INUMP(y), y, ARG2, s_max);
+# endif
+#endif
+ return ((long)x < (long)y) ? y : x;
+}
+
+SCM lmin(x, y)
+ SCM x, y;
+{
+#ifdef FLOATS
+ double z;
+#endif
+ if UNBNDP(y) {
+#ifndef RECKLESS
+ if (!(NUMBERP(x)))
+ badx: wta(x, (char *)ARG1, s_min);
+#endif
+ return x;
+ }
+#ifdef FLOATS
+ if NINUMP(x) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(x), badx);
+ if BIGP(x) {
+ if INUMP(y) return BIGSIGN(x) ? x : y;
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return (-1==bigcomp(x, y)) ? y : x;
+ ASRTGO(REALP(y), bady);
+ z = big2dbl(x);
+ return (z > REALPART(y)) ? y : makdbl(z, 0.0);
+ }
+ ASRTGO(REALP(x), badx);
+# else
+ ASSERT(NIMP(x) && REALP(x), x, ARG1, s_min);
+# endif
+ if INUMP(y) return (REALPART(x) > (z = INUM(y))) ? makdbl(z, 0.0) : x;
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return (REALPART(x) > (z = big2dbl(y))) ? makdbl(z, 0.0) : x;
+ ASRTGO(REALP(y), bady);
+# else
+ ASRTGO(NIMP(y) && REALP(y), bady);
+# endif
+ return (REALPART(x) > REALPART(y)) ? y : x;
+ }
+ if NINUMP(y) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return BIGSIGN(y) ? y : x;
+# ifndef RECKLESS
+ if (!(REALP(y)))
+ bady: wta(y, (char *)ARG2, s_min);
+# endif
+# else
+# ifndef RECKLESS
+ if (!(NIMP(y) && REALP(y)))
+ bady: wta(y, (char *)ARG2, s_min);
+# endif
+# endif
+ return ((z = INUM(x)) > REALPART(y)) ? y : makdbl(z, 0.0);
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ ASSERT(NIMP(x) && BIGP(x), x, ARG1, s_min);
+ if INUMP(y) return BIGSIGN(x) ? x : y;
+ ASRTGO(NIMP(y) && BIGP(y), bady);
+ return (-1==bigcomp(x, y)) ? y : x;
+ }
+ if NINUMP(y) {
+# ifndef RECKLESS
+ if (!(NIMP(y) && BIGP(y)))
+ bady: wta(y, (char *)ARG2, s_min);
+# endif
+ return BIGSIGN(y) ? y : x;
+ }
+# else
+ ASSERT(INUMP(x), x, ARG1, s_min);
+ ASSERT(INUMP(y), y, ARG2, s_min);
+# endif
+#endif
+ return ((long)x > (long)y) ? y : x;
+}
+
+SCM sum(x, y)
+ SCM x, y;
+{
+ if UNBNDP(y) {
+ if UNBNDP(x) return INUM0;
+#ifndef RECKLESS
+ if (!(NUMBERP(x)))
+ badx: wta(x, (char *)ARG1, s_sum);
+#endif
+ return x;
+ }
+#ifdef FLOATS
+ if NINUMP(x) {
+ SCM t;
+# ifdef BIGDIG
+ ASRTGO(NIMP(x), badx);
+ if BIGP(x) {
+ if INUMP(y) {t = x; x = y; y = t; goto intbig;}
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) {
+ if (NUMDIGS(x) > NUMDIGS(y)) {t = x; x = y; y = t;}
+ return addbig(BDIGITS(x), NUMDIGS(x), BIGSIGN(x), y, 0);
+ }
+ ASRTGO(INEXP(y), bady);
+ bigreal: return makdbl(big2dbl(x)+REALPART(y), CPLXP(y)?IMAG(y):0.0);
+ }
+ ASRTGO(INEXP(x), badx);
+# else
+ ASRTGO(NIMP(x) && INEXP(x), badx);
+# endif
+ if INUMP(y) {t = x; x = y; y = t; goto intreal;}
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) {t = x; x = y; y = t; goto bigreal;}
+# ifndef RECKLESS
+ else if (!(INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_sum);
+# endif
+# else
+# ifndef RECKLESS
+ if (!(NIMP(y) && INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_sum);
+# endif
+# endif
+ { double i = 0.0;
+ if CPLXP(x) i = IMAG(x);
+ if CPLXP(y) i += IMAG(y);
+ return makdbl(REALPART(x)+REALPART(y), i); }
+ }
+ if NINUMP(y) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y)
+ intbig: {
+# ifndef DIGSTOOBIG
+ long z = pseudolong(INUM(x));
+ return addbig((BIGDIG *)&z, DIGSPERLONG, (x < 0) ? 0x0100 : 0, y, 0);
+# else
+ BIGDIG zdigs[DIGSPERLONG];
+ longdigs(INUM(x), zdigs);
+ return addbig(zdigs, DIGSPERLONG, (x < 0) ? 0x0100 : 0, y, 0);
+# endif
+ }
+ ASRTGO(INEXP(y), bady);
+# else
+ ASRTGO(NIMP(y) && INEXP(y), bady);
+# endif
+ intreal: return makdbl(INUM(x)+REALPART(y), CPLXP(y)?IMAG(y):0.0);
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ SCM t;
+ ASRTGO(NIMP(x) && BIGP(x), badx);
+ if INUMP(y) {t = x; x = y; y = t; goto intbig;}
+ ASRTGO(NIMP(y) && BIGP(y), bady);
+ if (NUMDIGS(x) > NUMDIGS(y)) {t = x; x = y; y = t;}
+ return addbig(BDIGITS(x), NUMDIGS(x), BIGSIGN(x), y, 0);
+ }
+ if NINUMP(y) {
+# ifndef RECKLESS
+ if (!(NIMP(y) && BIGP(y)))
+ bady: wta(y, (char *)ARG2, s_sum);
+# endif
+ intbig: {
+# ifndef DIGSTOOBIG
+ long z = pseudolong(INUM(x));
+ return addbig(&z, DIGSPERLONG, (x < 0) ? 0x0100 : 0, y, 0);
+# else
+ BIGDIG zdigs[DIGSPERLONG];
+ longdigs(INUM(x), zdigs);
+ return addbig(zdigs, DIGSPERLONG, (x < 0) ? 0x0100 : 0, y, 0);
+# endif
+ }
+ }
+# else
+ ASRTGO(INUMP(x), badx);
+ ASSERT(INUMP(y), y, ARG2, s_sum);
+# endif
+#endif
+ x = INUM(x)+INUM(y);
+ if FIXABLE(x) return MAKINUM(x);
+#ifdef BIGDIG
+ return long2big(x);
+#else
+# ifdef FLOATS
+ return makdbl((double)x, 0.0);
+# else
+ wta(y, (char *)OVFLOW, s_sum);
+# endif
+#endif
+}
+
+SCM difference(x, y)
+ SCM x, y;
+{
+#ifdef FLOATS
+ if NINUMP(x) {
+# ifndef RECKLESS
+ if (!(NIMP(x)))
+ badx: wta(x, (char *)ARG1, s_difference);
+# endif
+ if UNBNDP(y) {
+# ifdef BIGDIG
+ if BIGP(x) {
+ x = copybig(x, !BIGSIGN(x));
+ return NUMDIGS(x) * BITSPERDIG/CHAR_BIT <= sizeof(SCM) ?
+ big2inum(x, NUMDIGS(x)) : x;
+ }
+# endif
+ ASRTGO(INEXP(x), badx);
+ return makdbl(-REALPART(x), CPLXP(x)?-IMAG(x):0.0);
+ }
+ if INUMP(y) return sum(x, MAKINUM(-INUM(y)));
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(x) {
+ if BIGP(y) return (NUMDIGS(x) < NUMDIGS(y)) ?
+ addbig(BDIGITS(x), NUMDIGS(x), BIGSIGN(x), y, 0x0100) :
+ addbig(BDIGITS(y), NUMDIGS(y), BIGSIGN(y) ^ 0x0100, x, 0);
+ ASRTGO(INEXP(y), bady);
+ return makdbl(big2dbl(x)-REALPART(y), CPLXP(y)?-IMAG(y):0.0);
+ }
+ ASRTGO(INEXP(x), badx);
+ if BIGP(y) return makdbl(REALPART(x)-big2dbl(y), CPLXP(x)?IMAG(x):0.0);
+ ASRTGO(INEXP(y), bady);
+# else
+ ASRTGO(INEXP(x), badx);
+ ASRTGO(NIMP(y) && INEXP(y), bady);
+# endif
+ if CPLXP(x)
+ if CPLXP(y)
+ return makdbl(REAL(x)-REAL(y), IMAG(x)-IMAG(y));
+ else
+ return makdbl(REAL(x)-REALPART(y), IMAG(x));
+ return makdbl(REALPART(x)-REALPART(y), CPLXP(y)?-IMAG(y):0.0);
+ }
+ if UNBNDP(y) {x = -INUM(x); goto checkx;}
+ if NINUMP(y) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) {
+# ifndef DIGSTOOBIG
+ long z = pseudolong(INUM(x));
+ return addbig((BIGDIG *)&z, DIGSPERLONG, (x < 0) ? 0x0100 : 0, y, 0x0100);
+# else
+ BIGDIG zdigs[DIGSPERLONG];
+ longdigs(INUM(x), zdigs);
+ return addbig(zdigs, DIGSPERLONG, (x < 0) ? 0x0100 : 0, y, 0x0100);
+# endif
+ }
+# ifndef RECKLESS
+ if (!(INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_difference);
+# endif
+# else
+# ifndef RECKLESS
+ if (!(NIMP(y) && INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_difference);
+# endif
+# endif
+ return makdbl(INUM(x)-REALPART(y), CPLXP(y)?-IMAG(y):0.0);
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ ASSERT(NIMP(x) && BIGP(x), x, ARG1, s_difference);
+ if UNBNDP(y) {
+ x = copybig(x, !BIGSIGN(x));
+ return NUMDIGS(x) * BITSPERDIG/CHAR_BIT <= sizeof(SCM) ?
+ big2inum(x, NUMDIGS(x)) : x;
+ }
+ if INUMP(y) {
+# ifndef DIGSTOOBIG
+ long z = pseudolong(INUM(y));
+ return addbig(&z, DIGSPERLONG, (y < 0) ? 0 : 0x0100, x, 0);
+# else
+ BIGDIG zdigs[DIGSPERLONG];
+ longdigs(INUM(x), zdigs);
+ return addbig(zdigs, DIGSPERLONG, (y < 0) ? 0 : 0x0100, x, 0);
+# endif
+ }
+ ASRTGO(NIMP(y) && BIGP(y), bady);
+ return (NUMDIGS(x) < NUMDIGS(y)) ?
+ addbig(BDIGITS(x), NUMDIGS(x), BIGSIGN(x), y, 0x0100) :
+ addbig(BDIGITS(y), NUMDIGS(y), BIGSIGN(y) ^ 0x0100, x, 0);
+ }
+ if UNBNDP(y) {x = -INUM(x); goto checkx;}
+ if NINUMP(y) {
+# ifndef RECKLESS
+ if (!(NIMP(y) && BIGP(y)))
+ bady: wta(y, (char *)ARG2, s_difference);
+# endif
+ {
+# ifndef DIGSTOOBIG
+ long z = pseudolong(INUM(x));
+ return addbig(&z, DIGSPERLONG, (x < 0) ? 0x0100 : 0, y, 0x0100);
+# else
+ BIGDIG zdigs[DIGSPERLONG];
+ longdigs(INUM(x), zdigs);
+ return addbig(zdigs, DIGSPERLONG, (x < 0) ? 0x0100 : 0, y, 0x0100);
+# endif
+ }
+ }
+# else
+ ASSERT(INUMP(x), x, ARG1, s_difference);
+ if UNBNDP(y) {x = -INUM(x); goto checkx;}
+ ASSERT(INUMP(y), y, ARG2, s_difference);
+# endif
+#endif
+ x = INUM(x)-INUM(y);
+ checkx:
+ if FIXABLE(x) return MAKINUM(x);
+#ifdef BIGDIG
+ return long2big(x);
+#else
+# ifdef FLOATS
+ return makdbl((double)x, 0.0);
+# else
+ wta(y, (char *)OVFLOW, s_difference);
+# endif
+#endif
+}
+
+SCM product(x, y)
+ SCM x, y;
+{
+ if UNBNDP(y) {
+ if UNBNDP(x) return MAKINUM(1L);
+#ifndef RECKLESS
+ if (!(NUMBERP(x)))
+ badx: wta(x, (char *)ARG1, s_product);
+#endif
+ return x;
+ }
+#ifdef FLOATS
+ if NINUMP(x) {
+ SCM t;
+# ifdef BIGDIG
+ ASRTGO(NIMP(x), badx);
+ if BIGP(x) {
+ if INUMP(y) {t = x; x = y; y = t; goto intbig;}
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return mulbig(BDIGITS(x), NUMDIGS(x), BDIGITS(y), NUMDIGS(y),
+ BIGSIGN(x) ^ BIGSIGN(y));
+ ASRTGO(INEXP(y), bady);
+ bigreal: {
+ double bg = big2dbl(x);
+ return makdbl(bg*REALPART(y), CPLXP(y)?bg*IMAG(y):0.0); }
+ }
+ ASRTGO(INEXP(x), badx);
+# else
+ ASRTGO(NIMP(x) && INEXP(x), badx);
+# endif
+ if INUMP(y) {t = x; x = y; y = t; goto intreal;}
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) {t = x; x = y; y = t; goto bigreal;}
+# ifndef RECKLESS
+ else if (!(INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_product);
+# endif
+# else
+# ifndef RECKLESS
+ if (!(NIMP(y) && INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_product);
+# endif
+# endif
+ if CPLXP(x)
+ if CPLXP(y)
+ return makdbl(REAL(x)*REAL(y)-IMAG(x)*IMAG(y),
+ REAL(x)*IMAG(y)+IMAG(x)*REAL(y));
+ else
+ return makdbl(REAL(x)*REALPART(y), IMAG(x)*REALPART(y));
+ return makdbl(REALPART(x)*REALPART(y),
+ CPLXP(y)?REALPART(x)*IMAG(y):0.0);
+ }
+ if NINUMP(y) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) {
+ intbig: if (INUM0==x) return x; if (MAKINUM(1L)==x) return y;
+ {
+# ifndef DIGSTOOBIG
+ long z = pseudolong(INUM(x));
+ return mulbig((BIGDIG *)&z, DIGSPERLONG, BDIGITS(y), NUMDIGS(y),
+ BIGSIGN(y) ? (x>0) : (x<0));
+# else
+ BIGDIG zdigs[DIGSPERLONG];
+ longdigs(INUM(x), zdigs);
+ return mulbig(zdigs, DIGSPERLONG, BDIGITS(y), NUMDIGS(y),
+ BIGSIGN(y) ? (x>0) : (x<0));
+# endif
+ }
+ }
+ ASRTGO(INEXP(y), bady);
+# else
+ ASRTGO(NIMP(y) && INEXP(y), bady);
+# endif
+ intreal: return makdbl(INUM(x)*REALPART(y), CPLXP(y)?INUM(x)*IMAG(y):0.0);
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ ASRTGO(NIMP(x) && BIGP(x), badx);
+ if INUMP(y) {SCM t = x; x = y; y = t; goto intbig;}
+ ASRTGO(NIMP(y) && BIGP(y), bady);
+ return mulbig(BDIGITS(x), NUMDIGS(x), BDIGITS(y), NUMDIGS(y),
+ BIGSIGN(x) ^ BIGSIGN(y));
+ }
+ if NINUMP(y) {
+# ifndef RECKLESS
+ if (!(NIMP(y) && BIGP(y)))
+ bady: wta(y, (char *)ARG2, s_product);
+# endif
+ intbig: if (INUM0==x) return x; if (MAKINUM(1L)==x) return y;
+ {
+# ifndef DIGSTOOBIG
+ long z = pseudolong(INUM(x));
+ return mulbig(&z, DIGSPERLONG, BDIGITS(y), NUMDIGS(y),
+ BIGSIGN(y) ? (x>0) : (x<0));
+# else
+ BIGDIG zdigs[DIGSPERLONG];
+ longdigs(INUM(x), zdigs);
+ return mulbig(zdigs, DIGSPERLONG, BDIGITS(y), NUMDIGS(y),
+ BIGSIGN(y) ? (x>0) : (x<0));
+# endif
+ }
+ }
+# else
+ ASRTGO(INUMP(x), badx);
+ ASSERT(INUMP(y), y, ARG2, s_product);
+# endif
+#endif
+ {
+ long i, j, k;
+ i = INUM(x);
+ if (0==i) return x;
+ j = INUM(y);
+ k = i * j;
+ y = MAKINUM(k);
+ if (k != INUM(y) || k/i != j)
+#ifdef BIGDIG
+ { int sgn = (i < 0) ^ (j < 0);
+# ifndef DIGSTOOBIG
+ i = pseudolong(i);
+ j = pseudolong(j);
+ return mulbig((BIGDIG *)&i, DIGSPERLONG,
+ (BIGDIG *)&j, DIGSPERLONG, sgn);
+# else /* DIGSTOOBIG */
+ BIGDIG idigs[DIGSPERLONG];
+ BIGDIG jdigs[DIGSPERLONG];
+ longdigs(i, idigs);
+ longdigs(j, jdigs);
+ return mulbig(idigs, DIGSPERLONG, jdigs, DIGSPERLONG, sgn);
+# endif
+ }
+#else
+# ifdef FLOATS
+ return makdbl(((double)i)*((double)j), 0.0);
+# else
+ wta(y, (char *)OVFLOW, s_product);
+# endif
+#endif
+ return y;
+ }
+}
+
+SCM divide(x, y)
+ SCM x, y;
+{
+#ifdef FLOATS
+ double d, r, i, a;
+ if NINUMP(x) {
+# ifndef RECKLESS
+ if (!(NIMP(x)))
+ badx: wta(x, (char *)ARG1, s_divide);
+# endif
+ if UNBNDP(y) {
+# ifdef BIGDIG
+ if BIGP(x) return makdbl(1.0/big2dbl(x), 0.0);
+# endif
+ ASRTGO(INEXP(x), badx);
+ if REALP(x) return makdbl(1.0/REALPART(x), 0.0);
+ r = REAL(x); i = IMAG(x); d = r*r+i*i;
+ return makdbl(r/d, -i/d);
+ }
+# ifdef BIGDIG
+ if BIGP(x) {
+ SCM z;
+ if INUMP(y) {
+ z = INUM(y);
+ ASSERT(z, y, OVFLOW, s_divide);
+ if (1==z) return x;
+ if (z < 0) z = -z;
+ if (z < BIGRAD) {
+ SCM w = copybig(x, BIGSIGN(x) ? (y>0) : (y<0));
+ return divbigdig(BDIGITS(w), NUMDIGS(w), (BIGDIG)z) ?
+ makdbl(big2dbl(x)/INUM(y), 0.0) : normbig(w);
+ }
+# ifndef DIGSTOOBIG
+ z = pseudolong(z);
+ z = divbigbig(BDIGITS(x), NUMDIGS(x), (BIGDIG *)&z, DIGSPERLONG,
+ BIGSIGN(x) ? (y>0) : (y<0), 3);
+# else
+ { BIGDIG zdigs[DIGSPERLONG];
+ longdigs(z, zdigs);
+ z = divbigbig(BDIGITS(x), NUMDIGS(x), zdigs, DIGSPERLONG,
+ BIGSIGN(x) ? (y>0) : (y<0), 3);}
+# endif
+ return z ? z : makdbl(big2dbl(x)/INUM(y), 0.0);
+ }
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) {
+ z = divbigbig(BDIGITS(x), NUMDIGS(x), BDIGITS(y), NUMDIGS(y),
+ BIGSIGN(x) ^ BIGSIGN(y), 3);
+ return z ? z : makdbl(big2dbl(x)/big2dbl(y), 0.0);
+ }
+ ASRTGO(INEXP(y), bady);
+ if REALP(y) return makdbl(big2dbl(x)/REALPART(y), 0.0);
+ a = big2dbl(x);
+ goto complex_div;
+ }
+# endif
+ ASRTGO(INEXP(x), badx);
+ if INUMP(y) {d = INUM(y); goto basic_div;}
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) {d = big2dbl(y); goto basic_div;}
+ ASRTGO(INEXP(y), bady);
+# else
+ ASRTGO(NIMP(y) && INEXP(y), bady);
+# endif
+ if REALP(y) {
+ d = REALPART(y);
+ basic_div: return makdbl(REALPART(x)/d, CPLXP(x)?IMAG(x)/d:0.0);
+ }
+ a = REALPART(x);
+ if REALP(x) goto complex_div;
+ r = REAL(y); i = IMAG(y); d = r*r+i*i;
+ return makdbl((a*r+IMAG(x)*i)/d, (IMAG(x)*r-a*i)/d);
+ }
+ if UNBNDP(y) {
+ if ((MAKINUM(1L)==x) || (MAKINUM(-1L)==x)) return x;
+ return makdbl(1.0/((double)INUM(x)), 0.0);
+ }
+ if NINUMP(y) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(y), bady);
+ if BIGP(y) return makdbl(INUM(x)/big2dbl(y), 0.0);
+# ifndef RECKLESS
+ if (!(INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_divide);
+# endif
+# else
+# ifndef RECKLESS
+ if (!(NIMP(y) && INEXP(y)))
+ bady: wta(y, (char *)ARG2, s_divide);
+# endif
+# endif
+ if REALP(y) return makdbl(INUM(x)/REALPART(y), 0.0);
+ a = INUM(x);
+ complex_div:
+ r = REAL(y); i = IMAG(y); d = r*r+i*i;
+ return makdbl((a*r)/d, (-a*i)/d);
+ }
+#else
+# ifdef BIGDIG
+ if NINUMP(x) {
+ SCM z;
+ ASSERT(NIMP(x) && BIGP(x), x, ARG1, s_divide);
+ if UNBNDP(y) goto ov;
+ if INUMP(y) {
+ z = INUM(y);
+ if (!z) goto ov;
+ if (1==z) return x;
+ if (z < 0) z = -z;
+ if (z < BIGRAD) {
+ SCM w = copybig(x, BIGSIGN(x) ? (y>0) : (y<0));
+ if (divbigdig(BDIGITS(w), NUMDIGS(w), (BIGDIG)z)) goto ov;
+ return w;
+ }
+# ifndef DIGSTOOBIG
+ z = pseudolong(z);
+ z = divbigbig(BDIGITS(x), NUMDIGS(x), &z, DIGSPERLONG,
+ BIGSIGN(x) ? (y>0) : (y<0), 3);
+# else
+ { BIGDIG zdigs[DIGSPERLONG];
+ longdigs(z, zdigs);
+ z = divbigbig(BDIGITS(x), NUMDIGS(x), zdigs, DIGSPERLONG,
+ BIGSIGN(x) ? (y>0) : (y<0), 3);}
+# endif
+ } else {
+ ASRTGO(NIMP(y) && BIGP(y), bady);
+ z = divbigbig(BDIGITS(x), NUMDIGS(x), BDIGITS(y), NUMDIGS(y),
+ BIGSIGN(x) ^ BIGSIGN(y), 3);
+ }
+ if (!z) goto ov;
+ return z;
+ }
+ if UNBNDP(y) {
+ if ((MAKINUM(1L)==x) || (MAKINUM(-1L)==x)) return x;
+ goto ov;
+ }
+ if NINUMP(y) {
+# ifndef RECKLESS
+ if (!(NIMP(y) && BIGP(y)))
+ bady: wta(y, (char *)ARG2, s_divide);
+# endif
+ goto ov;
+ }
+# else
+ ASSERT(INUMP(x), x, ARG1, s_divide);
+ if UNBNDP(y) {
+ if ((MAKINUM(1L)==x) || (MAKINUM(-1L)==x)) return x;
+ goto ov;
+ }
+ ASSERT(INUMP(y), y, ARG2, s_divide);
+# endif
+#endif
+ {
+ long z = INUM(y);
+ if ((0==z) || INUM(x)%z) goto ov;
+ z = INUM(x)/z;
+ if FIXABLE(z) return MAKINUM(z);
+#ifdef BIGDIG
+ return long2big(z);
+#endif
+#ifdef FLOATS
+ ov: return makdbl(((double)INUM(x))/((double)INUM(y)), 0.0);
+#else
+ ov: wta(x, (char *)OVFLOW, s_divide);
+#endif
+ }
+}
+
+#ifdef FLOATS
+double lasinh(x)
+ double x;
+{
+ return log(x+sqrt(x*x+1));
+}
+
+double lacosh(x)
+ double x;
+{
+ return log(x+sqrt(x*x-1));
+}
+
+double latanh(x)
+ double x;
+{
+ return 0.5*log((1+x)/(1-x));
+}
+
+double ltrunc(x)
+ double x;
+{
+ if (x < 0.0) return -floor(-x);
+ return floor(x);
+}
+double round(x)
+ double x;
+{
+ double plus_half = x + 0.5;
+ double result = floor(plus_half);
+ /* Adjust so that the round is towards even. */
+ return (plus_half==result && plus_half / 2 != floor(plus_half / 2))
+ ? result - 1 : result;
+}
+
+struct dpair {double x, y;};
+
+void two_doubles(z1, z2, sstring, xy)
+ SCM z1, z2;
+ char *sstring;
+ struct dpair *xy;
+{
+ if INUMP(z1) xy->x = INUM(z1);
+ else {
+# ifdef BIGDIG
+ ASRTGO(NIMP(z1), badz1);
+ if BIGP(z1) xy->x = big2dbl(z1);
+ else {
+# ifndef RECKLESS
+ if (!(REALP(z1)))
+ badz1: wta(z1, (char *)ARG1, sstring);
+# endif
+ xy->x = REALPART(z1);}
+# else
+ {ASSERT(NIMP(z1) && REALP(z1), z1, ARG1, sstring);
+ xy->x = REALPART(z1);}
+# endif
+ }
+ if INUMP(z2) xy->y = INUM(z2);
+ else {
+# ifdef BIGDIG
+ ASRTGO(NIMP(z2), badz2);
+ if BIGP(z2) xy->y = big2dbl(z2);
+ else {
+# ifndef RECKLESS
+ if (!(REALP(z2)))
+ badz2: wta(z2, (char *)ARG2, sstring);
+# endif
+ xy->y = REALPART(z2);}
+# else
+ {ASSERT(NIMP(z2) && REALP(z2), z2, ARG2, sstring);
+ xy->y = REALPART(z2);}
+# endif
+ }
+}
+
+SCM expt(z1, z2)
+ SCM z1, z2;
+{
+ struct dpair xy;
+ two_doubles(z1, z2, s_expt, &xy);
+ return makdbl(pow(xy.x, xy.y), 0.0);
+}
+SCM latan2(z1, z2)
+ SCM z1, z2;
+{
+ struct dpair xy;
+ two_doubles(z1, z2, s_atan2, &xy);
+ return makdbl(atan2(xy.x, xy.y), 0.0);
+}
+SCM makrect(z1, z2)
+ SCM z1, z2;
+{
+ struct dpair xy;
+ two_doubles(z1, z2, s_makrect, &xy);
+ return makdbl(xy.x, xy.y);
+}
+SCM makpolar(z1, z2)
+ SCM z1, z2;
+{
+ struct dpair xy;
+ two_doubles(z1, z2, s_makpolar, &xy);
+ return makdbl(xy.x*cos(xy.y), xy.x*sin(xy.y));
+}
+
+SCM real_part(z)
+ SCM z;
+{
+ if NINUMP(z) {
+# ifdef BIGDIG
+ ASRTGO(NIMP(z), badz);
+ if BIGP(z) return z;
+# ifndef RECKLESS
+ if (!(INEXP(z)))
+ badz: wta(z, (char *)ARG1, s_real_part);
+# endif
+# else
+ ASSERT(NIMP(z) && INEXP(z), z, ARG1, s_real_part);
+# endif
+ if CPLXP(z) return makdbl(REAL(z), 0.0);
+ }
+ return z;
+}
+SCM imag_part(z)
+ SCM z;
+{
+ if INUMP(z) return INUM0;
+# ifdef BIGDIG
+ ASRTGO(NIMP(z), badz);
+ if BIGP(z) return INUM0;
+# ifndef RECKLESS
+ if (!(INEXP(z)))
+ badz: wta(z, (char *)ARG1, s_imag_part);
+# endif
+# else
+ ASSERT(NIMP(z) && INEXP(z), z, ARG1, s_imag_part);
+# endif
+ if CPLXP(z) return makdbl(IMAG(z), 0.0);
+ return flo0;
+}
+SCM magnitude(z)
+ SCM z;
+{
+ if INUMP(z) return absval(z);
+# ifdef BIGDIG
+ ASRTGO(NIMP(z), badz);
+ if BIGP(z) return absval(z);
+# ifndef RECKLESS
+ if (!(INEXP(z)))
+ badz: wta(z, (char *)ARG1, s_magnitude);
+# endif
+# else
+ ASSERT(NIMP(z) && INEXP(z), z, ARG1, s_magnitude);
+# endif
+ if CPLXP(z)
+ {
+ double i = IMAG(z), r = REAL(z);
+ return makdbl(sqrt(i*i+r*r), 0.0);
+ }
+ return makdbl(fabs(REALPART(z)), 0.0);
+}
+
+SCM angle(z)
+ SCM z;
+{
+ double x, y = 0.0;
+ if INUMP(z) {x = (z>=INUM0) ? 1.0 : -1.0; goto do_angle;}
+# ifdef BIGDIG
+ ASRTGO(NIMP(z), badz);
+ if BIGP(z) {x = (TYP16(z)==tc16_bigpos) ? 1.0 : -1.0; goto do_angle;}
+# ifndef RECKLESS
+ if (!(INEXP(z))) {
+ badz: wta(z, (char *)ARG1, s_angle);}
+# endif
+# else
+ ASSERT(NIMP(z) && INEXP(z), z, ARG1, s_angle);
+# endif
+ if REALP(z) {x = REALPART(z); goto do_angle;}
+ x = REAL(z); y = IMAG(z);
+do_angle:
+ return makdbl(atan2(y, x), 0.0);
+}
+
+double floident(z)
+ double z;
+{
+ return z;
+}
+SCM in2ex(z)
+ SCM z;
+{
+ if INUMP(z) return z;
+# ifdef BIGDIG
+ ASRTGO(NIMP(z), badz);
+ if BIGP(z) return z;
+# ifndef RECKLESS
+ if (!(REALP(z)))
+ badz: wta(z, (char *)ARG1, s_in2ex);
+# endif
+# else
+ ASSERT(NIMP(z) && REALP(z), z, ARG1, s_in2ex);
+# endif
+# ifdef BIGDIG
+ {
+ double u = floor(REALPART(z)+0.5);
+ if ((u <= MOST_POSITIVE_FIXNUM) && (-u <= -MOST_NEGATIVE_FIXNUM)) {
+ /* Negation is a workaround for HP700 cc bug */
+ SCM ans = MAKINUM((long)u);
+ if (INUM(ans)==(long)u) return ans;
+ }
+ ASRTGO(!IS_INF(u), badz); /* problem? */
+ return dbl2big(u);
+ }
+# else
+ return MAKINUM((long)floor(REALPART(z)+0.5));
+# endif
+}
+#else /* ~FLOATS */
+static char s_trunc[] = "truncate";
+SCM numident(x)
+ SCM x;
+{
+ ASSERT(INUMP(x), x, ARG1, s_trunc);
+ return x;
+}
+#endif /* FLOATS */
+
+#ifdef BIGDIG
+# ifdef FLOATS
+SCM dbl2big(d)
+ double d; /* must be integer */
+{
+ sizet i = 0;
+ long c;
+ BIGDIG *digits;
+ SCM ans;
+ double u = (d < 0)?-d:d;
+ while (0 != floor(u)) {u /= BIGRAD;i++;}
+ ans = mkbig(i, d < 0);
+ digits = BDIGITS(ans);
+ while (i--) {
+ u *= BIGRAD;
+ c = floor(u);
+ u -= c;
+ digits[i] = c;
+ }
+ ASSERT(0==u, INUM0, OVFLOW, "dbl2big");
+ return ans;
+}
+double big2dbl(b)
+ SCM b;
+{
+ double ans = 0.0;
+ sizet i = NUMDIGS(b);
+ BIGDIG *digits = BDIGITS(b);
+ while (i--) ans = digits[i] + BIGRAD*ans;
+ if (tc16_bigneg==TYP16(b)) return -ans;
+ return ans;
+}
+# endif
+#endif
+
+unsigned long hasher(obj, n, d)
+ SCM obj;
+ unsigned long n;
+ sizet d;
+{
+ switch (7 & (int) obj) {
+ case 2: case 6: /* INUMP(obj) */
+ return INUM(obj) % n;
+ case 4:
+ if ICHRP(obj)
+ return (unsigned)(downcase[ICHR(obj)]) % n;
+ switch ((int) obj) {
+#ifndef SICP
+ case (int) EOL: d = 256; break;
+#endif
+ case (int) BOOL_T: d = 257; break;
+ case (int) BOOL_F: d = 258; break;
+ case (int) EOF_VAL: d = 259; break;
+ default: d = 263; /* perhaps should be error */
+ }
+ return d % n;
+ default: return 263 % n; /* perhaps should be error */
+ case 0:
+ switch TYP7(obj) {
+ default: return 263 % n;
+ case tc7_smob:
+ switch TYP16(obj) {
+ case tcs_bignums:
+ bighash: return INUM(modulo(obj, MAKINUM(n)));
+ default: return 263 % n;
+#ifdef FLOATS
+ case tc16_flo:
+ if REALP(obj) {
+ double r = REALPART(obj);
+ if (floor(r)==r) {
+ obj = in2ex(obj);
+ if IMP(obj) return INUM(obj) % n;
+ goto bighash;
+ }
+ }
+ obj = number2string(obj, MAKINUM(10));
+#endif
+ }
+ case tcs_symbols: case tc7_string:
+ return strhash(UCHARS(obj), (sizet) LENGTH(obj), n);
+ case tc7_vector: {
+ sizet len = LENGTH(obj);
+ SCM *data = VELTS(obj);
+ if (len>5) {
+ sizet i = d/2;
+ unsigned long h = 1;
+ while (i--) h = ((h<<8) + (hasher(data[h % len], n, 2))) % n;
+ return h;
+ }
+ else {
+ sizet i = len;
+ unsigned long h = (n)-1;
+ while (i--) h = ((h<<8) + (hasher(data[i], n, d/len))) % n;
+ return h;
+ }
+ }
+ case tcs_cons_imcar: case tcs_cons_nimcar:
+ if (d) return (hasher(CAR(obj), n, d/2)+hasher(CDR(obj), n, d/2)) % n;
+ else return 1;
+ case tc7_port:
+ return ((RDNG & CAR(obj)) ? 260 : 261) % n;
+ case tcs_closures: case tc7_contin: case tcs_subrs:
+ return 262 % n;
+ }
+ }
+}
+
+static char s_hashv[] = "hashv", s_hashq[] = "hashq";
+extern char s_obunhash[];
+#define s_hash (&s_obunhash[9])
+
+SCM hash(obj, n)
+ SCM obj;
+ SCM n;
+{
+ ASSERT(INUMP(n) && 0 <= n, n, ARG2, s_hash);
+ return MAKINUM(hasher(obj, INUM(n), 10));
+}
+
+SCM hashv(obj, n)
+ SCM obj;
+ SCM n;
+{
+ ASSERT(INUMP(n) && 0 <= n, n, ARG2, s_hashv);
+ if ICHRP(obj) return MAKINUM((unsigned)(downcase[ICHR(obj)]) % INUM(n));
+ if (NIMP(obj) && NUMP(obj)) return MAKINUM(hasher(obj, INUM(n), 10));
+ else return MAKINUM(obj % INUM(n));
+}
+
+SCM hashq(obj, n)
+ SCM obj;
+ SCM n;
+{
+ ASSERT(INUMP(n) && 0 <= n, n, ARG2, s_hashq);
+ return MAKINUM((((unsigned) obj) >> 1) % INUM(n));
+}
+
+static iproc subr1s[] = {
+ {"number?", numberp},
+ {"complex?", numberp},
+ {s_inexactp, inexactp},
+#ifdef FLOATS
+ {"real?", realp},
+ {"rational?", realp},
+ {"integer?", intp},
+ {s_real_part, real_part},
+ {s_imag_part, imag_part},
+ {s_magnitude, magnitude},
+ {s_angle, angle},
+ {s_in2ex, in2ex},
+#else
+ {"real?", numberp},
+ {"rational?", numberp},
+ {"integer?", exactp},
+ {"floor", numident},
+ {"ceiling", numident},
+ {s_trunc, numident},
+ {"round", numident},
+#endif
+ {s_zerop, zerop},
+ {s_positivep, positivep},
+ {s_negativep, negativep},
+ {s_str2list, string2list},
+ {"list->string", string},
+ {s_st_copy, string_copy},
+ {"list->vector", vector},
+ {s_vect2list, vector2list},
+ {0, 0}};
+
+static iproc asubrs[] = {
+ {s_difference, difference},
+ {s_divide, divide},
+ {s_max, lmax},
+ {s_min, lmin},
+ {s_sum, sum},
+ {s_product, product},
+ {0, 0}};
+
+static iproc subr2s[] = {
+#ifdef FLOATS
+ {s_makrect, makrect},
+ {s_makpolar, makpolar},
+ {s_memv, memv},
+ {s_assv, assv},
+ {s_atan2, latan2},
+ {s_expt, expt},
+#else
+ {"memv", memq},
+ {"assv", assq},
+#endif
+ {s_list_tail, list_tail},
+ {s_ve_fill, vector_fill},
+ {s_st_fill, string_fill},
+ {s_hash, hash},
+ {s_hashv, hashv},
+ {s_hashq, hashq},
+ {0, 0}};
+
+static iproc subr2os[] = {
+ {s_str2number, string2number},
+ {s_number2string, number2string},
+ {0, 0}};
+
+static iproc rpsubrs[] = {
+#ifdef FLOATS
+ {"eqv?", eqv},
+#else
+ {"eqv?", eq},
+#endif
+ {s_eqp, eqp},
+ {s_lessp, lessp},
+ {s_grp, greaterp},
+ {s_leqp, leqp},
+ {s_greqp, greqp},
+ {0, 0}};
+
+#ifdef FLOATS
+static dblproc cxrs[] = {
+ {"floor", floor},
+ {"ceiling", ceil},
+ {"truncate", ltrunc},
+ {"round", round},
+ {"$sqrt", sqrt},
+ {"$abs", fabs},
+ {"$exp", exp},
+ {"$log", log},
+ {"$sin", sin},
+ {"$cos", cos},
+ {"$tan", tan},
+ {"$asin", asin},
+ {"$acos", acos},
+ {"$atan", atan},
+ {"$sinh", sinh},
+ {"$cosh", cosh},
+ {"$tanh", tanh},
+ {"$asinh", lasinh},
+ {"$acosh", lacosh},
+ {"$atanh", latanh},
+ {"exact->inexact", floident},
+ {0, 0}};
+#endif
+
+#ifdef FLOATS
+# ifndef DBL_DIG
+static void add1(f, fsum)
+ double f, *fsum;
+{
+ *fsum = f + 1.0;
+}
+# endif
+#endif
+
+void init_scl()
+{
+ init_iprocs(subr1s, tc7_subr_1);
+ init_iprocs(subr2os, tc7_subr_2o);
+ init_iprocs(subr2s, tc7_subr_2);
+ init_iprocs(asubrs, tc7_asubr);
+ init_iprocs(rpsubrs, tc7_rpsubr);
+#ifdef SICP
+ add_feature("sicp");
+#endif
+#ifdef FLOATS
+ init_iprocs((iproc *)cxrs, tc7_cxr);
+ NEWCELL(flo0);
+# ifdef SINGLES
+ CAR(flo0) = tc_flo;
+ FLO(flo0) = 0.0;
+# else
+ CDR(flo0) = (SCM)must_malloc(1L*sizeof(double), "real");
+ REAL(flo0) = 0.0;
+ CAR(flo0) = tc_dblr;
+# endif
+# ifdef DBL_DIG
+ dblprec = (DBL_DIG > 20) ? 20 : DBL_DIG;
+# else
+ { /* determine floating point precision */
+ double f = 0.1;
+ double fsum = 1.0+f;
+ while (fsum != 1.0) {
+ f /= 10.0;
+ if (++dblprec > 20) break;
+ add1(f, &fsum);
+ }
+ dblprec = dblprec-1;
+ }
+# endif /* DBL_DIG */
+#endif
+}