-/* fltcalc.c
- * Authors: Matthias Heil
- */
-
/*
- * TODO:
+ * Copyright (C) 1995-2008 University of Karlsruhe. All right reserved.
+ *
+ * This file is part of libFirm.
*
- * This code uses the C-type long double to respesent floating
- * point values. This is bad because:
+ * This file may be distributed and/or modified under the terms of the
+ * GNU General Public License version 2 as published by the Free Software
+ * Foundation and appearing in the file LICENSE.GPL included in the
+ * packaging of this file.
*
- * 1.) It depends on IEEE arithmetic on the compilation engine (hardly a problem)
- * 2.) The existance on the type and its bits size (may be identical to double or even float)
- * 3.) Arithmetic operations will be done with "higher order" precision, which might be wrong
+ * Licensees holding valid libFirm Professional Edition licenses may use
+ * this file in accordance with the libFirm Commercial License.
+ * Agreement provided with the Software.
*
- * Replace this code ASAP.
+ * This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
+ * WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR
+ * PURPOSE.
*/
+
+/**
+ * @file
+ * @brief tarval floating point calculations
+ * @date 2003
+ * @author Mathias Heil
+ * @version $Id$
+ */
+
+#ifdef HAVE_CONFIG_H
+# include "config.h"
+#endif
+
#include "fltcalc.h"
-#include <string.h>
-#include <float.h>
-#include <stdlib.h>
+#include "strcalc.h"
+
+#include <math.h> /* need isnan() and isinf() (will be changed)*/
+/* undef some reused constants defined by math.h */
+#ifdef NAN
+# undef NAN
+#endif
+
+#ifdef HAVE_INTTYPES_H
+# include <inttypes.h>
+#endif
+#ifdef HAVE_STRING_H
+# include <string.h>
+#endif
+#ifdef HAVE_STDLIB_H
+# include <stdlib.h>
+#endif
#include <stdio.h>
+#include <assert.h>
-/* only defined in C99 mode */
-extern long double strtold(const char *str, char **end);
+#include "xmalloc.h"
-/********
- * globals
- ********/
-static long double value;
+/** The number of extra precesion rounding bits */
+#define ROUNDING_BITS 2
-//#define CAST_IN(val) ({ long double xxx = *(long double *)(val); printf("CAST to %Lg\n", xxx); xxx; })
+typedef uint32_t UINT32;
-#define CAST_IN(val) (*((long double *)((val))))
-#define CAST_OUT(val) ((void *)&(val))
+#ifdef HAVE_LONG_DOUBLE
+#ifdef WORDS_BIGENDIAN
+typedef union {
+ struct {
+ UINT32 high;
+ UINT32 mid;
+ UINT32 low;
+ } val;
+ volatile long double d;
+} value_t;
+#else
+typedef union {
+ struct {
+ UINT32 low;
+ UINT32 mid;
+ UINT32 high;
+ } val;
+ volatile long double d;
+} value_t;
+#endif
+#else
+#ifdef WORDS_BIGENDIAN
+typedef union {
+ struct {
+ UINT32 high;
+ UINT32 low;
+ } val;
+ volatile double d;
+} value_t;
+#else
+typedef union {
+ struct {
+ UINT32 low;
+ UINT32 high;
+ } val;
+ volatile double d;
+} value_t;
+#endif
+#endif
-#define CLEAR_BUFFER() memset((char*)&value, 0, sizeof(long double))
-/********
- * private functions
- ********/
+/**
+ * possible float states
+ */
+typedef enum {
+ NORMAL, /**< normal representation, implicit 1 */
+ ZERO, /**< +/-0 */
+ SUBNORMAL, /**< denormals, implicit 0 */
+ INF, /**< +/-oo */
+ NAN, /**< Not A Number */
+} value_class_t;
+
+/** A descriptor for an IEEE float value. */
+typedef struct {
+ unsigned char exponent_size; /**< size of exponent in bits */
+ unsigned char mantissa_size; /**< size of mantissa in bits */
+ value_class_t clss; /**< state of this float */
+} descriptor_t;
+
+#define CLEAR_BUFFER(buffer) memset(buffer, 0, calc_buffer_size)
+
+/* our floating point value */
+struct _fp_value {
+ descriptor_t desc;
+ char sign;
+ char value[1]; /* exp[value_size] + mant[value_size] */
+};
+
+#define _exp(a) &((a)->value[0])
+#define _mant(a) &((a)->value[value_size])
+
+#define _save_result(x) memcpy((x), sc_get_buffer(), value_size)
+#define _shift_right(x, y, b) sc_shr((x), (y), value_size*4, 0, (b))
+#define _shift_left(x, y, b) sc_shl((x), (y), value_size*4, 0, (b))
+
+
+#ifdef FLTCALC_DEBUG
+# define DEBUGPRINTF(x) printf x
+#else
+# define DEBUGPRINTF(x) ((void)0)
+#endif
+
+#ifdef FLTCALC_TRACE_CALC
+# define TRACEPRINTF(x) printf x
+#else
+# define TRACEPRINTF(x) ((void)0)
+#endif
+
+/** The immediate precision. */
+static unsigned immediate_prec = 0;
+
+/** A temporal buffer. */
+static fp_value *calc_buffer = NULL;
+
+/** Current rounding mode.*/
+static fc_rounding_mode_t rounding_mode;
+
+static int calc_buffer_size;
+static int value_size;
+static int max_precision;
+
+/** Exact flag. */
+static int fc_exact = 1;
+
+#if 0
+static void fail_char(const char *str, unsigned int len, int pos) {
+ if (*(str+pos))
+ printf("ERROR: Unexpected character '%c'\n", *(str + pos));
+ else
+ printf("ERROR: Unexpected end of string\n");
+ while (len-- && *str) printf("%c", *str++); printf("\n");
+ while (pos--) printf(" "); printf("^\n");
+ /* the front end has to to check constant strings */
+ exit(-1);
+}
+#endif
+
+/** pack machine-like */
+static void *pack(const fp_value *int_float, void *packed) {
+ char *shift_val;
+ char *temp;
+ fp_value *val_buffer;
+
+ temp = alloca(value_size);
+ shift_val = alloca(value_size);
+
+ switch (int_float->desc.clss) {
+ case NAN:
+ val_buffer = alloca(calc_buffer_size);
+ fc_get_qnan(int_float->desc.exponent_size, int_float->desc.mantissa_size, val_buffer);
+ int_float = val_buffer;
+ break;
+
+ case INF:
+ val_buffer = alloca(calc_buffer_size);
+ fc_get_plusinf(int_float->desc.exponent_size, int_float->desc.mantissa_size, val_buffer);
+ val_buffer->sign = int_float->sign;
+ int_float = val_buffer;
+ break;
+
+ default:
+ break;
+ }
+ /* pack sign */
+ sc_val_from_ulong(int_float->sign, temp);
+
+ sc_val_from_ulong(int_float->desc.exponent_size + int_float->desc.mantissa_size, NULL);
+ _shift_left(temp, sc_get_buffer(), packed);
+
+ /* extract exponent */
+ sc_val_from_ulong(int_float->desc.mantissa_size, shift_val);
+
+ _shift_left(_exp(int_float), shift_val, temp);
+
+ sc_or(temp, packed, packed);
+
+ /* extract mantissa */
+ /* remove rounding bits */
+ sc_val_from_ulong(ROUNDING_BITS, shift_val);
+ _shift_right(_mant(int_float), shift_val, temp);
+
+ /* remove leading 1 (or 0 if denormalized) */
+ sc_max_from_bits(int_float->desc.mantissa_size, 0, shift_val); /* all mantissa bits are 1's */
+ sc_and(temp, shift_val, temp);
+
+ /* save result */
+ sc_or(temp, packed, packed);
+
+ return packed;
+}
+
+/**
+ * Normalize a fp_value.
+ *
+ * @return non-zero if result is exact
+ */
+static int normalize(const fp_value *in_val, fp_value *out_val, int sticky) {
+ int exact = 1;
+ int hsb;
+ char lsb, guard, round, round_dir = 0;
+ char *temp = alloca(value_size);
+
+ /* save rounding bits at the end */
+ hsb = ROUNDING_BITS + in_val->desc.mantissa_size - sc_get_highest_set_bit(_mant(in_val)) - 1;
+
+ if (in_val != out_val) {
+ out_val->sign = in_val->sign;
+ memcpy(&out_val->desc, &in_val->desc, sizeof(out_val->desc));
+ }
+
+ out_val->desc.clss = NORMAL;
+
+ /* mantissa all zeros, so zero exponent (because of explicit one) */
+ if (hsb == ROUNDING_BITS + in_val->desc.mantissa_size) {
+ sc_val_from_ulong(0, _exp(out_val));
+ hsb = -1;
+ }
+
+ /* shift the first 1 into the left of the radix point (i.e. hsb == -1) */
+ if (hsb < -1) {
+ /* shift right */
+ sc_val_from_ulong(-hsb-1, temp);
+
+ _shift_right(_mant(in_val), temp, _mant(out_val));
+
+ /* remember if some bits were shifted away */
+ if (sc_had_carry()) {
+ exact = 0;
+ sticky = 1;
+ }
+ sc_add(_exp(in_val), temp, _exp(out_val));
+ } else if (hsb > -1) {
+ /* shift left */
+ sc_val_from_ulong(hsb+1, temp);
+
+ _shift_left(_mant(in_val), temp, _mant(out_val));
+
+ sc_sub(_exp(in_val), temp, _exp(out_val));
+ }
+
+ /* check for exponent underflow */
+ if (sc_is_negative(_exp(out_val)) || sc_is_zero(_exp(out_val))) {
+ DEBUGPRINTF(("Exponent underflow!\n"));
+ /* exponent underflow */
+ /* shift the mantissa right to have a zero exponent */
+ sc_val_from_ulong(1, temp);
+ sc_sub(temp, _exp(out_val), NULL);
+
+ _shift_right(_mant(out_val), sc_get_buffer(), _mant(out_val));
+ if (sc_had_carry()) {
+ exact = 0;
+ sticky = 1;
+ }
+ /* denormalized means exponent of zero */
+ sc_val_from_ulong(0, _exp(out_val));
+
+ out_val->desc.clss = SUBNORMAL;
+ }
+
+ /* perform rounding by adding a value that clears the guard bit and the round bit
+ * and either causes a carry to round up or not */
+ /* get the last 3 bits of the value */
+ lsb = sc_sub_bits(_mant(out_val), out_val->desc.mantissa_size + ROUNDING_BITS, 0) & 0x7;
+ guard = (lsb&0x2)>>1;
+ round = lsb&0x1;
+
+ switch (rounding_mode) {
+ case FC_TONEAREST:
+ /* round to nearest representable value, if in doubt choose the version
+ * with lsb == 0 */
+ round_dir = guard && (sticky || round || lsb>>2);
+ break;
+ case FC_TOPOSITIVE:
+ /* if positive: round to one if the exact value is bigger, else to zero */
+ round_dir = (!out_val->sign && (guard || round || sticky));
+ break;
+ case FC_TONEGATIVE:
+ /* if negative: round to one if the exact value is bigger, else to zero */
+ round_dir = (out_val->sign && (guard || round || sticky));
+ break;
+ case FC_TOZERO:
+ /* always round to 0 (chopping mode) */
+ round_dir = 0;
+ break;
+ }
+ DEBUGPRINTF(("Rounding (s%d, l%d, g%d, r%d, s%d) %s\n", out_val->sign, lsb>>2, guard, round, sticky, (round_dir)?"up":"down"));
+
+ if (round_dir == 1) {
+ guard = (round^guard)<<1;
+ lsb = !(round || guard)<<2 | guard | round;
+ } else {
+ lsb = -((guard<<1) | round);
+ }
+
+ /* add the rounded value */
+ if (lsb != 0) {
+ sc_val_from_long(lsb, temp);
+ sc_add(_mant(out_val), temp, _mant(out_val));
+ exact = 0;
+ }
+
+ /* could have rounded down to zero */
+ if (sc_is_zero(_mant(out_val)) && (out_val->desc.clss == SUBNORMAL))
+ out_val->desc.clss = ZERO;
+
+ /* check for rounding overflow */
+ hsb = ROUNDING_BITS + out_val->desc.mantissa_size - sc_get_highest_set_bit(_mant(out_val)) - 1;
+ if ((out_val->desc.clss != SUBNORMAL) && (hsb < -1)) {
+ sc_val_from_ulong(1, temp);
+ _shift_right(_mant(out_val), temp, _mant(out_val));
+ if (exact && sc_had_carry())
+ exact = 0;
+ sc_add(_exp(out_val), temp, _exp(out_val));
+ } else if ((out_val->desc.clss == SUBNORMAL) && (hsb == -1)) {
+ /* overflow caused the mantissa to be normal again,
+ * so adapt the exponent accordingly */
+ sc_val_from_ulong(1, temp);
+ sc_add(_exp(out_val), temp, _exp(out_val));
+
+ out_val->desc.clss = NORMAL;
+ }
+ /* no further rounding is needed, because rounding overflow means
+ * the carry of the original rounding was propagated all the way
+ * up to the bit left of the radix point. This implies the bits
+ * to the right are all zeros (rounding is +1) */
+
+ /* check for exponent overflow */
+ sc_val_from_ulong((1 << out_val->desc.exponent_size) - 1, temp);
+ if (sc_comp(_exp(out_val), temp) != -1) {
+ DEBUGPRINTF(("Exponent overflow!\n"));
+ /* exponent overflow, reaction depends on rounding method:
+ *
+ * mode | sign of value | result
+ *--------------------------------------------------------------
+ * TO_NEAREST | + | +inf
+ * | - | -inf
+ *--------------------------------------------------------------
+ * TO_POSITIVE | + | +inf
+ * | - | smallest representable value
+ *--------------------------------------------------------------
+ * TO_NEAGTIVE | + | largest representable value
+ * | - | -inf
+ *--------------------------------------------------------------
+ * TO_ZERO | + | largest representable value
+ * | - | smallest representable value
+ *--------------------------------------------------------------*/
+ if (out_val->sign == 0) {
+ /* value is positive */
+ switch (rounding_mode) {
+ case FC_TONEAREST:
+ case FC_TOPOSITIVE:
+ out_val->desc.clss = INF;
+ break;
+
+ case FC_TONEGATIVE:
+ case FC_TOZERO:
+ fc_get_max(out_val->desc.exponent_size, out_val->desc.mantissa_size, out_val);
+ }
+ } else {
+ /* value is negative */
+ switch (rounding_mode) {
+ case FC_TONEAREST:
+ case FC_TONEGATIVE:
+ out_val->desc.clss = INF;
+ break;
+
+ case FC_TOPOSITIVE:
+ case FC_TOZERO:
+ fc_get_min(out_val->desc.exponent_size, out_val->desc.mantissa_size, out_val);
+ }
+ }
+ }
+ return exact;
+}
+
+/**
+ * Operations involving NaN's must return NaN
+ */
+#define handle_NAN(a, b, result) \
+do { \
+ if (a->desc.clss == NAN) { \
+ if (a != result) memcpy(result, a, calc_buffer_size); \
+ return; \
+ } \
+ if (b->desc.clss == NAN) { \
+ if (b != result) memcpy(result, b, calc_buffer_size); \
+ return; \
+ } \
+}while (0)
+
+
+/**
+ * calculate a + b, where a is the value with the bigger exponent
+ */
+static void _fadd(const fp_value *a, const fp_value *b, fp_value *result) {
+ char *temp;
+ char *exp_diff;
+
+ char sign, res_sign;
+ char sticky;
+
+ fc_exact = 1;
+
+ handle_NAN(a, b, result);
+
+ /* make sure result has a descriptor */
+ if (result != a && result != b)
+ memcpy(&result->desc, &a->desc, sizeof(descriptor_t));
+
+ /* determine if this is an addition or subtraction */
+ sign = a->sign ^ b->sign;
+
+ /* produce NaN on inf - inf */
+ if (sign && (a->desc.clss == INF) && (b->desc.clss == INF)) {
+ fc_get_qnan(a->desc.exponent_size, b->desc.mantissa_size, result);
+ return;
+ }
+
+ temp = alloca(value_size);
+ exp_diff = alloca(value_size);
+
+ /* get exponent difference */
+ sc_sub(_exp(a), _exp(b), exp_diff);
+
+ /* initially set sign to be the sign of a, special treatment of subtraction
+ * when exponents are equal is required though.
+ * Also special care about the sign is needed when the mantissas are equal
+ * (+/- 0 ?) */
+ if (sign && sc_val_to_long(exp_diff) == 0) {
+ switch (sc_comp(_mant(a), _mant(b))) {
+ case 1: /* a > b */
+ res_sign = a->sign; /* abs(a) is bigger and a is negative */
+ break;
+ case 0: /* a == b */
+ res_sign = (rounding_mode == FC_TONEGATIVE);
+ break;
+ case -1: /* a < b */
+ res_sign = b->sign; /* abs(b) is bigger and b is negative */
+ break;
+ default:
+ /* can't be reached */
+ res_sign = 0;
+ break;
+ }
+ }
+ else
+ res_sign = a->sign;
+ result->sign = res_sign;
+
+ /* sign has been taken care of, check for special cases */
+ if (a->desc.clss == ZERO || b->desc.clss == INF) {
+ if (b != result)
+ memcpy(result, b, calc_buffer_size);
+ result->sign = res_sign;
+ return;
+ }
+ if (b->desc.clss == ZERO || a->desc.clss == INF) {
+ if (a != result)
+ memcpy(result, a, calc_buffer_size);
+ result->sign = res_sign;
+ return;
+ }
+
+ /* shift the smaller value to the right to align the radix point */
+ /* subnormals have their radix point shifted to the right,
+ * take care of this first */
+ if ((b->desc.clss == SUBNORMAL) && (a->desc.clss != SUBNORMAL)) {
+ sc_val_from_ulong(1, temp);
+ sc_sub(exp_diff, temp, exp_diff);
+ }
+
+ _shift_right(_mant(b), exp_diff, temp);
+ sticky = sc_had_carry();
+ fc_exact &= !sticky;
+
+ if (sticky && sign) {
+ /* if subtracting a little more than the represented value or adding a little
+ * more than the represented value to a negative value this, in addition to the
+ * still set sticky bit, takes account of the 'little more' */
+ char *temp1 = alloca(calc_buffer_size);
+ sc_val_from_ulong(1, temp1);
+ sc_add(temp, temp1, temp);
+ }
+
+ if (sign) {
+ if (sc_comp(_mant(a), temp) == -1)
+ sc_sub(temp, _mant(a), _mant(result));
+ else
+ sc_sub(_mant(a), temp, _mant(result));
+ } else {
+ sc_add(_mant(a), temp, _mant(result));
+ }
+
+ /* _normalize expects a 'normal' radix point, adding two subnormals
+ * results in a subnormal radix point -> shifting before normalizing */
+ if ((a->desc.clss == SUBNORMAL) && (b->desc.clss == SUBNORMAL)) {
+ sc_val_from_ulong(1, NULL);
+ _shift_left(_mant(result), sc_get_buffer(), _mant(result));
+ }
+
+ /* resulting exponent is the bigger one */
+ memmove(_exp(result), _exp(a), value_size);
+
+ fc_exact &= normalize(result, result, sticky);
+}
+
+/**
+ * calculate a * b
+ */
+static void _fmul(const fp_value *a, const fp_value *b, fp_value *result) {
+ int sticky;
+ char *temp;
+ char res_sign;
+
+ fc_exact = 1;
+
+ handle_NAN(a, b, result);
+
+ temp = alloca(value_size);
+
+ if (result != a && result != b)
+ memcpy(&result->desc, &a->desc, sizeof(descriptor_t));
+
+ result->sign = res_sign = a->sign ^ b->sign;
+
+ /* produce NaN on 0 * inf */
+ if (a->desc.clss == ZERO) {
+ if (b->desc.clss == INF)
+ fc_get_qnan(a->desc.exponent_size, a->desc.mantissa_size, result);
+ else {
+ if (a != result)
+ memcpy(result, a, calc_buffer_size);
+ result->sign = res_sign;
+ }
+ return;
+ }
+ if (b->desc.clss == ZERO) {
+ if (a->desc.clss == INF)
+ fc_get_qnan(a->desc.exponent_size, a->desc.mantissa_size, result);
+ else {
+ if (b != result)
+ memcpy(result, b, calc_buffer_size);
+ result->sign = res_sign;
+ }
+ return;
+ }
+
+ if (a->desc.clss == INF) {
+ if (a != result)
+ memcpy(result, a, calc_buffer_size);
+ result->sign = res_sign;
+ return;
+ }
+ if (b->desc.clss == INF) {
+ if (b != result)
+ memcpy(result, b, calc_buffer_size);
+ result->sign = res_sign;
+ return;
+ }
+
+ /* exp = exp(a) + exp(b) - excess */
+ sc_add(_exp(a), _exp(b), _exp(result));
+
+ sc_val_from_ulong((1 << (a->desc.exponent_size - 1)) - 1, temp);
+ sc_sub(_exp(result), temp, _exp(result));
+
+ /* mixed normal, subnormal values introduce an error of 1, correct it */
+ if ((a->desc.clss == SUBNORMAL) ^ (b->desc.clss == SUBNORMAL)) {
+ sc_val_from_ulong(1, temp);
+ sc_add(_exp(result), temp, _exp(result));
+ }
+
+ sc_mul(_mant(a), _mant(b), _mant(result));
+
+ /* realign result: after a multiplication the digits right of the radix
+ * point are the sum of the factors' digits after the radix point. As all
+ * values are normalized they both have the same amount of these digits,
+ * which has to be restored by proper shifting
+ * because of the rounding bits */
+ sc_val_from_ulong(ROUNDING_BITS + result->desc.mantissa_size, temp);
+
+ _shift_right(_mant(result), temp, _mant(result));
+ sticky = sc_had_carry();
+ fc_exact &= !sticky;
+
+ fc_exact &= normalize(result, result, sticky);
+}
+
+/**
+ * calculate a / b
+ */
+static void _fdiv(const fp_value *a, const fp_value *b, fp_value *result) {
+ int sticky;
+ char *temp, *dividend;
+ char res_sign;
+
+ fc_exact = 1;
+
+ handle_NAN(a, b, result);
+
+ temp = alloca(value_size);
+ dividend = alloca(value_size);
+
+ if (result != a && result != b)
+ memcpy(&result->desc, &a->desc, sizeof(descriptor_t));
+
+ result->sign = res_sign = a->sign ^ b->sign;
+
+ /* produce NAN on 0/0 and inf/inf */
+ if (a->desc.clss == ZERO) {
+ if (b->desc.clss == ZERO)
+ /* 0/0 -> nan */
+ fc_get_qnan(a->desc.exponent_size, a->desc.mantissa_size, result);
+ else {
+ /* 0/x -> a */
+ if (a != result)
+ memcpy(result, a, calc_buffer_size);
+ result->sign = res_sign;
+ }
+ return;
+ }
+
+ if (b->desc.clss == INF) {
+ if (a->desc.clss == INF)
+ /* inf/inf -> nan */
+ fc_get_qnan(a->desc.exponent_size, a->desc.mantissa_size, result);
+ else {
+ /* x/inf -> 0 */
+ sc_val_from_ulong(0, NULL);
+ _save_result(_exp(result));
+ _save_result(_mant(result));
+ result->desc.clss = ZERO;
+ }
+ return;
+ }
+
+ if (a->desc.clss == INF) {
+ /* inf/x -> inf */
+ if (a != result)
+ memcpy(result, a, calc_buffer_size);
+ result->sign = res_sign;
+ return;
+ }
+ if (b->desc.clss == ZERO) {
+ /* division by zero */
+ if (result->sign)
+ fc_get_minusinf(a->desc.exponent_size, a->desc.mantissa_size, result);
+ else
+ fc_get_plusinf(a->desc.exponent_size, a->desc.mantissa_size, result);
+ return;
+ }
+
+ /* exp = exp(a) - exp(b) + excess - 1*/
+ sc_sub(_exp(a), _exp(b), _exp(result));
+ sc_val_from_ulong((1 << (a->desc.exponent_size - 1)) - 2, temp);
+ sc_add(_exp(result), temp, _exp(result));
+
+ /* mixed normal, subnormal values introduce an error of 1, correct it */
+ if ((a->desc.clss == SUBNORMAL) ^ (b->desc.clss == SUBNORMAL)) {
+ sc_val_from_ulong(1, temp);
+ sc_add(_exp(result), temp, _exp(result));
+ }
+
+ /* mant(res) = mant(a) / 1/2mant(b) */
+ /* to gain more bits of precision in the result the dividend could be
+ * shifted left, as this operation does not loose bits. This would not
+ * fit into the integer precision, but due to the rounding bits (which
+ * are always zero because the values are all normalized) the divisor
+ * can be shifted right instead to achieve the same result */
+ sc_val_from_ulong(ROUNDING_BITS + result->desc.mantissa_size, temp);
+
+ _shift_left(_mant(a), temp, dividend);
+
+ {
+ char *divisor = alloca(calc_buffer_size);
+ sc_val_from_ulong(1, divisor);
+ _shift_right(_mant(b), divisor, divisor);
+ sc_div(dividend, divisor, _mant(result));
+ sticky = sc_had_carry();
+ fc_exact &= !sticky;
+ }
+
+ fc_exact &= normalize(result, result, sticky);
+}
+
+#if 0
+static void _power_of_ten(int exp, descriptor_t *desc, char *result) {
+ char *build;
+ char *temp;
+
+ /* positive sign */
+ result->sign = 0;
+
+ /* set new descriptor (else result is supposed to already have one) */
+ if (desc != NULL)
+ memcpy(&result->desc, desc, sizeof(descriptor_t));
+
+ build = alloca(value_size);
+ temp = alloca(value_size);
+
+ sc_val_from_ulong((1 << (result->desc.exponent_size - 1)) - 1, _exp(result));
+
+ if (exp > 0) {
+ /* temp is value of ten now */
+ sc_val_from_ulong(10, NULL);
+ _save_result(temp);
+
+ for (exp--; exp > 0; exp--) {
+ _save_result(build);
+ sc_mul(build, temp, NULL);
+ }
+ _save_result(build);
+
+ /* temp is amount of left shift needed to put the value left of the radix point */
+ sc_val_from_ulong(result->desc.mantissa_size + ROUNDING_BITS, temp);
+
+ _shift_left(build, temp, _mant(result));
+
+ _normalize(result, result, 0);
+ }
+}
+#endif
+
+/**
+ * Truncate the fractional part away.
+ *
+ * This does not clip to any integer range.
+ */
+static void _trunc(const fp_value *a, fp_value *result) {
+ /*
+ * When exponent == 0 all bits left of the radix point
+ * are the integral part of the value. For 15bit exp_size
+ * this would require a left shift of max. 16383 bits which
+ * is too much.
+ * But it is enough to ensure that no bit right of the radix
+ * point remains set. This restricts the interesting
+ * exponents to the interval [0, mant_size-1].
+ * Outside this interval the truncated value is either 0 or
+ * it does not have fractional parts.
+ */
+
+ int exp_bias, exp_val;
+ char *temp;
+
+ /* fixme: can be exact */
+ fc_exact = 0;
+
+ temp = alloca(value_size);
+
+ if (a != result)
+ memcpy(&result->desc, &a->desc, sizeof(descriptor_t));
+
+ exp_bias = (1 << (a->desc.exponent_size - 1)) - 1;
+ exp_val = sc_val_to_long(_exp(a)) - exp_bias;
+
+ if (exp_val < 0) {
+ sc_val_from_ulong(0, NULL);
+ _save_result(_exp(result));
+ _save_result(_mant(result));
+ result->desc.clss = ZERO;
+
+ return;
+ }
+
+ if (exp_val > a->desc.mantissa_size) {
+ if (a != result)
+ memcpy(result, a, calc_buffer_size);
+
+ return;
+ }
+
+ /* set up a proper mask to delete all bits right of the
+ * radix point if the mantissa had been shifted until exp == 0 */
+ sc_max_from_bits(1 + exp_val, 0, temp);
+ sc_val_from_long(a->desc.mantissa_size - exp_val + 2, NULL);
+ _shift_left(temp, sc_get_buffer(), temp);
+
+ /* and the mask and return the result */
+ sc_and(_mant(a), temp, _mant(result));
+
+ if (a != result) memcpy(_exp(result), _exp(a), value_size);
+
+ return;
+}
/********
* functions defined in fltcalc.h
********/
-const void *fc_get_buffer(void)
-{
- return CAST_OUT(value);
-}
-
-const int fc_get_buffer_length(void)
-{
- return sizeof(long double);
-}
-
-void fc_val_from_str(const char *str, unsigned int len)
-{
- CLEAR_BUFFER();
- value = strtold(str, NULL);
-}
-
-void fc_val_from_float(long double l)
-{
- CLEAR_BUFFER();
- value = l;
-}
-
-long double fc_val_to_float(const void *val)
-{
- return CAST_IN(val);
-}
-
-void fc_get_min(unsigned int num_bits)
-{
- CLEAR_BUFFER();
- switch (num_bits)
- {
- case 32:
- value = FLT_MIN;
- break;
- case 64:
- value = DBL_MIN;
- break;
- case 80:
- default:
- value = LDBL_MIN;
- break;
- }
-}
-
-void fc_get_max(unsigned int num_bits)
-{
- CLEAR_BUFFER();
- switch (num_bits)
- {
- case 32:
- value = FLT_MAX;
- break;
- case 64:
- value = DBL_MAX;
- break;
- case 80:
- default:
- value = LDBL_MAX;
- break;
- }
-}
-
-void fc_get_nan(void)
-{
- value = strtold("nan", NULL);
-
-}
-
-void fc_get_inf(void)
-{
- value = strtold("inf", NULL);
-}
-
-void fc_calc(const void *a, const void *b, int opcode)
-{
- CLEAR_BUFFER();
- switch (opcode)
- {
- case FC_ADD:
- value = CAST_IN(a) + CAST_IN(b);
- break;
- case FC_SUB:
- value = CAST_IN(a) - CAST_IN(b);
- break;
- case FC_MUL:
- value = CAST_IN(a) * CAST_IN(b);
- break;
- case FC_DIV:
- value = CAST_IN(a) / CAST_IN(b);
- break;
- case FC_NEG:
- value = -CAST_IN(a);
- break;
- }
-}
-
-int fc_comp(const void *a, const void *b)
-{
- if (CAST_IN(a) == CAST_IN(b)) return 0;
- else return (CAST_IN(a) > CAST_IN(b))?(1):(-1);
-}
-
-char *fc_print_dec(const void *a, char *buf, int buflen)
-{
- snprintf(buf, buflen, "%1.30Lg", CAST_IN(a));
- return buf;
-}
-
-unsigned char fc_sub_bits(const void *value, unsigned num_bits, unsigned byte_ofs)
-{
- long double val = CAST_IN(value);
- float f;
- double d;
-
- unsigned char *p;
- unsigned len;
-
- switch (num_bits) {
- case 32:
- f = (float)val;
- p = (unsigned char *)&f;
- len = 4;
- break;
-
- case 64:
- d = (double)val;
- p = (unsigned char *)&d;
- len = 8;
- break;
-
- case 80:
- p = (unsigned char *)&val;
- len = 10;
- break;
-
- default:
- return 0;
- }
-
- if (byte_ofs > len)
- return 0;
- return p[byte_ofs];
+const void *fc_get_buffer(void) {
+ return calc_buffer;
+}
+
+int fc_get_buffer_length(void) {
+ return calc_buffer_size;
+}
+
+void *fc_val_from_str(const char *str, unsigned int len, char exp_size, char mant_size, void *result) {
+#if 0
+ enum {
+ START,
+ LEFT_OF_DOT,
+ RIGHT_OF_DOT,
+ EXP_START,
+ EXPONENT,
+ END
+ };
+
+ char exp_sign;
+ int exp_int, hsb, state;
+
+ const char *old_str;
+
+ int pos;
+ char *mant_str, *exp_val, *power_val;
+
+ (void) len;
+ if (result == NULL) result = calc_buffer;
+
+ exp_val = alloca(value_size);
+ power_val = alloca(calc_buffer_size);
+ mant_str = alloca((len)?(len):(strlen(str)));
+
+ result->desc.exponent_size = exp_size;
+ result->desc.mantissa_size = mant_size;
+ result->desc.clss = NORMAL;
+
+ old_str = str;
+ pos = 0;
+ exp_int = 0;
+ state = START;
+
+ while (len == 0 || str-old_str < len) {
+ switch (state) {
+ case START:
+ switch (*str) {
+ case '+':
+ result->sign = 0;
+ state = LEFT_OF_DOT;
+ str++;
+ break;
+
+ case '-':
+ result->sign = 1;
+ state = LEFT_OF_DOT;
+ str++;
+ break;
+
+ case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9':
+ result->sign = 0;
+ state = LEFT_OF_DOT;
+ break;
+
+ case '.':
+ result->sign = 0;
+ state = RIGHT_OF_DOT;
+ str++;
+ break;
+
+ case 'n':
+ case 'N':
+ case 'i':
+ case 'I':
+ break;
+
+ default:
+ fail_char(old_str, len, str - old_str);
+ }
+ break;
+
+ case LEFT_OF_DOT:
+ switch (*str) {
+ case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9':
+ mant_str[pos++] = *(str++);
+ break;
+
+ case '.':
+ state = RIGHT_OF_DOT;
+ str++;
+ break;
+
+ case 'e':
+ case 'E':
+ state = EXP_START;
+ str++;
+ break;
+
+ case '\0':
+ mant_str[pos] = '\0';
+ goto done;
+
+ default:
+ fail_char(old_str, len, str - old_str);
+ }
+ break;
+
+ case RIGHT_OF_DOT:
+ switch (*str) {
+ case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9':
+ mant_str[pos++] = *(str++);
+ exp_int++;
+ break;
+
+ case 'e':
+ case 'E':
+ state = EXP_START;
+ str++;
+ break;
+
+ case '\0':
+ mant_str[pos] = '\0';
+ goto done;
+
+ default:
+ fail_char(old_str, len, str - old_str);
+ }
+ break;
+
+ case EXP_START:
+ switch (*str) {
+ case '-':
+ exp_sign = 1;
+ /* fall through */
+ case '+':
+ if (*(str-1) != 'e' && *(str-1) != 'E') fail_char(old_str, len, str - old_str);
+ str++;
+ break;
+
+ case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9':
+ mant_str[pos] = '\0';
+ pos = 1;
+ str++;
+ state = EXPONENT;
+ break;
+
+ default:
+ fail_char(old_str, len, str - old_str);
+ }
+ break;
+
+ case EXPONENT:
+ switch (*str) {
+ case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9':
+ pos++;
+ str++;
+ break;
+
+ case '\0': goto done;
+
+ default:
+ fail_char(old_str, len, str - old_str);
+ }
+ }
+ } /* switch(state) */
+
+done:
+ sc_val_from_str(mant_str, strlen(mant_str), _mant(result));
+
+ /* shift to put value left of radix point */
+ sc_val_from_ulong(mant_size + ROUNDING_BITS, exp_val);
+
+ _shift_left(_mant(result), exp_val, _mant(result));
+
+ sc_val_from_ulong((1 << (exp_size - 1)) - 1, _exp(result));
+
+ _normalize(result, result, 0);
+
+ if (state == EXPONENT) {
+ exp_int -= atoi(str-pos);
+ }
+
+ _power_of_ten(exp_int, &result->desc, power_val);
+
+ _fdiv(result, power_val, result);
+
+ return result;
+#else
+ /* XXX excuse of an implementation to make things work */
+ LLDBL val;
+ fp_value *tmp = alloca(calc_buffer_size);
+ (void) len;
+
+#ifdef HAVE_LONG_DOUBLE
+ val = strtold(str, NULL);
+ DEBUGPRINTF(("val_from_str(%s)\n", str));
+ fc_val_from_ieee754(val, 15, 64, tmp);
+#else
+ val = strtod(str, NULL);
+ DEBUGPRINTF(("val_from_str(%s)\n", str));
+ fc_val_from_ieee754(val, 11, 52, tmp);
+#endif /* HAVE_LONG_DOUBLE */
+ return fc_cast(tmp, exp_size, mant_size, result);
+#endif
+}
+
+fp_value *fc_val_from_ieee754(LLDBL l, char exp_size, char mant_size, fp_value *result) {
+ char *temp;
+ int bias_res, bias_val, mant_val;
+ value_t srcval;
+ UINT32 sign, exponent, mantissa0, mantissa1;
+
+ srcval.d = l;
+ bias_res = ((1 << (exp_size - 1)) - 1);
+
+#ifdef HAVE_LONG_DOUBLE
+ mant_val = 64;
+ bias_val = 0x3fff;
+ sign = (srcval.val.high & 0x00008000) != 0;
+ exponent = (srcval.val.high & 0x00007FFF) ;
+ mantissa0 = srcval.val.mid;
+ mantissa1 = srcval.val.low;
+#else /* no long double */
+ mant_val = 52;
+ bias_val = 0x3ff;
+ sign = (srcval.val.high & 0x80000000) != 0;
+ exponent = (srcval.val.high & 0x7FF00000) >> 20;
+ mantissa0 = srcval.val.high & 0x000FFFFF;
+ mantissa1 = srcval.val.low;
+#endif
+
+#ifdef HAVE_LONG_DOUBLE
+ TRACEPRINTF(("val_from_float(%.8X%.8X%.8X)\n", ((int*)&l)[2], ((int*)&l)[1], ((int*)&l)[0]));/* srcval.val.high, srcval.val.mid, srcval.val.low)); */
+ DEBUGPRINTF(("(%d-%.4X-%.8X%.8X)\n", sign, exponent, mantissa0, mantissa1));
+#else
+ TRACEPRINTF(("val_from_float(%.8X%.8X)\n", srcval.val.high, srcval.val.low));
+ DEBUGPRINTF(("(%d-%.3X-%.5X%.8X)\n", sign, exponent, mantissa0, mantissa1));
+#endif
+
+ if (result == NULL) result = calc_buffer;
+ temp = alloca(value_size);
+
+ /* CLEAR the buffer, else some bits might be uninitialised */
+ memset(result, 0, fc_get_buffer_length());
+
+ result->desc.exponent_size = exp_size;
+ result->desc.mantissa_size = mant_size;
+
+ /* extract sign */
+ result->sign = sign;
+
+ /* sign and flag suffice to identify nan or inf, no exponent/mantissa
+ * encoding is needed. the function can return immediately in these cases */
+ if (isnan(l)) {
+ result->desc.clss = NAN;
+ TRACEPRINTF(("val_from_float resulted in NAN\n"));
+ return result;
+ }
+ else if (isinf(l)) {
+ result->desc.clss = INF;
+ TRACEPRINTF(("val_from_float resulted in %sINF\n", (result->sign == 1) ? "-" : ""));
+ return result;
+ }
+
+ /* build exponent, because input and output exponent and mantissa sizes may differ
+ * this looks more complicated than it is: unbiased input exponent + output bias,
+ * minus the mantissa difference which is added again later when the output float
+ * becomes normalized */
+#ifdef HAVE_EXPLICIT_ONE
+ sc_val_from_long((exponent-bias_val+bias_res)-(mant_val-mant_size-1), _exp(result));
+#else
+ sc_val_from_long((exponent-bias_val+bias_res)-(mant_val-mant_size), _exp(result));
+#endif
+
+ /* build mantissa representation */
+#ifndef HAVE_EXPLICIT_ONE
+ if (exponent != 0) {
+ /* insert the hidden bit */
+ sc_val_from_ulong(1, temp);
+ sc_val_from_ulong(mant_val + ROUNDING_BITS, NULL);
+ _shift_left(temp, sc_get_buffer(), NULL);
+ }
+ else
+#endif
+ {
+ sc_val_from_ulong(0, NULL);
+ }
+
+ _save_result(_mant(result));
+
+ /* bits from the upper word */
+ sc_val_from_ulong(mantissa0, temp);
+ sc_val_from_ulong(34, NULL);
+ _shift_left(temp, sc_get_buffer(), temp);
+ sc_or(_mant(result), temp, _mant(result));
+
+ /* bits from the lower word */
+ sc_val_from_ulong(mantissa1, temp);
+ sc_val_from_ulong(ROUNDING_BITS, NULL);
+ _shift_left(temp, sc_get_buffer(), temp);
+ sc_or(_mant(result), temp, _mant(result));
+
+ /* _normalize expects the radix point to be normal, so shift mantissa of subnormal
+ * origin one to the left */
+ if (exponent == 0) {
+ sc_val_from_ulong(1, NULL);
+ _shift_left(_mant(result), sc_get_buffer(), _mant(result));
+ }
+
+ normalize(result, result, 0);
+
+ TRACEPRINTF(("val_from_float results in %s\n", fc_print(result, temp, calc_buffer_size, FC_PACKED)));
+
+ return result;
+}
+
+LLDBL fc_val_to_ieee754(const fp_value *val) {
+ fp_value *value;
+ fp_value *temp = NULL;
+
+ int byte_offset;
+
+ UINT32 sign;
+ UINT32 exponent;
+ UINT32 mantissa0;
+ UINT32 mantissa1;
+
+ value_t buildval;
+
+#ifdef HAVE_LONG_DOUBLE
+ char result_exponent = 15;
+ char result_mantissa = 64;
+#else
+ char result_exponent = 11;
+ char result_mantissa = 52;
+#endif
+
+ temp = alloca(calc_buffer_size);
+#ifdef HAVE_EXPLICIT_ONE
+ value = fc_cast(val, result_exponent, result_mantissa-1, temp);
+#else
+ value = fc_cast(val, result_exponent, result_mantissa, temp);
+#endif
+
+ sign = value->sign;
+
+ /* @@@ long double exponent is 15bit, so the use of sc_val_to_long should not
+ * lead to wrong results */
+ exponent = sc_val_to_long(_exp(value)) ;
+
+ sc_val_from_ulong(ROUNDING_BITS, NULL);
+ _shift_right(_mant(value), sc_get_buffer(), _mant(value));
+
+ mantissa0 = 0;
+ mantissa1 = 0;
+
+ for (byte_offset = 0; byte_offset < 4; byte_offset++)
+ mantissa1 |= sc_sub_bits(_mant(value), result_mantissa, byte_offset) << (byte_offset<<3);
+
+ for (; (byte_offset<<3) < result_mantissa; byte_offset++)
+ mantissa0 |= sc_sub_bits(_mant(value), result_mantissa, byte_offset) << ((byte_offset-4)<<3);
+
+#ifdef HAVE_LONG_DOUBLE
+ buildval.val.high = sign << 15;
+ buildval.val.high |= exponent;
+ buildval.val.mid = mantissa0;
+ buildval.val.low = mantissa1;
+#else /* no long double */
+ mantissa0 &= 0x000FFFFF; /* get rid of garbage */
+ buildval.val.high = sign << 31;
+ buildval.val.high |= exponent << 20;
+ buildval.val.high |= mantissa0;
+ buildval.val.low = mantissa1;
+#endif
+
+ TRACEPRINTF(("val_to_float: %d-%x-%x%x\n", sign, exponent, mantissa0, mantissa1));
+ return buildval.d;
+}
+
+fp_value *fc_cast(const fp_value *value, char exp_size, char mant_size, fp_value *result) {
+ char *temp;
+ int exp_offset, val_bias, res_bias;
+
+ if (result == NULL) result = calc_buffer;
+ temp = alloca(value_size);
+
+ if (value->desc.exponent_size == exp_size && value->desc.mantissa_size == mant_size) {
+ if (value != result)
+ memcpy(result, value, calc_buffer_size);
+ return result;
+ }
+
+ if (value->desc.clss == NAN) {
+ if (sc_get_highest_set_bit(_mant(value)) == value->desc.mantissa_size + 1)
+ return fc_get_qnan(exp_size, mant_size, result);
+ else
+ return fc_get_snan(exp_size, mant_size, result);
+ }
+
+ /* set the descriptor of the new value */
+ result->desc.exponent_size = exp_size;
+ result->desc.mantissa_size = mant_size;
+ result->desc.clss = value->desc.clss;
+
+ result->sign = value->sign;
+
+ /* when the mantissa sizes differ normalizing has to shift to align it.
+ * this would change the exponent, which is unwanted. So calculate this
+ * offset and add it */
+ val_bias = (1 << (value->desc.exponent_size - 1)) - 1;
+ res_bias = (1 << (exp_size - 1)) - 1;
+
+ exp_offset = (res_bias - val_bias) - (value->desc.mantissa_size - mant_size);
+ sc_val_from_long(exp_offset, temp);
+ sc_add(_exp(value), temp, _exp(result));
+
+ /* _normalize expects normalized radix point */
+ if (value->desc.clss == SUBNORMAL) {
+ sc_val_from_ulong(1, NULL);
+ _shift_left(_mant(value), sc_get_buffer(), _mant(result));
+ } else if (value != result) {
+ memcpy(_mant(result), _mant(value), value_size);
+ } else {
+ memmove(_mant(result), _mant(value), value_size);
+ }
+
+ normalize(result, result, 0);
+ TRACEPRINTF(("Cast results in %s\n", fc_print(result, temp, value_size, FC_PACKED)));
+ return result;
+}
+
+fp_value *fc_get_max(unsigned int exponent_size, unsigned int mantissa_size, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ result->desc.exponent_size = exponent_size;
+ result->desc.mantissa_size = mantissa_size;
+ result->desc.clss = NORMAL;
+
+ result->sign = 0;
+
+ sc_val_from_ulong((1<<exponent_size) - 2, _exp(result));
+
+ sc_max_from_bits(mantissa_size + 1, 0, _mant(result));
+ sc_val_from_ulong(ROUNDING_BITS, NULL);
+ _shift_left(_mant(result), sc_get_buffer(), _mant(result));
+
+ return result;
+}
+
+fp_value *fc_get_min(unsigned int exponent_size, unsigned int mantissa_size, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ fc_get_max(exponent_size, mantissa_size, result);
+ result->sign = 1;
+
+ return result;
+}
+
+fp_value *fc_get_snan(unsigned int exponent_size, unsigned int mantissa_size, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ result->desc.exponent_size = exponent_size;
+ result->desc.mantissa_size = mantissa_size;
+ result->desc.clss = NAN;
+
+ result->sign = 0;
+
+ sc_val_from_ulong((1<<exponent_size)-1, _exp(result));
+
+ /* signaling NaN has non-zero mantissa with msb not set */
+ sc_val_from_ulong(1, _mant(result));
+
+ return result;
+}
+
+fp_value *fc_get_qnan(unsigned int exponent_size, unsigned int mantissa_size, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ result->desc.exponent_size = exponent_size;
+ result->desc.mantissa_size = mantissa_size;
+ result->desc.clss = NAN;
+
+ result->sign = 0;
+
+ sc_val_from_ulong((1<<exponent_size)-1, _exp(result));
+
+ /* quiet NaN has the msb of the mantissa set, so shift one there */
+ sc_val_from_ulong(1, _mant(result));
+ /* mantissa_size >+< 1 because of two extra rounding bits */
+ sc_val_from_ulong(mantissa_size + 1, NULL);
+ _shift_left(_mant(result), sc_get_buffer(), _mant(result));
+
+ return result;
+}
+
+fp_value *fc_get_plusinf(unsigned int exponent_size, unsigned int mantissa_size, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ result->desc.exponent_size = exponent_size;
+ result->desc.mantissa_size = mantissa_size;
+ result->desc.clss = NORMAL;
+
+ result->sign = 0;
+
+ sc_val_from_ulong((1<<exponent_size)-1, _exp(result));
+
+ sc_val_from_ulong(0, _mant(result));
+
+ return result;
+}
+
+fp_value *fc_get_minusinf(unsigned int exponent_size, unsigned int mantissa_size, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ fc_get_plusinf(exponent_size, mantissa_size, result);
+ result->sign = 1;
+
+ return result;
+}
+
+int fc_comp(const fp_value *val_a, const fp_value *val_b) {
+ int mul = 1;
+
+ /*
+ * shortcut: if both values are identical, they are either
+ * Unordered if NaN or equal
+ */
+ if (val_a == val_b)
+ return val_a->desc.clss == NAN ? 2 : 0;
+
+ /* unordered if one is a NaN */
+ if (val_a->desc.clss == NAN || val_b->desc.clss == NAN)
+ return 2;
+
+ /* zero is equal independent of sign */
+ if ((val_a->desc.clss == ZERO) && (val_b->desc.clss == ZERO))
+ return 0;
+
+ /* different signs make compare easy */
+ if (val_a->sign != val_b->sign)
+ return (val_a->sign == 0) ? (1) : (-1);
+
+ mul = val_a->sign ? -1 : 1;
+
+ /* both infinity means equality */
+ if ((val_a->desc.clss == INF) && (val_b->desc.clss == INF))
+ return 0;
+
+ /* infinity is bigger than the rest */
+ if (val_a->desc.clss == INF)
+ return 1 * mul;
+ if (val_b->desc.clss == INF)
+ return -1 * mul;
+
+ /* check first exponent, that mantissa if equal */
+ switch (sc_comp(_exp(val_a), _exp(val_b))) {
+ case -1:
+ return -1 * mul;
+ case 1:
+ return 1 * mul;
+ case 0:
+ return sc_comp(_mant(val_a), _mant(val_b)) * mul;
+ default:
+ return 2;
+ }
+}
+
+int fc_is_zero(const fp_value *a) {
+ return a->desc.clss == ZERO;
+}
+
+int fc_is_negative(const fp_value *a) {
+ return a->sign;
+}
+
+int fc_is_inf(const fp_value *a) {
+ return a->desc.clss == INF;
+}
+
+int fc_is_nan(const fp_value *a) {
+ return a->desc.clss == NAN;
+}
+
+int fc_is_subnormal(const fp_value *a) {
+ return a->desc.clss == SUBNORMAL;
+}
+
+char *fc_print(const fp_value *val, char *buf, int buflen, unsigned base) {
+ char *mul_1;
+
+ mul_1 = alloca(calc_buffer_size);
+
+ switch (base) {
+ case FC_DEC:
+ switch (val->desc.clss) {
+ case INF:
+ if (buflen >= 8 + val->sign) sprintf(buf, "%sINFINITY", val->sign ? "-":"");
+ else snprintf(buf, buflen, "%sINF", val->sign ? "-":NULL);
+ break;
+ case NAN:
+ snprintf(buf, buflen, "NAN");
+ break;
+ case ZERO:
+ snprintf(buf, buflen, "0.0");
+ break;
+ default:
+ /* XXX to be implemented */
+#ifdef HAVE_LONG_DOUBLE
+ /* XXX 30 is arbitrary */
+ snprintf(buf, buflen, "%.30LE", fc_val_to_ieee754(val));
+#else
+ snprintf(buf, buflen, "%.18E", fc_val_to_ieee754(val));
+#endif
+ }
+ break;
+
+ case FC_HEX:
+ switch (val->desc.clss) {
+ case INF:
+ if (buflen >= 8+val->sign) sprintf(buf, "%sINFINITY", val->sign?"-":"");
+ else snprintf(buf, buflen, "%sINF", val->sign?"-":NULL);
+ break;
+ case NAN:
+ snprintf(buf, buflen, "NAN");
+ break;
+ case ZERO:
+ snprintf(buf, buflen, "0.0");
+ break;
+ default:
+#ifdef HAVE_LONG_DOUBLE
+ snprintf(buf, buflen, "%LA", fc_val_to_ieee754(val));
+#else
+ snprintf(buf, buflen, "%A", fc_val_to_ieee754(val));
+#endif
+ }
+ break;
+
+ case FC_PACKED:
+ default:
+ snprintf(buf, buflen, "%s", sc_print(pack(val, mul_1), value_size*4, SC_HEX, 0));
+ buf[buflen - 1] = '\0';
+ break;
+ }
+ return buf;
+}
+
+unsigned char fc_sub_bits(const fp_value *value, unsigned num_bits, unsigned byte_ofs) {
+ /* this is used to cache the packed version of the value */
+ static char *packed_value = NULL;
+
+ if (packed_value == NULL) packed_value = xmalloc(value_size);
+
+ if (value != NULL)
+ pack(value, packed_value);
+
+ return sc_sub_bits(packed_value, num_bits, byte_ofs);
+}
+
+/* Returns non-zero if the mantissa is zero, i.e. 1.0Exxx */
+int fc_zero_mantissa(const fp_value *value) {
+ return sc_get_lowest_set_bit(_mant(value)) == ROUNDING_BITS + value->desc.mantissa_size;
+}
+
+/* Returns the exponent of a value. */
+int fc_get_exponent(const fp_value *value) {
+ int exp_bias = (1 << (value->desc.exponent_size - 1)) - 1;
+ return sc_val_to_long(_exp(value)) - exp_bias;
+}
+
+/* Return non-zero if a given value can be converted lossless into another precision */
+int fc_can_lossless_conv_to(const fp_value *value, char exp_size, char mant_size) {
+ int v;
+ int exp_bias;
+
+ /* handle some special cases first */
+ switch (value->desc.clss) {
+ case ZERO:
+ case INF:
+ case NAN:
+ return 1;
+ default:
+ break;
+ }
+
+ /* check if the exponent can be encoded: note, 0 and all ones are reserved for the exponent */
+ exp_bias = (1 << (exp_size - 1)) - 1;
+ v = fc_get_exponent(value) + exp_bias;
+ if (0 < v && v < (1 << exp_size) - 1) {
+ /* check the mantissa */
+ v = value->desc.mantissa_size + ROUNDING_BITS - sc_get_lowest_set_bit(_mant(value));
+ return v < mant_size;
+ }
+ return 0;
+}
+
+
+fc_rounding_mode_t fc_set_rounding_mode(fc_rounding_mode_t mode) {
+ if (mode == FC_TONEAREST || mode == FC_TOPOSITIVE || mode == FC_TONEGATIVE || mode == FC_TOZERO)
+ rounding_mode = mode;
+
+ return rounding_mode;
+}
+
+fc_rounding_mode_t fc_get_rounding_mode(void) {
+ return rounding_mode;
+}
+
+void init_fltcalc(int precision) {
+ if (calc_buffer == NULL) {
+ /* does nothing if already init */
+ if (precision == 0) precision = FC_DEFAULT_PRECISION;
+
+ init_strcalc(precision + 4);
+
+ /* needs additionally two bits to round, a bit as explicit 1., and one for
+ * addition overflow */
+ max_precision = sc_get_precision() - 4;
+ if (max_precision < precision)
+ printf("WARNING: not enough precision available, using %d\n", max_precision);
+
+ rounding_mode = FC_TONEAREST;
+ value_size = sc_get_buffer_length();
+ calc_buffer_size = sizeof(fp_value) + 2*value_size - 1;
+
+ calc_buffer = xmalloc(calc_buffer_size);
+ memset(calc_buffer, 0, calc_buffer_size);
+ DEBUGPRINTF(("init fltcalc:\n\tVALUE_SIZE = %d\ntCALC_BUFFER_SIZE = %d\n\tcalc_buffer = %p\n\n", value_size, calc_buffer_size, calc_buffer));
+#ifdef HAVE_LONG_DOUBLE
+ DEBUGPRINTF(("\tUsing long double (1-15-64) interface\n"));
+#else
+ DEBUGPRINTF(("\tUsing double (1-11-52) interface\n"));
+#endif
+#ifdef WORDS_BIGENDIAN
+ DEBUGPRINTF(("\tWord order is big endian\n\n"));
+#else
+ DEBUGPRINTF(("\tWord order is little endian\n\n"));
+#endif
+ }
+}
+
+void finish_fltcalc (void) {
+ free(calc_buffer); calc_buffer = NULL;
+}
+
+#ifdef FLTCALC_TRACE_CALC
+static char buffer[100];
+#endif
+
+/* definition of interface functions */
+fp_value *fc_add(const fp_value *a, const fp_value *b, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ TRACEPRINTF(("%s ", fc_print(a, buffer, sizeof(buffer), FC_PACKED)));
+ TRACEPRINTF(("+ %s ", fc_print(b, buffer, sizeof(buffer), FC_PACKED)));
+
+ /* make the value with the bigger exponent the first one */
+ if (sc_comp(_exp(a), _exp(b)) == -1)
+ _fadd(b, a, result);
+ else
+ _fadd(a, b, result);
+
+ TRACEPRINTF(("= %s\n", fc_print(result, buffer, sizeof(buffer), FC_PACKED)));
+ return result;
+}
+
+fp_value *fc_sub(const fp_value *a, const fp_value *b, fp_value *result) {
+ fp_value *temp;
+
+ if (result == NULL) result = calc_buffer;
+
+ TRACEPRINTF(("%s ", fc_print(a, buffer, sizeof(buffer), FC_PACKED)));
+ TRACEPRINTF(("- %s ", fc_print(b, buffer, sizeof(buffer), FC_PACKED)));
+
+ temp = alloca(calc_buffer_size);
+ memcpy(temp, b, calc_buffer_size);
+ temp->sign = !b->sign;
+ if (sc_comp(_exp(a), _exp(temp)) == -1)
+ _fadd(temp, a, result);
+ else
+ _fadd(a, temp, result);
+
+ TRACEPRINTF(("= %s\n", fc_print(result, buffer, sizeof(buffer), FC_PACKED)));
+ return result;
+}
+
+fp_value *fc_mul(const fp_value *a, const fp_value *b, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ TRACEPRINTF(("%s ", fc_print(a, buffer, sizeof(buffer), FC_PACKED)));
+ TRACEPRINTF(("* %s ", fc_print(b, buffer, sizeof(buffer), FC_PACKED)));
+
+ _fmul(a, b, result);
+
+ TRACEPRINTF(("= %s\n", fc_print(result, buffer, sizeof(buffer), FC_PACKED)));
+ return result;
+}
+
+fp_value *fc_div(const fp_value *a, const fp_value *b, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ TRACEPRINTF(("%s ", fc_print(a, buffer, sizeof(buffer), FC_PACKED)));
+ TRACEPRINTF(("/ %s ", fc_print(b, buffer, sizeof(buffer), FC_PACKED)));
+
+ _fdiv(a, b, result);
+
+ TRACEPRINTF(("= %s\n", fc_print(result, buffer, sizeof(buffer), FC_PACKED)));
+ return result;
+}
+
+fp_value *fc_neg(const fp_value *a, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ TRACEPRINTF(("- %s ", fc_print(a, buffer, sizeof(buffer), FC_PACKED)));
+
+ if (a != result)
+ memcpy(result, a, calc_buffer_size);
+ result->sign = !a->sign;
+
+ TRACEPRINTF(("= %s\n", fc_print(result, buffer, sizeof(buffer), FC_PACKED)));
+ return result;
+}
+
+fp_value *fc_int(const fp_value *a, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ TRACEPRINTF(("%s ", fc_print(a, buffer, sizeof(buffer), FC_PACKED)));
+ TRACEPRINTF(("truncated to integer "));
+
+ _trunc(a, result);
+
+ TRACEPRINTF(("= %s\n", fc_print(result, buffer, sizeof(buffer), FC_PACKED)));
+ return result;
+}
+
+fp_value *fc_rnd(const fp_value *a, fp_value *result) {
+ if (result == NULL) result = calc_buffer;
+
+ (void) a;
+ TRACEPRINTF(("%s ", fc_print(a, buffer, sizeof(buffer), FC_PACKED)));
+ TRACEPRINTF(("rounded to integer "));
+
+ assert(!"fc_rnd() not yet implemented");
+
+ TRACEPRINTF(("= %s\n", fc_print(result, buffer, sizeof(buffer), FC_PACKED)));
+ return result;
+}
+
+/*
+ * convert a floating point value into an sc value ...
+ */
+int fc_flt2int(const fp_value *a, void *result, ir_mode *dst_mode) {
+ if (a->desc.clss == NORMAL) {
+ int exp_bias = (1 << (a->desc.exponent_size - 1)) - 1;
+ int exp_val = sc_val_to_long(_exp(a)) - exp_bias;
+ int shift, highest;
+
+ if (a->sign && !mode_is_signed(dst_mode)) {
+ /* FIXME: for now we cannot convert this */
+ return 0;
+ }
+
+ assert(exp_val >= 0 && "floating point value not integral before fc_flt2int() call");
+ shift = exp_val - (a->desc.mantissa_size + ROUNDING_BITS);
+
+ if (shift > 0) {
+ sc_shlI(_mant(a), shift, 64, 0, result);
+ } else {
+ sc_shrI(_mant(a), -shift, 64, 0, result);
+ }
+
+ /* check for overflow */
+ highest = sc_get_highest_set_bit(result);
+
+ if (mode_is_signed(dst_mode)) {
+ if (highest == sc_get_lowest_set_bit(result)) {
+ /* need extra test for MIN_INT */
+ if (highest >= (int) get_mode_size_bits(dst_mode)) {
+ /* FIXME: handle overflow */
+ return 0;
+ }
+ } else {
+ if (highest >= (int) get_mode_size_bits(dst_mode) - 1) {
+ /* FIXME: handle overflow */
+ return 0;
+ }
+ }
+ } else {
+ if (highest >= (int) get_mode_size_bits(dst_mode)) {
+ /* FIXME: handle overflow */
+ return 0;
+ }
+ }
+
+ if (a->sign)
+ sc_neg(result, result);
+
+ return 1;
+ }
+ else if (a->desc.clss == ZERO) {
+ sc_zero(result);
+ return 1;
+ }
+ return 0;
+}
+
+
+unsigned fc_set_immediate_precision(unsigned bits) {
+ unsigned old = immediate_prec;
+
+ immediate_prec = bits;
+ return old;
+}
+
+int fc_is_exact(void) {
+ return fc_exact;
}