Changeset 41455a22 in mainline for uspace/lib/softfloat/generic/div.c

Timestamp:

2012-04-07T17:56:35Z (12 years ago)

Author:

Martin Decky <martin@…>

Branches:

lfn, master, serial, ticket/834-toolchain-update, topic/msim-upgrade, topic/simplify-dev-export

Children:

44c1a48, f3378ba

Parents:

6bb169b5 (diff), 88d5c1e (diff)
Note: this is a merge changeset, the changes displayed below correspond to the merge itself.
Use the (diff) links above to see all the changes relative to each parent.

Message:

merge GCC 4.7.0 bump and related changes

File:

• uspace/lib/softfloat/generic/div.c (modified) (33 diffs)

uspace/lib/softfloat/generic/div.c

@@ -41 +41 @@
 #include <common.h>
 
-/**
- * Divide two single-precision floats.
- * 
+/** Divide two single-precision floats.
+ *
  * @param a Nominator.
  * @param b Denominator.
+ *
  * @return Result of division.
- */
-float32 divFloat32(float32 a, float32 b) 
+ *
+ */
+float32 div_float32(float32 a, float32 b)
 {
         float32 result;
@@ -56 +57 @@
         result.parts.sign = a.parts.sign ^ b.parts.sign;
         
-        if (isFloat32NaN(a)) {
-                if (isFloat32SigNaN(a)) {
-                        /*FIXME: SigNaN*/
-                }
-                /*NaN*/
+        if (is_float32_nan(a)) {
+                if (is_float32_signan(a)) {
+                        // FIXME: SigNaN
+                }
+                /* NaN */
                 return a;
         }
         
-        if (isFloat32NaN(b)) {
-                if (isFloat32SigNaN(b)) {
-                        /*FIXME: SigNaN*/
-                }
-                /*NaN*/
+        if (is_float32_nan(b)) {
+                if (is_float32_signan(b)) {
+                        // FIXME: SigNaN
+                }
+                /* NaN */
                 return b;
         }
         
-        if (isFloat32Infinity(a)) {
-                if (isFloat32Infinity(b)) {
+        if (is_float32_infinity(a)) {
+                if (is_float32_infinity(b)) {
                         /*FIXME: inf / inf */
-                        result.binary = FLOAT32_NAN;
+                        result.bin = FLOAT32_NAN;
                         return result;
                 }
@@ -83 +84 @@
                 return result;
         }
-
-        if (isFloat32Infinity(b)) {
-                if (isFloat32Zero(a)) {
+        
+        if (is_float32_infinity(b)) {
+                if (is_float32_zero(a)) {
                         /* FIXME 0 / inf */
                         result.parts.exp = 0;
@@ -97 +98 @@
         }
         
-        if (isFloat32Zero(b)) {
-                if (isFloat32Zero(a)) {
+        if (is_float32_zero(b)) {
+                if (is_float32_zero(a)) {
                         /*FIXME: 0 / 0*/
-                        result.binary = FLOAT32_NAN;
+                        result.bin = FLOAT32_NAN;
                         return result;
                 }
@@ -121 +122 @@
                         return result;
                 }
-
+                
                 /* normalize it*/
                 afrac <<= 1;
-                /* afrac is nonzero => it must stop */  
+                /* afrac is nonzero => it must stop */
                 while (!(afrac & FLOAT32_HIDDEN_BIT_MASK)) {
                         afrac <<= 1;
@@ -130 +131 @@
                 }
         }
-
+        
         if (bexp == 0) {
                 bfrac <<= 1;
-                /* bfrac is nonzero => it must stop */  
+                /* bfrac is nonzero => it must stop */
                 while (!(bfrac & FLOAT32_HIDDEN_BIT_MASK)) {
                         bfrac <<= 1;
@@ -139 +140 @@
                 }
         }
-
-        afrac = (afrac | FLOAT32_HIDDEN_BIT_MASK) << (32 - FLOAT32_FRACTION_SIZE - 1);
-        bfrac = (bfrac | FLOAT32_HIDDEN_BIT_MASK) << (32 - FLOAT32_FRACTION_SIZE);
-
+        
+        afrac = (afrac | FLOAT32_HIDDEN_BIT_MASK) << (32 - FLOAT32_FRACTION_SIZE - 1);
+        bfrac = (bfrac | FLOAT32_HIDDEN_BIT_MASK) << (32 - FLOAT32_FRACTION_SIZE);
+        
         if (bfrac <= (afrac << 1)) {
                 afrac >>= 1;
@@ -169 +170 @@
                 ++cexp;
                 cfrac >>= 1;
-        }       
-
+        }
+        
         /* check overflow */
         if (cexp >= FLOAT32_MAX_EXPONENT) {
@@ -178 +179 @@
                 return result;
         }
-
+        
         if (cexp < 0) {
                 /* FIXME: underflow */
@@ -190 +191 @@
                         cexp++;
                         cfrac >>= 1;
-                }       
+                }
         } else {
                 result.parts.exp = (uint32_t) cexp;
@@ -197 +198 @@
         result.parts.fraction = ((cfrac >> 6) & (~FLOAT32_HIDDEN_BIT_MASK)); 
         
-        return result;  
+        return result;
 }
 
-/**
- * Divide two double-precision floats.
+/** Divide two double-precision floats.
  *
  * @param a Nominator.
  * @param b Denominator.
+ *
  * @return Result of division.
- */
-float64 divFloat64(float64 a, float64 b) 
+ *
+ */
+float64 div_float64(float64 a, float64 b) 
 {
         float64 result;
@@ -217 +219 @@
         result.parts.sign = a.parts.sign ^ b.parts.sign;
         
-        if (isFloat64NaN(a)) {
-                if (isFloat64SigNaN(b)) {
-                        /*FIXME: SigNaN*/
+        if (is_float64_nan(a)) {
+                if (is_float64_signan(b)) {
+                        // FIXME: SigNaN
                         return b;
                 }
                 
-                if (isFloat64SigNaN(a)) {
-                        /*FIXME: SigNaN*/
-                }
-                /*NaN*/
+                if (is_float64_signan(a)) {
+                        // FIXME: SigNaN
+                }
+                /* NaN */
                 return a;
         }
         
-        if (isFloat64NaN(b)) {
-                if (isFloat64SigNaN(b)) {
-                        /*FIXME: SigNaN*/
-                }
-                /*NaN*/
+        if (is_float64_nan(b)) {
+                if (is_float64_signan(b)) {
+                        // FIXME: SigNaN
+                }
+                /* NaN */
                 return b;
         }
         
-        if (isFloat64Infinity(a)) {
-                if (isFloat64Infinity(b) || isFloat64Zero(b)) {
-                        /*FIXME: inf / inf */
-                        result.binary = FLOAT64_NAN;
+        if (is_float64_infinity(a)) {
+                if (is_float64_infinity(b) || is_float64_zero(b)) {
+                        // FIXME: inf / inf
+                        result.bin = FLOAT64_NAN;
                         return result;
                 }
@@ -249 +251 @@
                 return result;
         }
-
-        if (isFloat64Infinity(b)) {
-                if (isFloat64Zero(a)) {
+        
+        if (is_float64_infinity(b)) {
+                if (is_float64_zero(a)) {
                         /* FIXME 0 / inf */
                         result.parts.exp = 0;
@@ -263 +265 @@
         }
         
-        if (isFloat64Zero(b)) {
-                if (isFloat64Zero(a)) {
+        if (is_float64_zero(b)) {
+                if (is_float64_zero(a)) {
                         /*FIXME: 0 / 0*/
-                        result.binary = FLOAT64_NAN;
+                        result.bin = FLOAT64_NAN;
                         return result;
                 }
@@ -274 +276 @@
                 return result;
         }
-
+        
         afrac = a.parts.fraction;
         aexp = a.parts.exp;
@@ -287 +289 @@
                         return result;
                 }
-
+                
                 /* normalize it*/
                 aexp++;
@@ -296 +298 @@
                 }
         }
-
+        
         if (bexp == 0) {
                 bexp++;
@@ -305 +307 @@
                 }
         }
-
-        afrac = (afrac | FLOAT64_HIDDEN_BIT_MASK) << (64 - FLOAT64_FRACTION_SIZE - 2);
-        bfrac = (bfrac | FLOAT64_HIDDEN_BIT_MASK) << (64 - FLOAT64_FRACTION_SIZE - 1);
-
+        
+        afrac = (afrac | FLOAT64_HIDDEN_BIT_MASK) << (64 - FLOAT64_FRACTION_SIZE - 2);
+        bfrac = (bfrac | FLOAT64_HIDDEN_BIT_MASK) << (64 - FLOAT64_FRACTION_SIZE - 1);
+        
         if (bfrac <= (afrac << 1)) {
                 afrac >>= 1;
@@ -330 +332 @@
         
         /* round and shift */
-        result = finishFloat64(cexp, cfrac, result.parts.sign);
+        result = finish_float64(cexp, cfrac, result.parts.sign);
         return result;
 }
 
-/**
- * Divide two quadruple-precision floats.
+/** Divide two quadruple-precision floats.
  *
  * @param a Nominator.
  * @param b Denominator.
+ *
  * @return Result of division.
- */
-float128 divFloat128(float128 a, float128 b)
+ *
+ */
+float128 div_float128(float128 a, float128 b)
 {
         float128 result;
@@ -349 +352 @@
         uint64_t rem_hihi, rem_hilo, rem_lohi, rem_lolo;
         uint64_t tmp_hihi, tmp_hilo, tmp_lohi, tmp_lolo;
-
+        
         result.parts.sign = a.parts.sign ^ b.parts.sign;
-
-        if (isFloat128NaN(a)) {
-                if (isFloat128SigNaN(b)) {
-                        /*FIXME: SigNaN*/
+        
+        if (is_float128_nan(a)) {
+                if (is_float128_signan(b)) {
+                        // FIXME: SigNaN
                         return b;
                 }
-
-                if (isFloat128SigNaN(a)) {
-                        /*FIXME: SigNaN*/
-                }
-                /*NaN*/
+                
+                if (is_float128_signan(a)) {
+                        // FIXME: SigNaN
+                }
+                /* NaN */
                 return a;
         }
-
-        if (isFloat128NaN(b)) {
-                if (isFloat128SigNaN(b)) {
-                        /*FIXME: SigNaN*/
-                }
-                /*NaN*/
+        
+        if (is_float128_nan(b)) {
+                if (is_float128_signan(b)) {
+                        // FIXME: SigNaN
+                }
+                /* NaN */
                 return b;
         }
-
-        if (isFloat128Infinity(a)) {
-                if (isFloat128Infinity(b) || isFloat128Zero(b)) {
-                        /*FIXME: inf / inf */
-                        result.binary.hi = FLOAT128_NAN_HI;
-                        result.binary.lo = FLOAT128_NAN_LO;
+        
+        if (is_float128_infinity(a)) {
+                if (is_float128_infinity(b) || is_float128_zero(b)) {
+                        // FIXME: inf / inf
+                        result.bin.hi = FLOAT128_NAN_HI;
+                        result.bin.lo = FLOAT128_NAN_LO;
                         return result;
                 }
@@ -386 +389 @@
                 return result;
         }
-
-        if (isFloat128Infinity(b)) {
-                if (isFloat128Zero(a)) {
-                        /* FIXME 0 / inf */
+        
+        if (is_float128_infinity(b)) {
+                if (is_float128_zero(a)) {
+                        // FIXME 0 / inf
                         result.parts.exp = 0;
                         result.parts.frac_hi = 0;
@@ -395 +398 @@
                         return result;
                 }
-                /* FIXME: num / inf*/
+                // FIXME: num / inf
                 result.parts.exp = 0;
                 result.parts.frac_hi = 0;
@@ -401 +404 @@
                 return result;
         }
-
-        if (isFloat128Zero(b)) {
-                if (isFloat128Zero(a)) {
-                        /*FIXME: 0 / 0*/
-                        result.binary.hi = FLOAT128_NAN_HI;
-                        result.binary.lo = FLOAT128_NAN_LO;
-                        return result;
-                }
-                /* FIXME: division by zero */
+        
+        if (is_float128_zero(b)) {
+                if (is_float128_zero(a)) {
+                        // FIXME: 0 / 0
+                        result.bin.hi = FLOAT128_NAN_HI;
+                        result.bin.lo = FLOAT128_NAN_LO;
+                        return result;
+                }
+                // FIXME: division by zero
                 result.parts.exp = 0;
                 result.parts.frac_hi = 0;
@@ -415 +418 @@
                 return result;
         }
-
+        
         afrac_hi = a.parts.frac_hi;
         afrac_lo = a.parts.frac_lo;
@@ -422 +425 @@
         bfrac_lo = b.parts.frac_lo;
         bexp = b.parts.exp;
-
+        
         /* denormalized numbers */
         if (aexp == 0) {
@@ -431 +434 @@
                         return result;
                 }
-
+                
                 /* normalize it*/
                 aexp++;
@@ -443 +446 @@
                 }
         }
-
+        
         if (bexp == 0) {
                 bexp++;
@@ -455 +458 @@
                 }
         }
-
+        
         or128(afrac_hi, afrac_lo,
             FLOAT128_HIDDEN_BIT_MASK_HI, FLOAT128_HIDDEN_BIT_MASK_LO,
@@ -466 +469 @@
         lshift128(bfrac_hi, bfrac_lo,
             (128 - FLOAT128_FRACTION_SIZE - 1), &bfrac_hi, &bfrac_lo);
-
+        
         if (le128(bfrac_hi, bfrac_lo, afrac_hi, afrac_lo)) {
                 rshift128(afrac_hi, afrac_lo, 1, &afrac_hi, &afrac_lo);
                 aexp++;
         }
-
+        
         cexp = aexp - bexp + FLOAT128_BIAS - 2;
-
+        
         cfrac_hi = div128est(afrac_hi, afrac_lo, bfrac_hi);
-
+        
         mul128(bfrac_hi, bfrac_lo, 0x0ll, cfrac_hi,
             &tmp_lolo /* dummy */, &tmp_hihi, &tmp_hilo, &tmp_lohi);
-
-        /* sub192(afrac_hi, afrac_lo, 0, 
+        
+        /* sub192(afrac_hi, afrac_lo, 0,
          *     tmp_hihi, tmp_hilo, tmp_lohi
          *     &rem_hihi, &rem_hilo, &rem_lohi); */
@@ -487 +490 @@
         }
         rem_lohi = -tmp_lohi;
-
+        
         while ((int64_t) rem_hihi < 0) {
                 --cfrac_hi;
-                /* add192(rem_hihi, rem_hilo, rem_lohi, 
+                /* add192(rem_hihi, rem_hilo, rem_lohi,
                  *     0, bfrac_hi, bfrac_lo,
                  *     &rem_hihi, &rem_hilo, &rem_lohi); */
@@ -498 +501 @@
                 }
         }
-
+        
         cfrac_lo = div128est(rem_hilo, rem_lohi, bfrac_lo);
-
+        
         if ((cfrac_lo & 0x3FFF) <= 4) {
                 mul128(bfrac_hi, bfrac_lo, 0x0ll, cfrac_lo,
-                &tmp_hihi /* dummy */, &tmp_hilo, &tmp_lohi, &tmp_lolo);
-
+                    &tmp_hihi /* dummy */, &tmp_hilo, &tmp_lohi, &tmp_lolo);
+                
                 /* sub192(rem_hilo, rem_lohi, 0,
                  *     tmp_hilo, tmp_lohi, tmp_lolo,
@@ -513 +516 @@
                 }
                 rem_lolo = -tmp_lolo;
-
+                
                 while ((int64_t) rem_hilo < 0) {
                         --cfrac_lo;
@@ -524 +527 @@
                         }
                 }
-
+                
                 cfrac_lo |= ((rem_hilo | rem_lohi | rem_lolo) != 0 );
         }
-
+        
         shift_out = cfrac_lo << (64 - (128 - FLOAT128_FRACTION_SIZE - 1));
         rshift128(cfrac_hi, cfrac_lo, (128 - FLOAT128_FRACTION_SIZE - 1),
             &cfrac_hi, &cfrac_lo);
-
-        result = finishFloat128(cexp, cfrac_hi, cfrac_lo, result.parts.sign, shift_out);
+        
+        result = finish_float128(cexp, cfrac_hi, cfrac_lo, result.parts.sign, shift_out);
         return result;
 }