//
// The LLVM Compiler Infrastructure
//
-// This file was developed by Neil Booth and is distributed under the
-// University of Illinois Open Source License. See LICENSE.TXT for details.
+// This file is distributed under the University of Illinois Open Source
+// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
//
//===----------------------------------------------------------------------===//
-#include <cassert>
-#include <cstring>
#include "llvm/ADT/APFloat.h"
+#include "llvm/ADT/APSInt.h"
+#include "llvm/ADT/FoldingSet.h"
+#include "llvm/ADT/Hashing.h"
+#include "llvm/ADT/StringRef.h"
+#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/MathExtras.h"
+#include <limits.h>
+#include <cstring>
using namespace llvm;
/* Assumed in hexadecimal significand parsing, and conversion to
hexadecimal strings. */
+#define COMPILE_TIME_ASSERT(cond) extern int CTAssert[(cond) ? 1 : -1]
COMPILE_TIME_ASSERT(integerPartWidth % 4 == 0);
namespace llvm {
/* Number of bits in the significand. This includes the integer
bit. */
unsigned int precision;
+
+ /* True if arithmetic is supported. */
+ unsigned int arithmeticOK;
};
- const fltSemantics APFloat::IEEEsingle = { 127, -126, 24 };
- const fltSemantics APFloat::IEEEdouble = { 1023, -1022, 53 };
- const fltSemantics APFloat::IEEEquad = { 16383, -16382, 113 };
- const fltSemantics APFloat::x87DoubleExtended = { 16383, -16382, 64 };
- const fltSemantics APFloat::Bogus = { 0, 0, 0 };
+ const fltSemantics APFloat::IEEEhalf = { 15, -14, 11, true };
+ const fltSemantics APFloat::IEEEsingle = { 127, -126, 24, true };
+ const fltSemantics APFloat::IEEEdouble = { 1023, -1022, 53, true };
+ const fltSemantics APFloat::IEEEquad = { 16383, -16382, 113, true };
+ const fltSemantics APFloat::x87DoubleExtended = { 16383, -16382, 64, true };
+ const fltSemantics APFloat::Bogus = { 0, 0, 0, true };
// The PowerPC format consists of two doubles. It does not map cleanly
// onto the usual format above. For now only storage of constants of
// this type is supported, no arithmetic.
- const fltSemantics APFloat::PPCDoubleDouble = { 1023, -1022, 106 };
+ const fltSemantics APFloat::PPCDoubleDouble = { 1023, -1022, 106, false };
/* A tight upper bound on number of parts required to hold the value
pow(5, power) is
- power * 1024 / (441 * integerPartWidth) + 1
-
+ power * 815 / (351 * integerPartWidth) + 1
+
However, whilst the result may require only this many parts,
because we are multiplying two values to get it, the
multiplication may require an extra part with the excess part
const unsigned int maxExponent = 16383;
const unsigned int maxPrecision = 113;
const unsigned int maxPowerOfFiveExponent = maxExponent + maxPrecision - 1;
- const unsigned int maxPowerOfFiveParts = 2 + ((maxPowerOfFiveExponent * 1024)
- / (441 * integerPartWidth));
+ const unsigned int maxPowerOfFiveParts = 2 + ((maxPowerOfFiveExponent * 815)
+ / (351 * integerPartWidth));
}
-/* Put a bunch of private, handy routines in an anonymous namespace. */
-namespace {
+/* A bunch of private, handy routines. */
- inline unsigned int
- partCountForBits(unsigned int bits)
- {
- return ((bits) + integerPartWidth - 1) / integerPartWidth;
- }
+static inline unsigned int
+partCountForBits(unsigned int bits)
+{
+ return ((bits) + integerPartWidth - 1) / integerPartWidth;
+}
- unsigned int
- digitValue(unsigned int c)
- {
- unsigned int r;
+/* Returns 0U-9U. Return values >= 10U are not digits. */
+static inline unsigned int
+decDigitValue(unsigned int c)
+{
+ return c - '0';
+}
- r = c - '0';
- if(r <= 9)
- return r;
+static unsigned int
+hexDigitValue(unsigned int c)
+{
+ unsigned int r;
- return -1U;
- }
+ r = c - '0';
+ if (r <= 9)
+ return r;
- unsigned int
- hexDigitValue(unsigned int c)
- {
- unsigned int r;
+ r = c - 'A';
+ if (r <= 5)
+ return r + 10;
- r = c - '0';
- if(r <= 9)
- return r;
+ r = c - 'a';
+ if (r <= 5)
+ return r + 10;
- r = c - 'A';
- if(r <= 5)
- return r + 10;
+ return -1U;
+}
+
+static inline void
+assertArithmeticOK(const llvm::fltSemantics &semantics) {
+ assert(semantics.arithmeticOK &&
+ "Compile-time arithmetic does not support these semantics");
+}
- r = c - 'a';
- if(r <= 5)
- return r + 10;
+/* Return the value of a decimal exponent of the form
+ [+-]ddddddd.
- return -1U;
- }
+ If the exponent overflows, returns a large exponent with the
+ appropriate sign. */
+static int
+readExponent(StringRef::iterator begin, StringRef::iterator end)
+{
+ bool isNegative;
+ unsigned int absExponent;
+ const unsigned int overlargeExponent = 24000; /* FIXME. */
+ StringRef::iterator p = begin;
- /* This is ugly and needs cleaning up, but I don't immediately see
- how whilst remaining safe. */
- static int
- totalExponent(const char *p, int exponentAdjustment)
- {
- integerPart unsignedExponent;
- bool negative, overflow;
- long exponent;
+ assert(p != end && "Exponent has no digits");
- /* Move past the exponent letter and sign to the digits. */
+ isNegative = (*p == '-');
+ if (*p == '-' || *p == '+') {
p++;
- negative = *p == '-';
- if(*p == '-' || *p == '+')
- p++;
+ assert(p != end && "Exponent has no digits");
+ }
- unsignedExponent = 0;
- overflow = false;
- for(;;) {
- unsigned int value;
+ absExponent = decDigitValue(*p++);
+ assert(absExponent < 10U && "Invalid character in exponent");
- value = digitValue(*p);
- if(value == -1U)
- break;
+ for (; p != end; ++p) {
+ unsigned int value;
- p++;
- unsignedExponent = unsignedExponent * 10 + value;
- if(unsignedExponent > 65535)
- overflow = true;
+ value = decDigitValue(*p);
+ assert(value < 10U && "Invalid character in exponent");
+
+ value += absExponent * 10;
+ if (absExponent >= overlargeExponent) {
+ absExponent = overlargeExponent;
+ p = end; /* outwit assert below */
+ break;
}
+ absExponent = value;
+ }
- if(exponentAdjustment > 65535 || exponentAdjustment < -65536)
- overflow = true;
+ assert(p == end && "Invalid exponent in exponent");
- if(!overflow) {
- exponent = unsignedExponent;
- if(negative)
- exponent = -exponent;
- exponent += exponentAdjustment;
- if(exponent > 65535 || exponent < -65536)
- overflow = true;
- }
+ if (isNegative)
+ return -(int) absExponent;
+ else
+ return (int) absExponent;
+}
- if(overflow)
- exponent = negative ? -65536: 65535;
+/* This is ugly and needs cleaning up, but I don't immediately see
+ how whilst remaining safe. */
+static int
+totalExponent(StringRef::iterator p, StringRef::iterator end,
+ int exponentAdjustment)
+{
+ int unsignedExponent;
+ bool negative, overflow;
+ int exponent = 0;
+
+ assert(p != end && "Exponent has no digits");
- return exponent;
+ negative = *p == '-';
+ if (*p == '-' || *p == '+') {
+ p++;
+ assert(p != end && "Exponent has no digits");
}
- const char *
- skipLeadingZeroesAndAnyDot(const char *p, const char **dot)
- {
- *dot = 0;
- while(*p == '0')
- p++;
+ unsignedExponent = 0;
+ overflow = false;
+ for (; p != end; ++p) {
+ unsigned int value;
- if(*p == '.') {
- *dot = p++;
- while(*p == '0')
- p++;
- }
+ value = decDigitValue(*p);
+ assert(value < 10U && "Invalid character in exponent");
- return p;
+ unsignedExponent = unsignedExponent * 10 + value;
+ if (unsignedExponent > 32767)
+ overflow = true;
}
- /* Return the trailing fraction of a hexadecimal number.
- DIGITVALUE is the first hex digit of the fraction, P points to
- the next digit. */
- lostFraction
- trailingHexadecimalFraction(const char *p, unsigned int digitValue)
- {
- unsigned int hexDigit;
+ if (exponentAdjustment > 32767 || exponentAdjustment < -32768)
+ overflow = true;
- /* If the first trailing digit isn't 0 or 8 we can work out the
- fraction immediately. */
- if(digitValue > 8)
- return lfMoreThanHalf;
- else if(digitValue < 8 && digitValue > 0)
- return lfLessThanHalf;
+ if (!overflow) {
+ exponent = unsignedExponent;
+ if (negative)
+ exponent = -exponent;
+ exponent += exponentAdjustment;
+ if (exponent > 32767 || exponent < -32768)
+ overflow = true;
+ }
- /* Otherwise we need to find the first non-zero digit. */
- while(*p == '0')
- p++;
+ if (overflow)
+ exponent = negative ? -32768: 32767;
- hexDigit = hexDigitValue(*p);
+ return exponent;
+}
- /* If we ran off the end it is exactly zero or one-half, otherwise
- a little more. */
- if(hexDigit == -1U)
- return digitValue == 0 ? lfExactlyZero: lfExactlyHalf;
- else
- return digitValue == 0 ? lfLessThanHalf: lfMoreThanHalf;
+static StringRef::iterator
+skipLeadingZeroesAndAnyDot(StringRef::iterator begin, StringRef::iterator end,
+ StringRef::iterator *dot)
+{
+ StringRef::iterator p = begin;
+ *dot = end;
+ while (*p == '0' && p != end)
+ p++;
+
+ if (*p == '.') {
+ *dot = p++;
+
+ assert(end - begin != 1 && "Significand has no digits");
+
+ while (*p == '0' && p != end)
+ p++;
}
- /* Return the fraction lost were a bignum truncated losing the least
- significant BITS bits. */
- lostFraction
- lostFractionThroughTruncation(const integerPart *parts,
- unsigned int partCount,
- unsigned int bits)
- {
- unsigned int lsb;
+ return p;
+}
- lsb = APInt::tcLSB(parts, partCount);
+/* Given a normal decimal floating point number of the form
- /* Note this is guaranteed true if bits == 0, or LSB == -1U. */
- if(bits <= lsb)
- return lfExactlyZero;
- if(bits == lsb + 1)
- return lfExactlyHalf;
- if(bits <= partCount * integerPartWidth
- && APInt::tcExtractBit(parts, bits - 1))
- return lfMoreThanHalf;
+ dddd.dddd[eE][+-]ddd
- return lfLessThanHalf;
- }
+ where the decimal point and exponent are optional, fill out the
+ structure D. Exponent is appropriate if the significand is
+ treated as an integer, and normalizedExponent if the significand
+ is taken to have the decimal point after a single leading
+ non-zero digit.
- /* Shift DST right BITS bits noting lost fraction. */
- lostFraction
- shiftRight(integerPart *dst, unsigned int parts, unsigned int bits)
- {
- lostFraction lost_fraction;
+ If the value is zero, V->firstSigDigit points to a non-digit, and
+ the return exponent is zero.
+*/
+struct decimalInfo {
+ const char *firstSigDigit;
+ const char *lastSigDigit;
+ int exponent;
+ int normalizedExponent;
+};
+
+static void
+interpretDecimal(StringRef::iterator begin, StringRef::iterator end,
+ decimalInfo *D)
+{
+ StringRef::iterator dot = end;
+ StringRef::iterator p = skipLeadingZeroesAndAnyDot (begin, end, &dot);
+
+ D->firstSigDigit = p;
+ D->exponent = 0;
+ D->normalizedExponent = 0;
+
+ for (; p != end; ++p) {
+ if (*p == '.') {
+ assert(dot == end && "String contains multiple dots");
+ dot = p++;
+ if (p == end)
+ break;
+ }
+ if (decDigitValue(*p) >= 10U)
+ break;
+ }
- lost_fraction = lostFractionThroughTruncation(dst, parts, bits);
+ if (p != end) {
+ assert((*p == 'e' || *p == 'E') && "Invalid character in significand");
+ assert(p != begin && "Significand has no digits");
+ assert((dot == end || p - begin != 1) && "Significand has no digits");
- APInt::tcShiftRight(dst, parts, bits);
+ /* p points to the first non-digit in the string */
+ D->exponent = readExponent(p + 1, end);
- return lost_fraction;
+ /* Implied decimal point? */
+ if (dot == end)
+ dot = p;
}
- /* Combine the effect of two lost fractions. */
- lostFraction
- combineLostFractions(lostFraction moreSignificant,
- lostFraction lessSignificant)
- {
- if(lessSignificant != lfExactlyZero) {
- if(moreSignificant == lfExactlyZero)
- moreSignificant = lfLessThanHalf;
- else if(moreSignificant == lfExactlyHalf)
- moreSignificant = lfMoreThanHalf;
+ /* If number is all zeroes accept any exponent. */
+ if (p != D->firstSigDigit) {
+ /* Drop insignificant trailing zeroes. */
+ if (p != begin) {
+ do
+ do
+ p--;
+ while (p != begin && *p == '0');
+ while (p != begin && *p == '.');
}
- return moreSignificant;
+ /* Adjust the exponents for any decimal point. */
+ D->exponent += static_cast<exponent_t>((dot - p) - (dot > p));
+ D->normalizedExponent = (D->exponent +
+ static_cast<exponent_t>((p - D->firstSigDigit)
+ - (dot > D->firstSigDigit && dot < p)));
}
- /* The error from the true value, in half-ulps, on multiplying two
- floating point numbers, which differ from the value they
- approximate by at most HUE1 and HUE2 half-ulps, is strictly less
- than the returned value.
+ D->lastSigDigit = p;
+}
- See "How to Read Floating Point Numbers Accurately" by William D
- Clinger. */
- unsigned int
- HUerrBound(bool inexactMultiply, unsigned int HUerr1, unsigned int HUerr2)
- {
- assert(HUerr1 < 2 || HUerr2 < 2 || (HUerr1 + HUerr2 < 8));
+/* Return the trailing fraction of a hexadecimal number.
+ DIGITVALUE is the first hex digit of the fraction, P points to
+ the next digit. */
+static lostFraction
+trailingHexadecimalFraction(StringRef::iterator p, StringRef::iterator end,
+ unsigned int digitValue)
+{
+ unsigned int hexDigit;
- if (HUerr1 + HUerr2 == 0)
- return inexactMultiply * 2; /* <= inexactMultiply half-ulps. */
- else
- return inexactMultiply + 2 * (HUerr1 + HUerr2);
- }
+ /* If the first trailing digit isn't 0 or 8 we can work out the
+ fraction immediately. */
+ if (digitValue > 8)
+ return lfMoreThanHalf;
+ else if (digitValue < 8 && digitValue > 0)
+ return lfLessThanHalf;
- /* The number of ulps from the boundary (zero, or half if ISNEAREST)
- when the least significant BITS are truncated. BITS cannot be
- zero. */
- integerPart
- ulpsFromBoundary(const integerPart *parts, unsigned int bits, bool isNearest)
- {
- unsigned int count, partBits;
- integerPart part, boundary;
+ /* Otherwise we need to find the first non-zero digit. */
+ while (*p == '0')
+ p++;
- assert (bits != 0);
+ assert(p != end && "Invalid trailing hexadecimal fraction!");
- bits--;
- count = bits / integerPartWidth;
- partBits = bits % integerPartWidth + 1;
+ hexDigit = hexDigitValue(*p);
- part = parts[count] & (~(integerPart) 0 >> (integerPartWidth - partBits));
+ /* If we ran off the end it is exactly zero or one-half, otherwise
+ a little more. */
+ if (hexDigit == -1U)
+ return digitValue == 0 ? lfExactlyZero: lfExactlyHalf;
+ else
+ return digitValue == 0 ? lfLessThanHalf: lfMoreThanHalf;
+}
- if (isNearest)
- boundary = (integerPart) 1 << (partBits - 1);
- else
- boundary = 0;
+/* Return the fraction lost were a bignum truncated losing the least
+ significant BITS bits. */
+static lostFraction
+lostFractionThroughTruncation(const integerPart *parts,
+ unsigned int partCount,
+ unsigned int bits)
+{
+ unsigned int lsb;
- if (count == 0) {
- if (part - boundary <= boundary - part)
- return part - boundary;
- else
- return boundary - part;
- }
+ lsb = APInt::tcLSB(parts, partCount);
- if (part == boundary) {
- while (--count)
- if (parts[count])
- return ~(integerPart) 0; /* A lot. */
+ /* Note this is guaranteed true if bits == 0, or LSB == -1U. */
+ if (bits <= lsb)
+ return lfExactlyZero;
+ if (bits == lsb + 1)
+ return lfExactlyHalf;
+ if (bits <= partCount * integerPartWidth &&
+ APInt::tcExtractBit(parts, bits - 1))
+ return lfMoreThanHalf;
- return parts[0];
- } else if (part == boundary - 1) {
- while (--count)
- if (~parts[count])
- return ~(integerPart) 0; /* A lot. */
+ return lfLessThanHalf;
+}
- return -parts[0];
- }
+/* Shift DST right BITS bits noting lost fraction. */
+static lostFraction
+shiftRight(integerPart *dst, unsigned int parts, unsigned int bits)
+{
+ lostFraction lost_fraction;
- return ~(integerPart) 0; /* A lot. */
- }
+ lost_fraction = lostFractionThroughTruncation(dst, parts, bits);
- /* Place pow(5, power) in DST, and return the number of parts used.
- DST must be at least one part larger than size of the answer. */
- static unsigned int
- powerOf5(integerPart *dst, unsigned int power)
- {
- static integerPart firstEightPowers[] = { 1, 5, 25, 125, 625, 3125,
- 15625, 78125 };
- static integerPart pow5s[maxPowerOfFiveParts * 2 + 5] = { 78125 * 5 };
- static unsigned int partsCount[16] = { 1 };
+ APInt::tcShiftRight(dst, parts, bits);
+
+ return lost_fraction;
+}
- integerPart scratch[maxPowerOfFiveParts], *p1, *p2, *pow5;
- unsigned int result;
+/* Combine the effect of two lost fractions. */
+static lostFraction
+combineLostFractions(lostFraction moreSignificant,
+ lostFraction lessSignificant)
+{
+ if (lessSignificant != lfExactlyZero) {
+ if (moreSignificant == lfExactlyZero)
+ moreSignificant = lfLessThanHalf;
+ else if (moreSignificant == lfExactlyHalf)
+ moreSignificant = lfMoreThanHalf;
+ }
- assert(power <= maxExponent);
+ return moreSignificant;
+}
- p1 = dst;
- p2 = scratch;
+/* The error from the true value, in half-ulps, on multiplying two
+ floating point numbers, which differ from the value they
+ approximate by at most HUE1 and HUE2 half-ulps, is strictly less
+ than the returned value.
- *p1 = firstEightPowers[power & 7];
- power >>= 3;
+ See "How to Read Floating Point Numbers Accurately" by William D
+ Clinger. */
+static unsigned int
+HUerrBound(bool inexactMultiply, unsigned int HUerr1, unsigned int HUerr2)
+{
+ assert(HUerr1 < 2 || HUerr2 < 2 || (HUerr1 + HUerr2 < 8));
- result = 1;
- pow5 = pow5s;
+ if (HUerr1 + HUerr2 == 0)
+ return inexactMultiply * 2; /* <= inexactMultiply half-ulps. */
+ else
+ return inexactMultiply + 2 * (HUerr1 + HUerr2);
+}
- for (unsigned int n = 0; power; power >>= 1, n++) {
- unsigned int pc;
+/* The number of ulps from the boundary (zero, or half if ISNEAREST)
+ when the least significant BITS are truncated. BITS cannot be
+ zero. */
+static integerPart
+ulpsFromBoundary(const integerPart *parts, unsigned int bits, bool isNearest)
+{
+ unsigned int count, partBits;
+ integerPart part, boundary;
- pc = partsCount[n];
+ assert(bits != 0);
- /* Calculate pow(5,pow(2,n+3)) if we haven't yet. */
- if (pc == 0) {
- pc = partsCount[n - 1];
- APInt::tcFullMultiply(pow5, pow5 - pc, pow5 - pc, pc, pc);
- pc *= 2;
- if (pow5[pc - 1] == 0)
- pc--;
- partsCount[n] = pc;
- }
+ bits--;
+ count = bits / integerPartWidth;
+ partBits = bits % integerPartWidth + 1;
- if (power & 1) {
- integerPart *tmp;
+ part = parts[count] & (~(integerPart) 0 >> (integerPartWidth - partBits));
- APInt::tcFullMultiply(p2, p1, pow5, result, pc);
- result += pc;
- if (p2[result - 1] == 0)
- result--;
+ if (isNearest)
+ boundary = (integerPart) 1 << (partBits - 1);
+ else
+ boundary = 0;
- /* Now result is in p1 with partsCount parts and p2 is scratch
- space. */
- tmp = p1, p1 = p2, p2 = tmp;
- }
+ if (count == 0) {
+ if (part - boundary <= boundary - part)
+ return part - boundary;
+ else
+ return boundary - part;
+ }
- pow5 += pc;
- }
+ if (part == boundary) {
+ while (--count)
+ if (parts[count])
+ return ~(integerPart) 0; /* A lot. */
- if (p1 != dst)
- APInt::tcAssign(dst, p1, result);
+ return parts[0];
+ } else if (part == boundary - 1) {
+ while (--count)
+ if (~parts[count])
+ return ~(integerPart) 0; /* A lot. */
- return result;
+ return -parts[0];
}
- /* Zero at the end to avoid modular arithmetic when adding one; used
- when rounding up during hexadecimal output. */
- static const char hexDigitsLower[] = "0123456789abcdef0";
- static const char hexDigitsUpper[] = "0123456789ABCDEF0";
- static const char infinityL[] = "infinity";
- static const char infinityU[] = "INFINITY";
- static const char NaNL[] = "nan";
- static const char NaNU[] = "NAN";
+ return ~(integerPart) 0; /* A lot. */
+}
+
+/* Place pow(5, power) in DST, and return the number of parts used.
+ DST must be at least one part larger than size of the answer. */
+static unsigned int
+powerOf5(integerPart *dst, unsigned int power)
+{
+ static const integerPart firstEightPowers[] = { 1, 5, 25, 125, 625, 3125,
+ 15625, 78125 };
+ integerPart pow5s[maxPowerOfFiveParts * 2 + 5];
+ pow5s[0] = 78125 * 5;
+
+ unsigned int partsCount[16] = { 1 };
+ integerPart scratch[maxPowerOfFiveParts], *p1, *p2, *pow5;
+ unsigned int result;
+ assert(power <= maxExponent);
+
+ p1 = dst;
+ p2 = scratch;
+
+ *p1 = firstEightPowers[power & 7];
+ power >>= 3;
+
+ result = 1;
+ pow5 = pow5s;
+
+ for (unsigned int n = 0; power; power >>= 1, n++) {
+ unsigned int pc;
+
+ pc = partsCount[n];
+
+ /* Calculate pow(5,pow(2,n+3)) if we haven't yet. */
+ if (pc == 0) {
+ pc = partsCount[n - 1];
+ APInt::tcFullMultiply(pow5, pow5 - pc, pow5 - pc, pc, pc);
+ pc *= 2;
+ if (pow5[pc - 1] == 0)
+ pc--;
+ partsCount[n] = pc;
+ }
- /* Write out an integerPart in hexadecimal, starting with the most
- significant nibble. Write out exactly COUNT hexdigits, return
- COUNT. */
- static unsigned int
- partAsHex (char *dst, integerPart part, unsigned int count,
- const char *hexDigitChars)
- {
- unsigned int result = count;
+ if (power & 1) {
+ integerPart *tmp;
- assert (count != 0 && count <= integerPartWidth / 4);
+ APInt::tcFullMultiply(p2, p1, pow5, result, pc);
+ result += pc;
+ if (p2[result - 1] == 0)
+ result--;
- part >>= (integerPartWidth - 4 * count);
- while (count--) {
- dst[count] = hexDigitChars[part & 0xf];
- part >>= 4;
+ /* Now result is in p1 with partsCount parts and p2 is scratch
+ space. */
+ tmp = p1, p1 = p2, p2 = tmp;
}
- return result;
+ pow5 += pc;
}
- /* Write out an unsigned decimal integer. */
- static char *
- writeUnsignedDecimal (char *dst, unsigned int n)
- {
- char buff[40], *p;
+ if (p1 != dst)
+ APInt::tcAssign(dst, p1, result);
- p = buff;
- do
- *p++ = '0' + n % 10;
- while (n /= 10);
+ return result;
+}
- do
- *dst++ = *--p;
- while (p != buff);
+/* Zero at the end to avoid modular arithmetic when adding one; used
+ when rounding up during hexadecimal output. */
+static const char hexDigitsLower[] = "0123456789abcdef0";
+static const char hexDigitsUpper[] = "0123456789ABCDEF0";
+static const char infinityL[] = "infinity";
+static const char infinityU[] = "INFINITY";
+static const char NaNL[] = "nan";
+static const char NaNU[] = "NAN";
- return dst;
- }
+/* Write out an integerPart in hexadecimal, starting with the most
+ significant nibble. Write out exactly COUNT hexdigits, return
+ COUNT. */
+static unsigned int
+partAsHex (char *dst, integerPart part, unsigned int count,
+ const char *hexDigitChars)
+{
+ unsigned int result = count;
- /* Write out a signed decimal integer. */
- static char *
- writeSignedDecimal (char *dst, int value)
- {
- if (value < 0) {
- *dst++ = '-';
- dst = writeUnsignedDecimal(dst, -(unsigned) value);
- } else
- dst = writeUnsignedDecimal(dst, value);
+ assert(count != 0 && count <= integerPartWidth / 4);
- return dst;
+ part >>= (integerPartWidth - 4 * count);
+ while (count--) {
+ dst[count] = hexDigitChars[part & 0xf];
+ part >>= 4;
}
+
+ return result;
+}
+
+/* Write out an unsigned decimal integer. */
+static char *
+writeUnsignedDecimal (char *dst, unsigned int n)
+{
+ char buff[40], *p;
+
+ p = buff;
+ do
+ *p++ = '0' + n % 10;
+ while (n /= 10);
+
+ do
+ *dst++ = *--p;
+ while (p != buff);
+
+ return dst;
+}
+
+/* Write out a signed decimal integer. */
+static char *
+writeSignedDecimal (char *dst, int value)
+{
+ if (value < 0) {
+ *dst++ = '-';
+ dst = writeUnsignedDecimal(dst, -(unsigned) value);
+ } else
+ dst = writeUnsignedDecimal(dst, value);
+
+ return dst;
}
/* Constructors. */
semantics = ourSemantics;
count = partCount();
- if(count > 1)
+ if (count > 1)
significand.parts = new integerPart[count];
}
void
APFloat::freeSignificand()
{
- if(partCount() > 1)
+ if (partCount() > 1)
delete [] significand.parts;
}
exponent = rhs.exponent;
sign2 = rhs.sign2;
exponent2 = rhs.exponent2;
- if(category == fcNormal || category == fcNaN)
+ if (category == fcNormal || category == fcNaN)
copySignificand(rhs);
}
partCount());
}
+/* Make this number a NaN, with an arbitrary but deterministic value
+ for the significand. If double or longer, this is a signalling NaN,
+ which may not be ideal. If float, this is QNaN(0). */
+void APFloat::makeNaN(bool SNaN, bool Negative, const APInt *fill)
+{
+ category = fcNaN;
+ sign = Negative;
+
+ integerPart *significand = significandParts();
+ unsigned numParts = partCount();
+
+ // Set the significand bits to the fill.
+ if (!fill || fill->getNumWords() < numParts)
+ APInt::tcSet(significand, 0, numParts);
+ if (fill) {
+ APInt::tcAssign(significand, fill->getRawData(),
+ std::min(fill->getNumWords(), numParts));
+
+ // Zero out the excess bits of the significand.
+ unsigned bitsToPreserve = semantics->precision - 1;
+ unsigned part = bitsToPreserve / 64;
+ bitsToPreserve %= 64;
+ significand[part] &= ((1ULL << bitsToPreserve) - 1);
+ for (part++; part != numParts; ++part)
+ significand[part] = 0;
+ }
+
+ unsigned QNaNBit = semantics->precision - 2;
+
+ if (SNaN) {
+ // We always have to clear the QNaN bit to make it an SNaN.
+ APInt::tcClearBit(significand, QNaNBit);
+
+ // If there are no bits set in the payload, we have to set
+ // *something* to make it a NaN instead of an infinity;
+ // conventionally, this is the next bit down from the QNaN bit.
+ if (APInt::tcIsZero(significand, numParts))
+ APInt::tcSetBit(significand, QNaNBit - 1);
+ } else {
+ // We always have to set the QNaN bit to make it a QNaN.
+ APInt::tcSetBit(significand, QNaNBit);
+ }
+
+ // For x87 extended precision, we want to make a NaN, not a
+ // pseudo-NaN. Maybe we should expose the ability to make
+ // pseudo-NaNs?
+ if (semantics == &APFloat::x87DoubleExtended)
+ APInt::tcSetBit(significand, QNaNBit + 1);
+}
+
+APFloat APFloat::makeNaN(const fltSemantics &Sem, bool SNaN, bool Negative,
+ const APInt *fill) {
+ APFloat value(Sem, uninitialized);
+ value.makeNaN(SNaN, Negative, fill);
+ return value;
+}
+
APFloat &
APFloat::operator=(const APFloat &rhs)
{
- if(this != &rhs) {
- if(semantics != rhs.semantics) {
+ if (this != &rhs) {
+ if (semantics != rhs.semantics) {
freeSignificand();
initialize(rhs.semantics);
}
category != rhs.category ||
sign != rhs.sign)
return false;
- if (semantics==(const llvm::fltSemantics* const)&PPCDoubleDouble &&
+ if (semantics==(const llvm::fltSemantics*)&PPCDoubleDouble &&
sign2 != rhs.sign2)
return false;
if (category==fcZero || category==fcInfinity)
return true;
else if (category==fcNormal && exponent!=rhs.exponent)
return false;
- else if (semantics==(const llvm::fltSemantics* const)&PPCDoubleDouble &&
+ else if (semantics==(const llvm::fltSemantics*)&PPCDoubleDouble &&
exponent2!=rhs.exponent2)
return false;
else {
}
APFloat::APFloat(const fltSemantics &ourSemantics, integerPart value)
-{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
+ : exponent2(0), sign2(0) {
+ assertArithmeticOK(ourSemantics);
initialize(&ourSemantics);
sign = 0;
zeroSignificand();
normalize(rmNearestTiesToEven, lfExactlyZero);
}
+APFloat::APFloat(const fltSemantics &ourSemantics) : exponent2(0), sign2(0) {
+ assertArithmeticOK(ourSemantics);
+ initialize(&ourSemantics);
+ category = fcZero;
+ sign = false;
+}
+
+APFloat::APFloat(const fltSemantics &ourSemantics, uninitializedTag tag)
+ : exponent2(0), sign2(0) {
+ assertArithmeticOK(ourSemantics);
+ // Allocates storage if necessary but does not initialize it.
+ initialize(&ourSemantics);
+}
+
APFloat::APFloat(const fltSemantics &ourSemantics,
fltCategory ourCategory, bool negative)
-{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
+ : exponent2(0), sign2(0) {
+ assertArithmeticOK(ourSemantics);
initialize(&ourSemantics);
category = ourCategory;
sign = negative;
- if(category == fcNormal)
+ if (category == fcNormal)
category = fcZero;
+ else if (ourCategory == fcNaN)
+ makeNaN();
}
-APFloat::APFloat(const fltSemantics &ourSemantics, const char *text)
-{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
+APFloat::APFloat(const fltSemantics &ourSemantics, StringRef text)
+ : exponent2(0), sign2(0) {
+ assertArithmeticOK(ourSemantics);
initialize(&ourSemantics);
convertFromString(text, rmNearestTiesToEven);
}
-APFloat::APFloat(const APFloat &rhs)
-{
+APFloat::APFloat(const APFloat &rhs) : exponent2(0), sign2(0) {
initialize(rhs.semantics);
assign(rhs);
}
freeSignificand();
}
+// Profile - This method 'profiles' an APFloat for use with FoldingSet.
+void APFloat::Profile(FoldingSetNodeID& ID) const {
+ ID.Add(bitcastToAPInt());
+}
+
unsigned int
APFloat::partCount() const
{
{
assert(category == fcNormal || category == fcNaN);
- if(partCount() > 1)
+ if (partCount() > 1)
return significand.parts;
else
return &significand.part;
/* Our callers should never cause us to overflow. */
assert(carry == 0);
+ (void)carry;
}
/* Add the significand of the RHS. Returns the carry flag. */
integerPart scratch[4];
integerPart *fullSignificand;
lostFraction lost_fraction;
+ bool ignored;
assert(semantics == rhs.semantics);
precision = semantics->precision;
newPartsCount = partCountForBits(precision * 2);
- if(newPartsCount > 4)
+ if (newPartsCount > 4)
fullSignificand = new integerPart[newPartsCount];
else
fullSignificand = scratch;
omsb = APInt::tcMSB(fullSignificand, newPartsCount) + 1;
exponent += rhs.exponent;
- if(addend) {
+ if (addend) {
Significand savedSignificand = significand;
const fltSemantics *savedSemantics = semantics;
fltSemantics extendedSemantics;
/* Normalize our MSB. */
extendedPrecision = precision + precision - 1;
- if(omsb != extendedPrecision)
- {
- APInt::tcShiftLeft(fullSignificand, newPartsCount,
- extendedPrecision - omsb);
- exponent -= extendedPrecision - omsb;
- }
+ if (omsb != extendedPrecision) {
+ APInt::tcShiftLeft(fullSignificand, newPartsCount,
+ extendedPrecision - omsb);
+ exponent -= extendedPrecision - omsb;
+ }
/* Create new semantics. */
extendedSemantics = *semantics;
extendedSemantics.precision = extendedPrecision;
- if(newPartsCount == 1)
+ if (newPartsCount == 1)
significand.part = fullSignificand[0];
else
significand.parts = fullSignificand;
semantics = &extendedSemantics;
APFloat extendedAddend(*addend);
- status = extendedAddend.convert(extendedSemantics, rmTowardZero);
+ status = extendedAddend.convert(extendedSemantics, rmTowardZero, &ignored);
assert(status == opOK);
+ (void)status;
lost_fraction = addOrSubtractSignificand(extendedAddend, false);
/* Restore our state. */
- if(newPartsCount == 1)
+ if (newPartsCount == 1)
fullSignificand[0] = significand.part;
significand = savedSignificand;
semantics = savedSemantics;
exponent -= (precision - 1);
- if(omsb > precision) {
+ if (omsb > precision) {
unsigned int bits, significantParts;
lostFraction lf;
APInt::tcAssign(lhsSignificand, fullSignificand, partsCount);
- if(newPartsCount > 4)
+ if (newPartsCount > 4)
delete [] fullSignificand;
return lost_fraction;
rhsSignificand = rhs.significandParts();
partsCount = partCount();
- if(partsCount > 2)
+ if (partsCount > 2)
dividend = new integerPart[partsCount * 2];
else
dividend = scratch;
divisor = dividend + partsCount;
/* Copy the dividend and divisor as they will be modified in-place. */
- for(i = 0; i < partsCount; i++) {
+ for (i = 0; i < partsCount; i++) {
dividend[i] = lhsSignificand[i];
divisor[i] = rhsSignificand[i];
lhsSignificand[i] = 0;
/* Normalize the divisor. */
bit = precision - APInt::tcMSB(divisor, partsCount) - 1;
- if(bit) {
+ if (bit) {
exponent += bit;
APInt::tcShiftLeft(divisor, partsCount, bit);
}
/* Normalize the dividend. */
bit = precision - APInt::tcMSB(dividend, partsCount) - 1;
- if(bit) {
+ if (bit) {
exponent -= bit;
APInt::tcShiftLeft(dividend, partsCount, bit);
}
/* Ensure the dividend >= divisor initially for the loop below.
Incidentally, this means that the division loop below is
guaranteed to set the integer bit to one. */
- if(APInt::tcCompare(dividend, divisor, partsCount) < 0) {
+ if (APInt::tcCompare(dividend, divisor, partsCount) < 0) {
exponent--;
APInt::tcShiftLeft(dividend, partsCount, 1);
assert(APInt::tcCompare(dividend, divisor, partsCount) >= 0);
}
/* Long division. */
- for(bit = precision; bit; bit -= 1) {
- if(APInt::tcCompare(dividend, divisor, partsCount) >= 0) {
+ for (bit = precision; bit; bit -= 1) {
+ if (APInt::tcCompare(dividend, divisor, partsCount) >= 0) {
APInt::tcSubtract(dividend, divisor, 0, partsCount);
APInt::tcSetBit(lhsSignificand, bit - 1);
}
/* Figure out the lost fraction. */
int cmp = APInt::tcCompare(dividend, divisor, partsCount);
- if(cmp > 0)
+ if (cmp > 0)
lost_fraction = lfMoreThanHalf;
- else if(cmp == 0)
+ else if (cmp == 0)
lost_fraction = lfExactlyHalf;
- else if(APInt::tcIsZero(dividend, partsCount))
+ else if (APInt::tcIsZero(dividend, partsCount))
lost_fraction = lfExactlyZero;
else
lost_fraction = lfLessThanHalf;
- if(partsCount > 2)
+ if (partsCount > 2)
delete [] dividend;
return lost_fraction;
{
assert(bits < semantics->precision);
- if(bits) {
+ if (bits) {
unsigned int partsCount = partCount();
APInt::tcShiftLeft(significandParts(), partsCount, bits);
/* If exponents are equal, do an unsigned bignum comparison of the
significands. */
- if(compare == 0)
+ if (compare == 0)
compare = APInt::tcCompare(significandParts(), rhs.significandParts(),
partCount());
- if(compare > 0)
+ if (compare > 0)
return cmpGreaterThan;
- else if(compare < 0)
+ else if (compare < 0)
return cmpLessThan;
else
return cmpEqual;
APFloat::handleOverflow(roundingMode rounding_mode)
{
/* Infinity? */
- if(rounding_mode == rmNearestTiesToEven
- || rounding_mode == rmNearestTiesToAway
- || (rounding_mode == rmTowardPositive && !sign)
- || (rounding_mode == rmTowardNegative && sign))
- {
- category = fcInfinity;
- return (opStatus) (opOverflow | opInexact);
- }
+ if (rounding_mode == rmNearestTiesToEven ||
+ rounding_mode == rmNearestTiesToAway ||
+ (rounding_mode == rmTowardPositive && !sign) ||
+ (rounding_mode == rmTowardNegative && sign)) {
+ category = fcInfinity;
+ return (opStatus) (opOverflow | opInexact);
+ }
/* Otherwise we become the largest finite number. */
category = fcNormal;
/* Current callers never pass this so we don't handle it. */
assert(lost_fraction != lfExactlyZero);
- switch(rounding_mode) {
- default:
- assert(0);
-
+ switch (rounding_mode) {
case rmNearestTiesToAway:
return lost_fraction == lfExactlyHalf || lost_fraction == lfMoreThanHalf;
case rmNearestTiesToEven:
- if(lost_fraction == lfMoreThanHalf)
+ if (lost_fraction == lfMoreThanHalf)
return true;
/* Our zeroes don't have a significand to test. */
- if(lost_fraction == lfExactlyHalf && category != fcZero)
+ if (lost_fraction == lfExactlyHalf && category != fcZero)
return APInt::tcExtractBit(significandParts(), bit);
return false;
case rmTowardNegative:
return sign == true;
}
+ llvm_unreachable("Invalid rounding mode found");
}
APFloat::opStatus
unsigned int omsb; /* One, not zero, based MSB. */
int exponentChange;
- if(category != fcNormal)
+ if (category != fcNormal)
return opOK;
/* Before rounding normalize the exponent of fcNormal numbers. */
omsb = significandMSB() + 1;
- if(omsb) {
+ if (omsb) {
/* OMSB is numbered from 1. We want to place it in the integer
- bit numbered PRECISON if possible, with a compensating change in
+ bit numbered PRECISION if possible, with a compensating change in
the exponent. */
exponentChange = omsb - semantics->precision;
/* If the resulting exponent is too high, overflow according to
the rounding mode. */
- if(exponent + exponentChange > semantics->maxExponent)
+ if (exponent + exponentChange > semantics->maxExponent)
return handleOverflow(rounding_mode);
/* Subnormal numbers have exponent minExponent, and their MSB
is forced based on that. */
- if(exponent + exponentChange < semantics->minExponent)
+ if (exponent + exponentChange < semantics->minExponent)
exponentChange = semantics->minExponent - exponent;
/* Shifting left is easy as we don't lose precision. */
- if(exponentChange < 0) {
+ if (exponentChange < 0) {
assert(lost_fraction == lfExactlyZero);
shiftSignificandLeft(-exponentChange);
return opOK;
}
- if(exponentChange > 0) {
+ if (exponentChange > 0) {
lostFraction lf;
/* Shift right and capture any new lost fraction. */
lost_fraction = combineLostFractions(lf, lost_fraction);
/* Keep OMSB up-to-date. */
- if(omsb > (unsigned) exponentChange)
+ if (omsb > (unsigned) exponentChange)
omsb -= exponentChange;
else
omsb = 0;
/* As specified in IEEE 754, since we do not trap we do not report
underflow for exact results. */
- if(lost_fraction == lfExactlyZero) {
+ if (lost_fraction == lfExactlyZero) {
/* Canonicalize zeroes. */
- if(omsb == 0)
+ if (omsb == 0)
category = fcZero;
return opOK;
}
/* Increment the significand if we're rounding away from zero. */
- if(roundAwayFromZero(rounding_mode, lost_fraction, 0)) {
- if(omsb == 0)
+ if (roundAwayFromZero(rounding_mode, lost_fraction, 0)) {
+ if (omsb == 0)
exponent = semantics->minExponent;
incrementSignificand();
omsb = significandMSB() + 1;
/* Did the significand increment overflow? */
- if(omsb == (unsigned) semantics->precision + 1) {
+ if (omsb == (unsigned) semantics->precision + 1) {
/* Renormalize by incrementing the exponent and shifting our
significand right one. However if we already have the
maximum exponent we overflow to infinity. */
- if(exponent == semantics->maxExponent) {
+ if (exponent == semantics->maxExponent) {
category = fcInfinity;
return (opStatus) (opOverflow | opInexact);
/* The normal case - we were and are not denormal, and any
significand increment above didn't overflow. */
- if(omsb == semantics->precision)
+ if (omsb == semantics->precision)
return opInexact;
/* We have a non-zero denormal. */
assert(omsb < semantics->precision);
/* Canonicalize zeroes. */
- if(omsb == 0)
+ if (omsb == 0)
category = fcZero;
/* The fcZero case is a denormal that underflowed to zero. */
APFloat::opStatus
APFloat::addOrSubtractSpecials(const APFloat &rhs, bool subtract)
{
- switch(convolve(category, rhs.category)) {
+ switch (convolve(category, rhs.category)) {
default:
- assert(0);
+ llvm_unreachable(0);
case convolve(fcNaN, fcZero):
case convolve(fcNaN, fcNormal):
case convolve(fcInfinity, fcInfinity):
/* Differently signed infinities can only be validly
subtracted. */
- if(sign ^ rhs.sign != subtract) {
- category = fcNaN;
- // Arbitrary but deterministic value for significand
- APInt::tcSet(significandParts(), ~0U, partCount());
+ if (((sign ^ rhs.sign)!=0) != subtract) {
+ makeNaN();
return opInvalidOp;
}
/* Determine if the operation on the absolute values is effectively
an addition or subtraction. */
- subtract ^= (sign ^ rhs.sign);
+ subtract ^= (sign ^ rhs.sign) ? true : false;
/* Are we bigger exponent-wise than the RHS? */
bits = exponent - rhs.exponent;
/* Subtraction is more subtle than one might naively expect. */
- if(subtract) {
+ if (subtract) {
APFloat temp_rhs(rhs);
bool reverse;
/* Invert the lost fraction - it was on the RHS and
subtracted. */
- if(lost_fraction == lfLessThanHalf)
+ if (lost_fraction == lfLessThanHalf)
lost_fraction = lfMoreThanHalf;
- else if(lost_fraction == lfMoreThanHalf)
+ else if (lost_fraction == lfMoreThanHalf)
lost_fraction = lfLessThanHalf;
/* The code above is intended to ensure that no borrow is
necessary. */
assert(!carry);
+ (void)carry;
} else {
- if(bits > 0) {
+ if (bits > 0) {
APFloat temp_rhs(rhs);
lost_fraction = temp_rhs.shiftSignificandRight(bits);
/* We have a guard bit; generating a carry cannot happen. */
assert(!carry);
+ (void)carry;
}
return lost_fraction;
APFloat::opStatus
APFloat::multiplySpecials(const APFloat &rhs)
{
- switch(convolve(category, rhs.category)) {
+ switch (convolve(category, rhs.category)) {
default:
- assert(0);
+ llvm_unreachable(0);
case convolve(fcNaN, fcZero):
case convolve(fcNaN, fcNormal):
case convolve(fcZero, fcInfinity):
case convolve(fcInfinity, fcZero):
- category = fcNaN;
- // Arbitrary but deterministic value for significand
- APInt::tcSet(significandParts(), ~0U, partCount());
+ makeNaN();
return opInvalidOp;
case convolve(fcNormal, fcNormal):
APFloat::opStatus
APFloat::divideSpecials(const APFloat &rhs)
{
- switch(convolve(category, rhs.category)) {
+ switch (convolve(category, rhs.category)) {
default:
- assert(0);
+ llvm_unreachable(0);
case convolve(fcNaN, fcZero):
case convolve(fcNaN, fcNormal):
case convolve(fcInfinity, fcInfinity):
case convolve(fcZero, fcZero):
+ makeNaN();
+ return opInvalidOp;
+
+ case convolve(fcNormal, fcNormal):
+ return opOK;
+ }
+}
+
+APFloat::opStatus
+APFloat::modSpecials(const APFloat &rhs)
+{
+ switch (convolve(category, rhs.category)) {
+ default:
+ llvm_unreachable(0);
+
+ case convolve(fcNaN, fcZero):
+ case convolve(fcNaN, fcNormal):
+ case convolve(fcNaN, fcInfinity):
+ case convolve(fcNaN, fcNaN):
+ case convolve(fcZero, fcInfinity):
+ case convolve(fcZero, fcNormal):
+ case convolve(fcNormal, fcInfinity):
+ return opOK;
+
+ case convolve(fcZero, fcNaN):
+ case convolve(fcNormal, fcNaN):
+ case convolve(fcInfinity, fcNaN):
category = fcNaN;
- // Arbitrary but deterministic value for significand
- APInt::tcSet(significandParts(), ~0U, partCount());
+ copySignificand(rhs);
+ return opOK;
+
+ case convolve(fcNormal, fcZero):
+ case convolve(fcInfinity, fcZero):
+ case convolve(fcInfinity, fcNormal):
+ case convolve(fcInfinity, fcInfinity):
+ case convolve(fcZero, fcZero):
+ makeNaN();
return opInvalidOp;
case convolve(fcNormal, fcNormal):
{
opStatus fs;
+ assertArithmeticOK(*semantics);
+
fs = addOrSubtractSpecials(rhs, subtract);
/* This return code means it was not a simple case. */
- if(fs == opDivByZero) {
+ if (fs == opDivByZero) {
lostFraction lost_fraction;
lost_fraction = addOrSubtractSignificand(rhs, subtract);
/* If two numbers add (exactly) to zero, IEEE 754 decrees it is a
positive zero unless rounding to minus infinity, except that
adding two like-signed zeroes gives that zero. */
- if(category == fcZero) {
- if(rhs.category != fcZero || (sign == rhs.sign) == subtract)
+ if (category == fcZero) {
+ if (rhs.category != fcZero || (sign == rhs.sign) == subtract)
sign = (rounding_mode == rmTowardNegative);
}
APFloat::opStatus
APFloat::add(const APFloat &rhs, roundingMode rounding_mode)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
return addOrSubtract(rhs, rounding_mode, false);
}
APFloat::opStatus
APFloat::subtract(const APFloat &rhs, roundingMode rounding_mode)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
return addOrSubtract(rhs, rounding_mode, true);
}
APFloat::opStatus
APFloat::multiply(const APFloat &rhs, roundingMode rounding_mode)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
opStatus fs;
+ assertArithmeticOK(*semantics);
sign ^= rhs.sign;
fs = multiplySpecials(rhs);
- if(category == fcNormal) {
+ if (category == fcNormal) {
lostFraction lost_fraction = multiplySignificand(rhs, 0);
fs = normalize(rounding_mode, lost_fraction);
- if(lost_fraction != lfExactlyZero)
+ if (lost_fraction != lfExactlyZero)
fs = (opStatus) (fs | opInexact);
}
APFloat::opStatus
APFloat::divide(const APFloat &rhs, roundingMode rounding_mode)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
opStatus fs;
+ assertArithmeticOK(*semantics);
sign ^= rhs.sign;
fs = divideSpecials(rhs);
- if(category == fcNormal) {
+ if (category == fcNormal) {
lostFraction lost_fraction = divideSignificand(rhs);
fs = normalize(rounding_mode, lost_fraction);
- if(lost_fraction != lfExactlyZero)
+ if (lost_fraction != lfExactlyZero)
fs = (opStatus) (fs | opInexact);
}
return fs;
}
-/* Normalized remainder. This is not currently doing TRT. */
+/* Normalized remainder. This is not currently correct in all cases. */
APFloat::opStatus
-APFloat::mod(const APFloat &rhs, roundingMode rounding_mode)
+APFloat::remainder(const APFloat &rhs)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
opStatus fs;
APFloat V = *this;
unsigned int origSign = sign;
+
+ assertArithmeticOK(*semantics);
fs = V.divide(rhs, rmNearestTiesToEven);
if (fs == opDivByZero)
return fs;
int parts = partCount();
integerPart *x = new integerPart[parts];
+ bool ignored;
fs = V.convertToInteger(x, parts * integerPartWidth, true,
- rmNearestTiesToEven);
+ rmNearestTiesToEven, &ignored);
if (fs==opInvalidOp)
return fs;
rmNearestTiesToEven);
assert(fs==opOK); // should always work
- fs = V.multiply(rhs, rounding_mode);
+ fs = V.multiply(rhs, rmNearestTiesToEven);
assert(fs==opOK || fs==opInexact); // should not overflow or underflow
- fs = subtract(V, rounding_mode);
+ fs = subtract(V, rmNearestTiesToEven);
assert(fs==opOK || fs==opInexact); // likewise
if (isZero())
return fs;
}
+/* Normalized llvm frem (C fmod).
+ This is not currently correct in all cases. */
+APFloat::opStatus
+APFloat::mod(const APFloat &rhs, roundingMode rounding_mode)
+{
+ opStatus fs;
+ assertArithmeticOK(*semantics);
+ fs = modSpecials(rhs);
+
+ if (category == fcNormal && rhs.category == fcNormal) {
+ APFloat V = *this;
+ unsigned int origSign = sign;
+
+ fs = V.divide(rhs, rmNearestTiesToEven);
+ if (fs == opDivByZero)
+ return fs;
+
+ int parts = partCount();
+ integerPart *x = new integerPart[parts];
+ bool ignored;
+ fs = V.convertToInteger(x, parts * integerPartWidth, true,
+ rmTowardZero, &ignored);
+ if (fs==opInvalidOp)
+ return fs;
+
+ fs = V.convertFromZeroExtendedInteger(x, parts * integerPartWidth, true,
+ rmNearestTiesToEven);
+ assert(fs==opOK); // should always work
+
+ fs = V.multiply(rhs, rounding_mode);
+ assert(fs==opOK || fs==opInexact); // should not overflow or underflow
+
+ fs = subtract(V, rounding_mode);
+ assert(fs==opOK || fs==opInexact); // likewise
+
+ if (isZero())
+ sign = origSign; // IEEE754 requires this
+ delete[] x;
+ }
+ return fs;
+}
+
/* Normalized fused-multiply-add. */
APFloat::opStatus
APFloat::fusedMultiplyAdd(const APFloat &multiplicand,
const APFloat &addend,
roundingMode rounding_mode)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
opStatus fs;
+ assertArithmeticOK(*semantics);
+
/* Post-multiplication sign, before addition. */
sign ^= multiplicand.sign;
/* If and only if all arguments are normal do we need to do an
extended-precision calculation. */
- if(category == fcNormal
- && multiplicand.category == fcNormal
- && addend.category == fcNormal) {
+ if (category == fcNormal &&
+ multiplicand.category == fcNormal &&
+ addend.category == fcNormal) {
lostFraction lost_fraction;
lost_fraction = multiplySignificand(multiplicand, &addend);
fs = normalize(rounding_mode, lost_fraction);
- if(lost_fraction != lfExactlyZero)
+ if (lost_fraction != lfExactlyZero)
fs = (opStatus) (fs | opInexact);
/* If two numbers add (exactly) to zero, IEEE 754 decrees it is a
positive zero unless rounding to minus infinity, except that
adding two like-signed zeroes gives that zero. */
- if(category == fcZero && sign != addend.sign)
+ if (category == fcZero && sign != addend.sign)
sign = (rounding_mode == rmTowardNegative);
} else {
fs = multiplySpecials(multiplicand);
If we need to do the addition we can do so with normal
precision. */
- if(fs == opOK)
+ if (fs == opOK)
fs = addOrSubtract(addend, rounding_mode, false);
}
APFloat::cmpResult
APFloat::compare(const APFloat &rhs) const
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
cmpResult result;
+ assertArithmeticOK(*semantics);
assert(semantics == rhs.semantics);
- switch(convolve(category, rhs.category)) {
+ switch (convolve(category, rhs.category)) {
default:
- assert(0);
+ llvm_unreachable(0);
case convolve(fcNaN, fcZero):
case convolve(fcNaN, fcNormal):
case convolve(fcInfinity, fcNormal):
case convolve(fcInfinity, fcZero):
case convolve(fcNormal, fcZero):
- if(sign)
+ if (sign)
return cmpLessThan;
else
return cmpGreaterThan;
case convolve(fcNormal, fcInfinity):
case convolve(fcZero, fcInfinity):
case convolve(fcZero, fcNormal):
- if(rhs.sign)
+ if (rhs.sign)
return cmpGreaterThan;
else
return cmpLessThan;
case convolve(fcInfinity, fcInfinity):
- if(sign == rhs.sign)
+ if (sign == rhs.sign)
return cmpEqual;
- else if(sign)
+ else if (sign)
return cmpLessThan;
else
return cmpGreaterThan;
}
/* Two normal numbers. Do they have the same sign? */
- if(sign != rhs.sign) {
- if(sign)
+ if (sign != rhs.sign) {
+ if (sign)
result = cmpLessThan;
else
result = cmpGreaterThan;
/* Compare absolute values; invert result if negative. */
result = compareAbsoluteValue(rhs);
- if(sign) {
- if(result == cmpLessThan)
+ if (sign) {
+ if (result == cmpLessThan)
result = cmpGreaterThan;
- else if(result == cmpGreaterThan)
+ else if (result == cmpGreaterThan)
result = cmpLessThan;
}
}
return result;
}
+/// APFloat::convert - convert a value of one floating point type to another.
+/// The return value corresponds to the IEEE754 exceptions. *losesInfo
+/// records whether the transformation lost information, i.e. whether
+/// converting the result back to the original type will produce the
+/// original value (this is almost the same as return value==fsOK, but there
+/// are edge cases where this is not so).
+
APFloat::opStatus
APFloat::convert(const fltSemantics &toSemantics,
- roundingMode rounding_mode)
+ roundingMode rounding_mode, bool *losesInfo)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
lostFraction lostFraction;
unsigned int newPartCount, oldPartCount;
opStatus fs;
+ int shift;
+ const fltSemantics &fromSemantics = *semantics;
+ assertArithmeticOK(fromSemantics);
+ assertArithmeticOK(toSemantics);
lostFraction = lfExactlyZero;
newPartCount = partCountForBits(toSemantics.precision + 1);
oldPartCount = partCount();
+ shift = toSemantics.precision - fromSemantics.precision;
+
+ bool X86SpecialNan = false;
+ if (&fromSemantics == &APFloat::x87DoubleExtended &&
+ &toSemantics != &APFloat::x87DoubleExtended && category == fcNaN &&
+ (!(*significandParts() & 0x8000000000000000ULL) ||
+ !(*significandParts() & 0x4000000000000000ULL))) {
+ // x86 has some unusual NaNs which cannot be represented in any other
+ // format; note them here.
+ X86SpecialNan = true;
+ }
- /* Handle storage complications. If our new form is wider,
- re-allocate our bit pattern into wider storage. If it is
- narrower, we ignore the excess parts, but if narrowing to a
- single part we need to free the old storage.
- Be careful not to reference significandParts for zeroes
- and infinities, since it aborts. */
+ // If this is a truncation, perform the shift before we narrow the storage.
+ if (shift < 0 && (category==fcNormal || category==fcNaN))
+ lostFraction = shiftRight(significandParts(), oldPartCount, -shift);
+
+ // Fix the storage so it can hold to new value.
if (newPartCount > oldPartCount) {
+ // The new type requires more storage; make it available.
integerPart *newParts;
newParts = new integerPart[newPartCount];
APInt::tcSet(newParts, 0, newPartCount);
APInt::tcAssign(newParts, significandParts(), oldPartCount);
freeSignificand();
significand.parts = newParts;
- } else if (newPartCount < oldPartCount) {
- /* Capture any lost fraction through truncation of parts so we get
- correct rounding whilst normalizing. */
- if (category==fcNormal)
- lostFraction = lostFractionThroughTruncation
- (significandParts(), oldPartCount, toSemantics.precision);
- if (newPartCount == 1) {
- integerPart newPart = 0;
- if (category==fcNormal || category==fcNaN)
- newPart = significandParts()[0];
- freeSignificand();
- significand.part = newPart;
- }
+ } else if (newPartCount == 1 && oldPartCount != 1) {
+ // Switch to built-in storage for a single part.
+ integerPart newPart = 0;
+ if (category==fcNormal || category==fcNaN)
+ newPart = significandParts()[0];
+ freeSignificand();
+ significand.part = newPart;
}
- if(category == fcNormal) {
- /* Re-interpret our bit-pattern. */
- exponent += toSemantics.precision - semantics->precision;
- semantics = &toSemantics;
+ // Now that we have the right storage, switch the semantics.
+ semantics = &toSemantics;
+
+ // If this is an extension, perform the shift now that the storage is
+ // available.
+ if (shift > 0 && (category==fcNormal || category==fcNaN))
+ APInt::tcShiftLeft(significandParts(), newPartCount, shift);
+
+ if (category == fcNormal) {
fs = normalize(rounding_mode, lostFraction);
+ *losesInfo = (fs != opOK);
} else if (category == fcNaN) {
- int shift = toSemantics.precision - semantics->precision;
- // No normalization here, just truncate
- if (shift>0)
- APInt::tcShiftLeft(significandParts(), newPartCount, shift);
- else if (shift < 0)
- APInt::tcShiftRight(significandParts(), newPartCount, -shift);
+ *losesInfo = lostFraction != lfExactlyZero || X86SpecialNan;
// gcc forces the Quiet bit on, which means (float)(double)(float_sNan)
// does not give you back the same bits. This is dubious, and we
// don't currently do it. You're really supposed to get
// an invalid operation signal at runtime, but nobody does that.
- semantics = &toSemantics;
fs = opOK;
} else {
- semantics = &toSemantics;
+ *losesInfo = false;
fs = opOK;
}
/* Convert a floating point number to an integer according to the
rounding mode. If the rounded integer value is out of range this
- returns an invalid operation exception. If the rounded value is in
+ returns an invalid operation exception and the contents of the
+ destination parts are unspecified. If the rounded value is in
range but the floating point number is not the exact integer, the C
standard doesn't require an inexact exception to be raised. IEEE
854 does require it so we do that.
Note that for conversions to integer type the C standard requires
round-to-zero to always be used. */
APFloat::opStatus
-APFloat::convertToInteger(integerPart *parts, unsigned int width,
- bool isSigned,
- roundingMode rounding_mode) const
+APFloat::convertToSignExtendedInteger(integerPart *parts, unsigned int width,
+ bool isSigned,
+ roundingMode rounding_mode,
+ bool *isExact) const
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
lostFraction lost_fraction;
- unsigned int msb, partsCount;
- int bits;
+ const integerPart *src;
+ unsigned int dstPartsCount, truncatedBits;
- partsCount = partCountForBits(width);
+ assertArithmeticOK(*semantics);
- /* Handle the three special cases first. We produce
- a deterministic result even for the Invalid cases. */
- if (category == fcNaN) {
- // Neither sign nor isSigned affects this.
- APInt::tcSet(parts, 0, partsCount);
- return opInvalidOp;
- }
- if (category == fcInfinity) {
- if (!sign && isSigned)
- APInt::tcSetLeastSignificantBits(parts, partsCount, width-1);
- else if (!sign && !isSigned)
- APInt::tcSetLeastSignificantBits(parts, partsCount, width);
- else if (sign && isSigned) {
- APInt::tcSetLeastSignificantBits(parts, partsCount, 1);
- APInt::tcShiftLeft(parts, partsCount, width-1);
- } else // sign && !isSigned
- APInt::tcSet(parts, 0, partsCount);
+ *isExact = false;
+
+ /* Handle the three special cases first. */
+ if (category == fcInfinity || category == fcNaN)
return opInvalidOp;
- }
+
+ dstPartsCount = partCountForBits(width);
+
if (category == fcZero) {
- APInt::tcSet(parts, 0, partsCount);
+ APInt::tcSet(parts, 0, dstPartsCount);
+ // Negative zero can't be represented as an int.
+ *isExact = !sign;
return opOK;
}
- /* Shift the bit pattern so the fraction is lost. */
- APFloat tmp(*this);
-
- bits = (int) semantics->precision - 1 - exponent;
+ src = significandParts();
- if(bits > 0) {
- lost_fraction = tmp.shiftSignificandRight(bits);
+ /* Step 1: place our absolute value, with any fraction truncated, in
+ the destination. */
+ if (exponent < 0) {
+ /* Our absolute value is less than one; truncate everything. */
+ APInt::tcSet(parts, 0, dstPartsCount);
+ /* For exponent -1 the integer bit represents .5, look at that.
+ For smaller exponents leftmost truncated bit is 0. */
+ truncatedBits = semantics->precision -1U - exponent;
} else {
- if (-bits >= semantics->precision) {
- // Unrepresentably large.
- if (!sign && isSigned)
- APInt::tcSetLeastSignificantBits(parts, partsCount, width-1);
- else if (!sign && !isSigned)
- APInt::tcSetLeastSignificantBits(parts, partsCount, width);
- else if (sign && isSigned) {
- APInt::tcSetLeastSignificantBits(parts, partsCount, 1);
- APInt::tcShiftLeft(parts, partsCount, width-1);
- } else // sign && !isSigned
- APInt::tcSet(parts, 0, partsCount);
- return (opStatus)(opOverflow | opInexact);
- }
- tmp.shiftSignificandLeft(-bits);
- lost_fraction = lfExactlyZero;
- }
-
- if(lost_fraction != lfExactlyZero
- && tmp.roundAwayFromZero(rounding_mode, lost_fraction, 0))
- tmp.incrementSignificand();
+ /* We want the most significant (exponent + 1) bits; the rest are
+ truncated. */
+ unsigned int bits = exponent + 1U;
- msb = tmp.significandMSB();
+ /* Hopelessly large in magnitude? */
+ if (bits > width)
+ return opInvalidOp;
- /* Negative numbers cannot be represented as unsigned. */
- if(!isSigned && tmp.sign && msb != -1U)
- return opInvalidOp;
+ if (bits < semantics->precision) {
+ /* We truncate (semantics->precision - bits) bits. */
+ truncatedBits = semantics->precision - bits;
+ APInt::tcExtract(parts, dstPartsCount, src, bits, truncatedBits);
+ } else {
+ /* We want at least as many bits as are available. */
+ APInt::tcExtract(parts, dstPartsCount, src, semantics->precision, 0);
+ APInt::tcShiftLeft(parts, dstPartsCount, bits - semantics->precision);
+ truncatedBits = 0;
+ }
+ }
- /* It takes exponent + 1 bits to represent the truncated floating
- point number without its sign. We lose a bit for the sign, but
- the maximally negative integer is a special case. */
- if(msb + 1 > width) /* !! Not same as msb >= width !! */
- return opInvalidOp;
+ /* Step 2: work out any lost fraction, and increment the absolute
+ value if we would round away from zero. */
+ if (truncatedBits) {
+ lost_fraction = lostFractionThroughTruncation(src, partCount(),
+ truncatedBits);
+ if (lost_fraction != lfExactlyZero &&
+ roundAwayFromZero(rounding_mode, lost_fraction, truncatedBits)) {
+ if (APInt::tcIncrement(parts, dstPartsCount))
+ return opInvalidOp; /* Overflow. */
+ }
+ } else {
+ lost_fraction = lfExactlyZero;
+ }
- if(isSigned && msb + 1 == width
- && (!tmp.sign || tmp.significandLSB() != msb))
- return opInvalidOp;
+ /* Step 3: check if we fit in the destination. */
+ unsigned int omsb = APInt::tcMSB(parts, dstPartsCount) + 1;
- APInt::tcAssign(parts, tmp.significandParts(), partsCount);
+ if (sign) {
+ if (!isSigned) {
+ /* Negative numbers cannot be represented as unsigned. */
+ if (omsb != 0)
+ return opInvalidOp;
+ } else {
+ /* It takes omsb bits to represent the unsigned integer value.
+ We lose a bit for the sign, but care is needed as the
+ maximally negative integer is a special case. */
+ if (omsb == width && APInt::tcLSB(parts, dstPartsCount) + 1 != omsb)
+ return opInvalidOp;
+
+ /* This case can happen because of rounding. */
+ if (omsb > width)
+ return opInvalidOp;
+ }
- if(tmp.sign)
- APInt::tcNegate(parts, partsCount);
+ APInt::tcNegate (parts, dstPartsCount);
+ } else {
+ if (omsb >= width + !isSigned)
+ return opInvalidOp;
+ }
- if(lost_fraction == lfExactlyZero)
+ if (lost_fraction == lfExactlyZero) {
+ *isExact = true;
return opOK;
- else
+ } else
return opInexact;
}
-/* Convert an unsigned integer SRC to a floating point number,
- rounding according to ROUNDING_MODE. The sign of the floating
- point number is not modified. */
+/* Same as convertToSignExtendedInteger, except we provide
+ deterministic values in case of an invalid operation exception,
+ namely zero for NaNs and the minimal or maximal value respectively
+ for underflow or overflow.
+ The *isExact output tells whether the result is exact, in the sense
+ that converting it back to the original floating point type produces
+ the original value. This is almost equivalent to result==opOK,
+ except for negative zeroes.
+*/
APFloat::opStatus
-APFloat::convertFromUnsignedParts(const integerPart *src,
- unsigned int srcCount,
- roundingMode rounding_mode)
+APFloat::convertToInteger(integerPart *parts, unsigned int width,
+ bool isSigned,
+ roundingMode rounding_mode, bool *isExact) const
+{
+ opStatus fs;
+
+ fs = convertToSignExtendedInteger(parts, width, isSigned, rounding_mode,
+ isExact);
+
+ if (fs == opInvalidOp) {
+ unsigned int bits, dstPartsCount;
+
+ dstPartsCount = partCountForBits(width);
+
+ if (category == fcNaN)
+ bits = 0;
+ else if (sign)
+ bits = isSigned;
+ else
+ bits = width - isSigned;
+
+ APInt::tcSetLeastSignificantBits(parts, dstPartsCount, bits);
+ if (sign && isSigned)
+ APInt::tcShiftLeft(parts, dstPartsCount, width - 1);
+ }
+
+ return fs;
+}
+
+/* Same as convertToInteger(integerPart*, ...), except the result is returned in
+ an APSInt, whose initial bit-width and signed-ness are used to determine the
+ precision of the conversion.
+ */
+APFloat::opStatus
+APFloat::convertToInteger(APSInt &result,
+ roundingMode rounding_mode, bool *isExact) const
+{
+ unsigned bitWidth = result.getBitWidth();
+ SmallVector<uint64_t, 4> parts(result.getNumWords());
+ opStatus status = convertToInteger(
+ parts.data(), bitWidth, result.isSigned(), rounding_mode, isExact);
+ // Keeps the original signed-ness.
+ result = APInt(bitWidth, parts);
+ return status;
+}
+
+/* Convert an unsigned integer SRC to a floating point number,
+ rounding according to ROUNDING_MODE. The sign of the floating
+ point number is not modified. */
+APFloat::opStatus
+APFloat::convertFromUnsignedParts(const integerPart *src,
+ unsigned int srcCount,
+ roundingMode rounding_mode)
{
unsigned int omsb, precision, dstCount;
integerPart *dst;
lostFraction lost_fraction;
+ assertArithmeticOK(*semantics);
category = fcNormal;
omsb = APInt::tcMSB(src, srcCount) + 1;
dst = significandParts();
dstCount = partCount();
precision = semantics->precision;
- /* We want the most significant PRECISON bits of SRC. There may not
+ /* We want the most significant PRECISION bits of SRC. There may not
be that many; extract what we can. */
if (precision <= omsb) {
exponent = omsb - 1;
return normalize(rounding_mode, lost_fraction);
}
+APFloat::opStatus
+APFloat::convertFromAPInt(const APInt &Val,
+ bool isSigned,
+ roundingMode rounding_mode)
+{
+ unsigned int partCount = Val.getNumWords();
+ APInt api = Val;
+
+ sign = false;
+ if (isSigned && api.isNegative()) {
+ sign = true;
+ api = -api;
+ }
+
+ return convertFromUnsignedParts(api.getRawData(), partCount, rounding_mode);
+}
+
/* Convert a two's complement integer SRC to a floating point number,
rounding according to ROUNDING_MODE. ISSIGNED is true if the
integer is signed, in which case it must be sign-extended. */
bool isSigned,
roundingMode rounding_mode)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
opStatus status;
- if (isSigned
- && APInt::tcExtractBit(src, srcCount * integerPartWidth - 1)) {
+ assertArithmeticOK(*semantics);
+ if (isSigned &&
+ APInt::tcExtractBit(src, srcCount * integerPartWidth - 1)) {
integerPart *copy;
/* If we're signed and negative negate a copy. */
unsigned int width, bool isSigned,
roundingMode rounding_mode)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
unsigned int partCount = partCountForBits(width);
- APInt api = APInt(width, partCount, parts);
+ APInt api = APInt(width, makeArrayRef(parts, partCount));
sign = false;
- if(isSigned && APInt::tcExtractBit(parts, width - 1)) {
+ if (isSigned && APInt::tcExtractBit(parts, width - 1)) {
sign = true;
api = -api;
}
}
APFloat::opStatus
-APFloat::convertFromHexadecimalString(const char *p,
- roundingMode rounding_mode)
+APFloat::convertFromHexadecimalString(StringRef s, roundingMode rounding_mode)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
- lostFraction lost_fraction;
+ lostFraction lost_fraction = lfExactlyZero;
integerPart *significand;
unsigned int bitPos, partsCount;
- const char *dot, *firstSignificantDigit;
+ StringRef::iterator dot, firstSignificantDigit;
zeroSignificand();
exponent = 0;
bitPos = partsCount * integerPartWidth;
/* Skip leading zeroes and any (hexa)decimal point. */
- p = skipLeadingZeroesAndAnyDot(p, &dot);
+ StringRef::iterator begin = s.begin();
+ StringRef::iterator end = s.end();
+ StringRef::iterator p = skipLeadingZeroesAndAnyDot(begin, end, &dot);
firstSignificantDigit = p;
- for(;;) {
+ for (; p != end;) {
integerPart hex_value;
- if(*p == '.') {
- assert(dot == 0);
+ if (*p == '.') {
+ assert(dot == end && "String contains multiple dots");
dot = p++;
+ if (p == end) {
+ break;
+ }
}
hex_value = hexDigitValue(*p);
- if(hex_value == -1U) {
- lost_fraction = lfExactlyZero;
+ if (hex_value == -1U) {
break;
}
p++;
- /* Store the number whilst 4-bit nibbles remain. */
- if(bitPos) {
- bitPos -= 4;
- hex_value <<= bitPos % integerPartWidth;
- significand[bitPos / integerPartWidth] |= hex_value;
- } else {
- lost_fraction = trailingHexadecimalFraction(p, hex_value);
- while(hexDigitValue(*p) != -1U)
- p++;
+ if (p == end) {
break;
+ } else {
+ /* Store the number whilst 4-bit nibbles remain. */
+ if (bitPos) {
+ bitPos -= 4;
+ hex_value <<= bitPos % integerPartWidth;
+ significand[bitPos / integerPartWidth] |= hex_value;
+ } else {
+ lost_fraction = trailingHexadecimalFraction(p, end, hex_value);
+ while (p != end && hexDigitValue(*p) != -1U)
+ p++;
+ break;
+ }
}
}
/* Hex floats require an exponent but not a hexadecimal point. */
- assert(*p == 'p' || *p == 'P');
+ assert(p != end && "Hex strings require an exponent");
+ assert((*p == 'p' || *p == 'P') && "Invalid character in significand");
+ assert(p != begin && "Significand has no digits");
+ assert((dot == end || p - begin != 1) && "Significand has no digits");
/* Ignore the exponent if we are zero. */
- if(p != firstSignificantDigit) {
+ if (p != firstSignificantDigit) {
int expAdjustment;
/* Implicit hexadecimal point? */
- if(!dot)
+ if (dot == end)
dot = p;
/* Calculate the exponent adjustment implicit in the number of
significant digits. */
- expAdjustment = dot - firstSignificantDigit;
- if(expAdjustment < 0)
+ expAdjustment = static_cast<int>(dot - firstSignificantDigit);
+ if (expAdjustment < 0)
expAdjustment++;
expAdjustment = expAdjustment * 4 - 1;
expAdjustment -= partsCount * integerPartWidth;
/* Adjust for the given exponent. */
- exponent = totalExponent(p, expAdjustment);
+ exponent = totalExponent(p + 1, end, expAdjustment);
}
return normalize(rounding_mode, lost_fraction);
roundingMode rounding_mode)
{
unsigned int parts, pow5PartCount;
- fltSemantics calcSemantics = { 32767, -32767, 0 };
+ fltSemantics calcSemantics = { 32767, -32767, 0, true };
integerPart pow5Parts[maxPowerOfFiveParts];
bool isNearest;
- isNearest = (rounding_mode == rmNearestTiesToEven
- || rounding_mode == rmNearestTiesToAway);
+ isNearest = (rounding_mode == rmNearestTiesToEven ||
+ rounding_mode == rmNearestTiesToAway);
parts = partCountForBits(semantics->precision + 11);
decSig.exponent += exp;
lostFraction calcLostFraction;
- integerPart HUerr, HUdistance, powHUerr;
+ integerPart HUerr, HUdistance;
+ unsigned int powHUerr;
if (exp >= 0) {
/* multiplySignificand leaves the precision-th bit set to 1. */
excessPrecision = calcSemantics.precision;
}
/* Extra half-ulp lost in reciprocal of exponent. */
- powHUerr = (powStatus == opOK && calcLostFraction == lfExactlyZero) ? 0: 2;
+ powHUerr = (powStatus == opOK && calcLostFraction == lfExactlyZero) ? 0:2;
}
/* Both multiplySignificand and divideSignificand return the
result with the integer bit set. */
- assert (APInt::tcExtractBit
- (decSig.significandParts(), calcSemantics.precision - 1) == 1);
+ assert(APInt::tcExtractBit
+ (decSig.significandParts(), calcSemantics.precision - 1) == 1);
HUerr = HUerrBound(calcLostFraction != lfExactlyZero, sigStatus != opOK,
powHUerr);
}
APFloat::opStatus
-APFloat::convertFromDecimalString(const char *p, roundingMode rounding_mode)
+APFloat::convertFromDecimalString(StringRef str, roundingMode rounding_mode)
{
- const char *dot, *firstSignificantDigit;
- integerPart val, maxVal, decValue;
+ decimalInfo D;
opStatus fs;
- /* Skip leading zeroes and any decimal point. */
- p = skipLeadingZeroesAndAnyDot(p, &dot);
- firstSignificantDigit = p;
-
- /* The maximum number that can be multiplied by ten with any digit
- added without overflowing an integerPart. */
- maxVal = (~ (integerPart) 0 - 9) / 10;
-
- val = 0;
- while (val <= maxVal) {
- if (*p == '.') {
- assert(dot == 0);
- dot = p++;
- }
-
- decValue = digitValue(*p);
- if (decValue == -1U)
- break;
- p++;
- val = val * 10 + decValue;
- }
-
- integerPart *decSignificand;
- unsigned int partCount, maxPartCount;
-
- partCount = 0;
- maxPartCount = 4;
- decSignificand = new integerPart[maxPartCount];
- decSignificand[partCount++] = val;
+ /* Scan the text. */
+ StringRef::iterator p = str.begin();
+ interpretDecimal(p, str.end(), &D);
- /* Now continue to do single-part arithmetic for as long as we can.
- Then do a part multiplication, and repeat. */
- while (decValue != -1U) {
- integerPart multiplier;
+ /* Handle the quick cases. First the case of no significant digits,
+ i.e. zero, and then exponents that are obviously too large or too
+ small. Writing L for log 10 / log 2, a number d.ddddd*10^exp
+ definitely overflows if
- val = 0;
- multiplier = 1;
-
- while (multiplier <= maxVal) {
- if (*p == '.') {
- assert(dot == 0);
- dot = p++;
- }
+ (exp - 1) * L >= maxExponent
- decValue = digitValue(*p);
- if (decValue == -1U)
- break;
- p++;
- multiplier *= 10;
- val = val * 10 + decValue;
- }
+ and definitely underflows to zero where
- if (partCount == maxPartCount) {
- integerPart *newDecSignificand;
- newDecSignificand = new integerPart[maxPartCount = partCount * 2];
- APInt::tcAssign(newDecSignificand, decSignificand, partCount);
- delete [] decSignificand;
- decSignificand = newDecSignificand;
- }
+ (exp + 1) * L <= minExponent - precision
- APInt::tcMultiplyPart(decSignificand, decSignificand, multiplier, val,
- partCount, partCount + 1, false);
+ With integer arithmetic the tightest bounds for L are
- /* If we used another part (likely), increase the count. */
- if (decSignificand[partCount] != 0)
- partCount++;
- }
+ 93/28 < L < 196/59 [ numerator <= 256 ]
+ 42039/12655 < L < 28738/8651 [ numerator <= 65536 ]
+ */
- /* Now decSignificand contains the supplied significand ignoring the
- decimal point. Figure out our effective exponent, which is the
- specified exponent adjusted for any decimal point. */
-
- if (p == firstSignificantDigit) {
- /* Ignore the exponent if we are zero - we cannot overflow. */
+ if (decDigitValue(*D.firstSigDigit) >= 10U) {
category = fcZero;
fs = opOK;
- } else {
- int decimalExponent;
- if (dot)
- decimalExponent = dot + 1 - p;
- else
- decimalExponent = 0;
-
- /* Add the given exponent. */
- if (*p == 'e' || *p == 'E')
- decimalExponent = totalExponent(p, decimalExponent);
+ /* Check whether the normalized exponent is high enough to overflow
+ max during the log-rebasing in the max-exponent check below. */
+ } else if (D.normalizedExponent - 1 > INT_MAX / 42039) {
+ fs = handleOverflow(rounding_mode);
+
+ /* If it wasn't, then it also wasn't high enough to overflow max
+ during the log-rebasing in the min-exponent check. Check that it
+ won't overflow min in either check, then perform the min-exponent
+ check. */
+ } else if (D.normalizedExponent - 1 < INT_MIN / 42039 ||
+ (D.normalizedExponent + 1) * 28738 <=
+ 8651 * (semantics->minExponent - (int) semantics->precision)) {
+ /* Underflow to zero and round. */
+ zeroSignificand();
+ fs = normalize(rounding_mode, lfLessThanHalf);
+
+ /* We can finally safely perform the max-exponent check. */
+ } else if ((D.normalizedExponent - 1) * 42039
+ >= 12655 * semantics->maxExponent) {
+ /* Overflow and round. */
+ fs = handleOverflow(rounding_mode);
+ } else {
+ integerPart *decSignificand;
+ unsigned int partCount;
+
+ /* A tight upper bound on number of bits required to hold an
+ N-digit decimal integer is N * 196 / 59. Allocate enough space
+ to hold the full significand, and an extra part required by
+ tcMultiplyPart. */
+ partCount = static_cast<unsigned int>(D.lastSigDigit - D.firstSigDigit) + 1;
+ partCount = partCountForBits(1 + 196 * partCount / 59);
+ decSignificand = new integerPart[partCount + 1];
+ partCount = 0;
+
+ /* Convert to binary efficiently - we do almost all multiplication
+ in an integerPart. When this would overflow do we do a single
+ bignum multiplication, and then revert again to multiplication
+ in an integerPart. */
+ do {
+ integerPart decValue, val, multiplier;
+
+ val = 0;
+ multiplier = 1;
+
+ do {
+ if (*p == '.') {
+ p++;
+ if (p == str.end()) {
+ break;
+ }
+ }
+ decValue = decDigitValue(*p++);
+ assert(decValue < 10U && "Invalid character in significand");
+ multiplier *= 10;
+ val = val * 10 + decValue;
+ /* The maximum number that can be multiplied by ten with any
+ digit added without overflowing an integerPart. */
+ } while (p <= D.lastSigDigit && multiplier <= (~ (integerPart) 0 - 9) / 10);
+
+ /* Multiply out the current part. */
+ APInt::tcMultiplyPart(decSignificand, decSignificand, multiplier, val,
+ partCount, partCount + 1, false);
+
+ /* If we used another part (likely but not guaranteed), increase
+ the count. */
+ if (decSignificand[partCount])
+ partCount++;
+ } while (p <= D.lastSigDigit);
category = fcNormal;
fs = roundSignificandWithExponent(decSignificand, partCount,
- decimalExponent, rounding_mode);
- }
+ D.exponent, rounding_mode);
- delete [] decSignificand;
+ delete [] decSignificand;
+ }
return fs;
}
APFloat::opStatus
-APFloat::convertFromString(const char *p, roundingMode rounding_mode)
+APFloat::convertFromString(StringRef str, roundingMode rounding_mode)
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
+ assertArithmeticOK(*semantics);
+ assert(!str.empty() && "Invalid string length");
+
/* Handle a leading minus sign. */
- if(*p == '-')
- sign = 1, p++;
- else
- sign = 0;
+ StringRef::iterator p = str.begin();
+ size_t slen = str.size();
+ sign = *p == '-' ? 1 : 0;
+ if (*p == '-' || *p == '+') {
+ p++;
+ slen--;
+ assert(slen && "String has no digits");
+ }
- if(p[0] == '0' && (p[1] == 'x' || p[1] == 'X'))
- return convertFromHexadecimalString(p + 2, rounding_mode);
- else
- return convertFromDecimalString(p, rounding_mode);
+ if (slen >= 2 && p[0] == '0' && (p[1] == 'x' || p[1] == 'X')) {
+ assert(slen - 2 && "Invalid string");
+ return convertFromHexadecimalString(StringRef(p + 2, slen - 2),
+ rounding_mode);
+ }
+
+ return convertFromDecimalString(StringRef(p, slen), rounding_mode);
}
/* Write out a hexadecimal representation of the floating point value
APFloat::convertToHexString(char *dst, unsigned int hexDigits,
bool upperCase, roundingMode rounding_mode) const
{
- assert(semantics != (const llvm::fltSemantics* const)&PPCDoubleDouble &&
- "Compile-time arithmetic on PPC long double not supported yet");
char *p;
+ assertArithmeticOK(*semantics);
+
p = dst;
if (sign)
*dst++ = '-';
*dst = 0;
- return dst - p;
+ return static_cast<unsigned int>(dst - p);
}
/* Does the hard work of outputting the correctly rounded hexadecimal
q--;
*q = hexDigitChars[hexDigitValue (*q) + 1];
} while (*q == '0');
- assert (q >= p);
+ assert(q >= p);
} else {
/* Add trailing zeroes. */
memset (dst, '0', outputDigits);
return writeSignedDecimal (dst, exponent);
}
-// For good performance it is desirable for different APFloats
-// to produce different integers.
-uint32_t
-APFloat::getHashValue() const
-{
- if (category==fcZero) return sign<<8 | semantics->precision ;
- else if (category==fcInfinity) return sign<<9 | semantics->precision;
- else if (category==fcNaN) return 1<<10 | semantics->precision;
- else {
- uint32_t hash = sign<<11 | semantics->precision | exponent<<12;
- const integerPart* p = significandParts();
- for (int i=partCount(); i>0; i--, p++)
- hash ^= ((uint32_t)*p) ^ (*p)>>32;
- return hash;
- }
+hash_code llvm::hash_value(const APFloat &Arg) {
+ if (Arg.category != APFloat::fcNormal)
+ return hash_combine((uint8_t)Arg.category,
+ // NaN has no sign, fix it at zero.
+ Arg.isNaN() ? (uint8_t)0 : (uint8_t)Arg.sign,
+ Arg.semantics->precision);
+
+ // Normal floats need their exponent and significand hashed.
+ return hash_combine((uint8_t)Arg.category, (uint8_t)Arg.sign,
+ Arg.semantics->precision, Arg.exponent,
+ hash_combine_range(
+ Arg.significandParts(),
+ Arg.significandParts() + Arg.partCount()));
}
// Conversion from APFloat to/from host float/double. It may eventually be
APInt
APFloat::convertF80LongDoubleAPFloatToAPInt() const
{
- assert(semantics == (const llvm::fltSemantics* const)&x87DoubleExtended);
- assert (partCount()==2);
+ assert(semantics == (const llvm::fltSemantics*)&x87DoubleExtended);
+ assert(partCount()==2);
uint64_t myexponent, mysignificand;
}
uint64_t words[2];
- words[0] = (((uint64_t)sign & 1) << 63) |
- ((myexponent & 0x7fff) << 48) |
- ((mysignificand >>16) & 0xffffffffffffLL);
- words[1] = mysignificand & 0xffff;
- return APInt(80, 2, words);
+ words[0] = mysignificand;
+ words[1] = ((uint64_t)(sign & 1) << 15) |
+ (myexponent & 0x7fffLL);
+ return APInt(80, words);
}
APInt
APFloat::convertPPCDoubleDoubleAPFloatToAPInt() const
{
- assert(semantics == (const llvm::fltSemantics* const)&PPCDoubleDouble);
- assert (partCount()==2);
+ assert(semantics == (const llvm::fltSemantics*)&PPCDoubleDouble);
+ assert(partCount()==2);
uint64_t myexponent, mysignificand, myexponent2, mysignificand2;
}
uint64_t words[2];
- words[0] = (((uint64_t)sign & 1) << 63) |
+ words[0] = ((uint64_t)(sign & 1) << 63) |
((myexponent & 0x7ff) << 52) |
(mysignificand & 0xfffffffffffffLL);
- words[1] = (((uint64_t)sign2 & 1) << 63) |
+ words[1] = ((uint64_t)(sign2 & 1) << 63) |
((myexponent2 & 0x7ff) << 52) |
(mysignificand2 & 0xfffffffffffffLL);
- return APInt(128, 2, words);
+ return APInt(128, words);
+}
+
+APInt
+APFloat::convertQuadrupleAPFloatToAPInt() const
+{
+ assert(semantics == (const llvm::fltSemantics*)&IEEEquad);
+ assert(partCount()==2);
+
+ uint64_t myexponent, mysignificand, mysignificand2;
+
+ if (category==fcNormal) {
+ myexponent = exponent+16383; //bias
+ mysignificand = significandParts()[0];
+ mysignificand2 = significandParts()[1];
+ if (myexponent==1 && !(mysignificand2 & 0x1000000000000LL))
+ myexponent = 0; // denormal
+ } else if (category==fcZero) {
+ myexponent = 0;
+ mysignificand = mysignificand2 = 0;
+ } else if (category==fcInfinity) {
+ myexponent = 0x7fff;
+ mysignificand = mysignificand2 = 0;
+ } else {
+ assert(category == fcNaN && "Unknown category!");
+ myexponent = 0x7fff;
+ mysignificand = significandParts()[0];
+ mysignificand2 = significandParts()[1];
+ }
+
+ uint64_t words[2];
+ words[0] = mysignificand;
+ words[1] = ((uint64_t)(sign & 1) << 63) |
+ ((myexponent & 0x7fff) << 48) |
+ (mysignificand2 & 0xffffffffffffLL);
+
+ return APInt(128, words);
}
APInt
APFloat::convertDoubleAPFloatToAPInt() const
{
assert(semantics == (const llvm::fltSemantics*)&IEEEdouble);
- assert (partCount()==1);
+ assert(partCount()==1);
uint64_t myexponent, mysignificand;
mysignificand = *significandParts();
}
- return APInt(64, (((((uint64_t)sign & 1) << 63) |
+ return APInt(64, ((((uint64_t)(sign & 1) << 63) |
((myexponent & 0x7ff) << 52) |
(mysignificand & 0xfffffffffffffLL))));
}
APFloat::convertFloatAPFloatToAPInt() const
{
assert(semantics == (const llvm::fltSemantics*)&IEEEsingle);
- assert (partCount()==1);
+ assert(partCount()==1);
uint32_t myexponent, mysignificand;
if (category==fcNormal) {
myexponent = exponent+127; //bias
- mysignificand = *significandParts();
- if (myexponent == 1 && !(mysignificand & 0x400000))
+ mysignificand = (uint32_t)*significandParts();
+ if (myexponent == 1 && !(mysignificand & 0x800000))
myexponent = 0; // denormal
} else if (category==fcZero) {
myexponent = 0;
} else {
assert(category == fcNaN && "Unknown category!");
myexponent = 0xff;
- mysignificand = *significandParts();
+ mysignificand = (uint32_t)*significandParts();
}
return APInt(32, (((sign&1) << 31) | ((myexponent&0xff) << 23) |
(mysignificand & 0x7fffff)));
}
+APInt
+APFloat::convertHalfAPFloatToAPInt() const
+{
+ assert(semantics == (const llvm::fltSemantics*)&IEEEhalf);
+ assert(partCount()==1);
+
+ uint32_t myexponent, mysignificand;
+
+ if (category==fcNormal) {
+ myexponent = exponent+15; //bias
+ mysignificand = (uint32_t)*significandParts();
+ if (myexponent == 1 && !(mysignificand & 0x400))
+ myexponent = 0; // denormal
+ } else if (category==fcZero) {
+ myexponent = 0;
+ mysignificand = 0;
+ } else if (category==fcInfinity) {
+ myexponent = 0x1f;
+ mysignificand = 0;
+ } else {
+ assert(category == fcNaN && "Unknown category!");
+ myexponent = 0x1f;
+ mysignificand = (uint32_t)*significandParts();
+ }
+
+ return APInt(16, (((sign&1) << 15) | ((myexponent&0x1f) << 10) |
+ (mysignificand & 0x3ff)));
+}
+
// This function creates an APInt that is just a bit map of the floating
// point constant as it would appear in memory. It is not a conversion,
// and treating the result as a normal integer is unlikely to be useful.
APInt
-APFloat::convertToAPInt() const
+APFloat::bitcastToAPInt() const
{
- if (semantics == (const llvm::fltSemantics* const)&IEEEsingle)
+ if (semantics == (const llvm::fltSemantics*)&IEEEhalf)
+ return convertHalfAPFloatToAPInt();
+
+ if (semantics == (const llvm::fltSemantics*)&IEEEsingle)
return convertFloatAPFloatToAPInt();
-
- if (semantics == (const llvm::fltSemantics* const)&IEEEdouble)
+
+ if (semantics == (const llvm::fltSemantics*)&IEEEdouble)
return convertDoubleAPFloatToAPInt();
- if (semantics == (const llvm::fltSemantics* const)&PPCDoubleDouble)
+ if (semantics == (const llvm::fltSemantics*)&IEEEquad)
+ return convertQuadrupleAPFloatToAPInt();
+
+ if (semantics == (const llvm::fltSemantics*)&PPCDoubleDouble)
return convertPPCDoubleDoubleAPFloatToAPInt();
- assert(semantics == (const llvm::fltSemantics* const)&x87DoubleExtended &&
+ assert(semantics == (const llvm::fltSemantics*)&x87DoubleExtended &&
"unknown format!");
return convertF80LongDoubleAPFloatToAPInt();
}
float
APFloat::convertToFloat() const
{
- assert(semantics == (const llvm::fltSemantics* const)&IEEEsingle);
- APInt api = convertToAPInt();
+ assert(semantics == (const llvm::fltSemantics*)&IEEEsingle &&
+ "Float semantics are not IEEEsingle");
+ APInt api = bitcastToAPInt();
return api.bitsToFloat();
}
double
APFloat::convertToDouble() const
{
- assert(semantics == (const llvm::fltSemantics* const)&IEEEdouble);
- APInt api = convertToAPInt();
+ assert(semantics == (const llvm::fltSemantics*)&IEEEdouble &&
+ "Float semantics are not IEEEdouble");
+ APInt api = bitcastToAPInt();
return api.bitsToDouble();
}
-/// Integer bit is explicit in this format. Current Intel book does not
-/// define meaning of:
-/// exponent = all 1's, integer bit not set.
-/// exponent = 0, integer bit set. (formerly "psuedodenormals")
-/// exponent!=0 nor all 1's, integer bit not set. (formerly "unnormals")
+/// Integer bit is explicit in this format. Intel hardware (387 and later)
+/// does not support these bit patterns:
+/// exponent = all 1's, integer bit 0, significand 0 ("pseudoinfinity")
+/// exponent = all 1's, integer bit 0, significand nonzero ("pseudoNaN")
+/// exponent = 0, integer bit 1 ("pseudodenormal")
+/// exponent!=0 nor all 1's, integer bit 0 ("unnormal")
+/// At the moment, the first two are treated as NaNs, the second two as Normal.
void
APFloat::initFromF80LongDoubleAPInt(const APInt &api)
{
assert(api.getBitWidth()==80);
uint64_t i1 = api.getRawData()[0];
uint64_t i2 = api.getRawData()[1];
- uint64_t myexponent = (i1 >> 48) & 0x7fff;
- uint64_t mysignificand = ((i1 << 16) & 0xffffffffffff0000ULL) |
- (i2 & 0xffff);
+ uint64_t myexponent = (i2 & 0x7fff);
+ uint64_t mysignificand = i1;
initialize(&APFloat::x87DoubleExtended);
assert(partCount()==2);
- sign = i1>>63;
+ sign = static_cast<unsigned int>(i2>>15);
if (myexponent==0 && mysignificand==0) {
// exponent, significand meaningless
category = fcZero;
initialize(&APFloat::PPCDoubleDouble);
assert(partCount()==2);
- sign = i1>>63;
- sign2 = i2>>63;
+ sign = static_cast<unsigned int>(i1>>63);
+ sign2 = static_cast<unsigned int>(i2>>63);
if (myexponent==0 && mysignificand==0) {
// exponent, significand meaningless
// exponent2 and significand2 are required to be 0; we don't check
// exponent2 and significand2 are required to be 0; we don't check
category = fcInfinity;
} else if (myexponent==0x7ff && mysignificand!=0) {
- // exponent meaningless. So is the whole second word, but keep it
+ // exponent meaningless. So is the whole second word, but keep it
// for determinism.
category = fcNaN;
exponent2 = myexponent2;
exponent = -1022;
else
significandParts()[0] |= 0x10000000000000LL; // integer bit
- if (myexponent2==0)
+ if (myexponent2==0)
exponent2 = -1022;
else
significandParts()[1] |= 0x10000000000000LL; // integer bit
}
}
+void
+APFloat::initFromQuadrupleAPInt(const APInt &api)
+{
+ assert(api.getBitWidth()==128);
+ uint64_t i1 = api.getRawData()[0];
+ uint64_t i2 = api.getRawData()[1];
+ uint64_t myexponent = (i2 >> 48) & 0x7fff;
+ uint64_t mysignificand = i1;
+ uint64_t mysignificand2 = i2 & 0xffffffffffffLL;
+
+ initialize(&APFloat::IEEEquad);
+ assert(partCount()==2);
+
+ sign = static_cast<unsigned int>(i2>>63);
+ if (myexponent==0 &&
+ (mysignificand==0 && mysignificand2==0)) {
+ // exponent, significand meaningless
+ category = fcZero;
+ } else if (myexponent==0x7fff &&
+ (mysignificand==0 && mysignificand2==0)) {
+ // exponent, significand meaningless
+ category = fcInfinity;
+ } else if (myexponent==0x7fff &&
+ (mysignificand!=0 || mysignificand2 !=0)) {
+ // exponent meaningless
+ category = fcNaN;
+ significandParts()[0] = mysignificand;
+ significandParts()[1] = mysignificand2;
+ } else {
+ category = fcNormal;
+ exponent = myexponent - 16383;
+ significandParts()[0] = mysignificand;
+ significandParts()[1] = mysignificand2;
+ if (myexponent==0) // denormal
+ exponent = -16382;
+ else
+ significandParts()[1] |= 0x1000000000000LL; // integer bit
+ }
+}
+
void
APFloat::initFromDoubleAPInt(const APInt &api)
{
initialize(&APFloat::IEEEdouble);
assert(partCount()==1);
- sign = i>>63;
+ sign = static_cast<unsigned int>(i>>63);
if (myexponent==0 && mysignificand==0) {
// exponent, significand meaningless
category = fcZero;
}
}
+void
+APFloat::initFromHalfAPInt(const APInt & api)
+{
+ assert(api.getBitWidth()==16);
+ uint32_t i = (uint32_t)*api.getRawData();
+ uint32_t myexponent = (i >> 10) & 0x1f;
+ uint32_t mysignificand = i & 0x3ff;
+
+ initialize(&APFloat::IEEEhalf);
+ assert(partCount()==1);
+
+ sign = i >> 15;
+ if (myexponent==0 && mysignificand==0) {
+ // exponent, significand meaningless
+ category = fcZero;
+ } else if (myexponent==0x1f && mysignificand==0) {
+ // exponent, significand meaningless
+ category = fcInfinity;
+ } else if (myexponent==0x1f && mysignificand!=0) {
+ // sign, exponent, significand meaningless
+ category = fcNaN;
+ *significandParts() = mysignificand;
+ } else {
+ category = fcNormal;
+ exponent = myexponent - 15; //bias
+ *significandParts() = mysignificand;
+ if (myexponent==0) // denormal
+ exponent = -14;
+ else
+ *significandParts() |= 0x400; // integer bit
+ }
+}
+
/// Treat api as containing the bits of a floating point number. Currently
/// we infer the floating point type from the size of the APInt. The
/// isIEEE argument distinguishes between PPC128 and IEEE128 (not meaningful
void
APFloat::initFromAPInt(const APInt& api, bool isIEEE)
{
- if (api.getBitWidth() == 32)
+ if (api.getBitWidth() == 16)
+ return initFromHalfAPInt(api);
+ else if (api.getBitWidth() == 32)
return initFromFloatAPInt(api);
else if (api.getBitWidth()==64)
return initFromDoubleAPInt(api);
else if (api.getBitWidth()==80)
return initFromF80LongDoubleAPInt(api);
- else if (api.getBitWidth()==128 && !isIEEE)
- return initFromPPCDoubleDoubleAPInt(api);
+ else if (api.getBitWidth()==128)
+ return (isIEEE ?
+ initFromQuadrupleAPInt(api) : initFromPPCDoubleDoubleAPInt(api));
else
- assert(0);
+ llvm_unreachable(0);
}
-APFloat::APFloat(const APInt& api, bool isIEEE)
+APFloat
+APFloat::getAllOnesValue(unsigned BitWidth, bool isIEEE)
{
+ return APFloat(APInt::getAllOnesValue(BitWidth), isIEEE);
+}
+
+APFloat APFloat::getLargest(const fltSemantics &Sem, bool Negative) {
+ APFloat Val(Sem, fcNormal, Negative);
+
+ // We want (in interchange format):
+ // sign = {Negative}
+ // exponent = 1..10
+ // significand = 1..1
+
+ Val.exponent = Sem.maxExponent; // unbiased
+
+ // 1-initialize all bits....
+ Val.zeroSignificand();
+ integerPart *significand = Val.significandParts();
+ unsigned N = partCountForBits(Sem.precision);
+ for (unsigned i = 0; i != N; ++i)
+ significand[i] = ~((integerPart) 0);
+
+ // ...and then clear the top bits for internal consistency.
+ if (Sem.precision % integerPartWidth != 0)
+ significand[N-1] &=
+ (((integerPart) 1) << (Sem.precision % integerPartWidth)) - 1;
+
+ return Val;
+}
+
+APFloat APFloat::getSmallest(const fltSemantics &Sem, bool Negative) {
+ APFloat Val(Sem, fcNormal, Negative);
+
+ // We want (in interchange format):
+ // sign = {Negative}
+ // exponent = 0..0
+ // significand = 0..01
+
+ Val.exponent = Sem.minExponent; // unbiased
+ Val.zeroSignificand();
+ Val.significandParts()[0] = 1;
+ return Val;
+}
+
+APFloat APFloat::getSmallestNormalized(const fltSemantics &Sem, bool Negative) {
+ APFloat Val(Sem, fcNormal, Negative);
+
+ // We want (in interchange format):
+ // sign = {Negative}
+ // exponent = 0..0
+ // significand = 10..0
+
+ Val.exponent = Sem.minExponent;
+ Val.zeroSignificand();
+ Val.significandParts()[partCountForBits(Sem.precision)-1] |=
+ (((integerPart) 1) << ((Sem.precision - 1) % integerPartWidth));
+
+ return Val;
+}
+
+APFloat::APFloat(const APInt& api, bool isIEEE) : exponent2(0), sign2(0) {
initFromAPInt(api, isIEEE);
}
-APFloat::APFloat(float f)
-{
- APInt api = APInt(32, 0);
- initFromAPInt(api.floatToBits(f));
+APFloat::APFloat(float f) : exponent2(0), sign2(0) {
+ initFromAPInt(APInt::floatToBits(f));
}
-APFloat::APFloat(double d)
-{
- APInt api = APInt(64, 0);
- initFromAPInt(api.doubleToBits(d));
+APFloat::APFloat(double d) : exponent2(0), sign2(0) {
+ initFromAPInt(APInt::doubleToBits(d));
+}
+
+namespace {
+ static void append(SmallVectorImpl<char> &Buffer,
+ unsigned N, const char *Str) {
+ unsigned Start = Buffer.size();
+ Buffer.set_size(Start + N);
+ memcpy(&Buffer[Start], Str, N);
+ }
+
+ template <unsigned N>
+ void append(SmallVectorImpl<char> &Buffer, const char (&Str)[N]) {
+ append(Buffer, N, Str);
+ }
+
+ /// Removes data from the given significand until it is no more
+ /// precise than is required for the desired precision.
+ void AdjustToPrecision(APInt &significand,
+ int &exp, unsigned FormatPrecision) {
+ unsigned bits = significand.getActiveBits();
+
+ // 196/59 is a very slight overestimate of lg_2(10).
+ unsigned bitsRequired = (FormatPrecision * 196 + 58) / 59;
+
+ if (bits <= bitsRequired) return;
+
+ unsigned tensRemovable = (bits - bitsRequired) * 59 / 196;
+ if (!tensRemovable) return;
+
+ exp += tensRemovable;
+
+ APInt divisor(significand.getBitWidth(), 1);
+ APInt powten(significand.getBitWidth(), 10);
+ while (true) {
+ if (tensRemovable & 1)
+ divisor *= powten;
+ tensRemovable >>= 1;
+ if (!tensRemovable) break;
+ powten *= powten;
+ }
+
+ significand = significand.udiv(divisor);
+
+ // Truncate the significand down to its active bit count, but
+ // don't try to drop below 32.
+ unsigned newPrecision = std::max(32U, significand.getActiveBits());
+ significand = significand.trunc(newPrecision);
+ }
+
+
+ void AdjustToPrecision(SmallVectorImpl<char> &buffer,
+ int &exp, unsigned FormatPrecision) {
+ unsigned N = buffer.size();
+ if (N <= FormatPrecision) return;
+
+ // The most significant figures are the last ones in the buffer.
+ unsigned FirstSignificant = N - FormatPrecision;
+
+ // Round.
+ // FIXME: this probably shouldn't use 'round half up'.
+
+ // Rounding down is just a truncation, except we also want to drop
+ // trailing zeros from the new result.
+ if (buffer[FirstSignificant - 1] < '5') {
+ while (FirstSignificant < N && buffer[FirstSignificant] == '0')
+ FirstSignificant++;
+
+ exp += FirstSignificant;
+ buffer.erase(&buffer[0], &buffer[FirstSignificant]);
+ return;
+ }
+
+ // Rounding up requires a decimal add-with-carry. If we continue
+ // the carry, the newly-introduced zeros will just be truncated.
+ for (unsigned I = FirstSignificant; I != N; ++I) {
+ if (buffer[I] == '9') {
+ FirstSignificant++;
+ } else {
+ buffer[I]++;
+ break;
+ }
+ }
+
+ // If we carried through, we have exactly one digit of precision.
+ if (FirstSignificant == N) {
+ exp += FirstSignificant;
+ buffer.clear();
+ buffer.push_back('1');
+ return;
+ }
+
+ exp += FirstSignificant;
+ buffer.erase(&buffer[0], &buffer[FirstSignificant]);
+ }
+}
+
+void APFloat::toString(SmallVectorImpl<char> &Str,
+ unsigned FormatPrecision,
+ unsigned FormatMaxPadding) const {
+ switch (category) {
+ case fcInfinity:
+ if (isNegative())
+ return append(Str, "-Inf");
+ else
+ return append(Str, "+Inf");
+
+ case fcNaN: return append(Str, "NaN");
+
+ case fcZero:
+ if (isNegative())
+ Str.push_back('-');
+
+ if (!FormatMaxPadding)
+ append(Str, "0.0E+0");
+ else
+ Str.push_back('0');
+ return;
+
+ case fcNormal:
+ break;
+ }
+
+ if (isNegative())
+ Str.push_back('-');
+
+ // Decompose the number into an APInt and an exponent.
+ int exp = exponent - ((int) semantics->precision - 1);
+ APInt significand(semantics->precision,
+ makeArrayRef(significandParts(),
+ partCountForBits(semantics->precision)));
+
+ // Set FormatPrecision if zero. We want to do this before we
+ // truncate trailing zeros, as those are part of the precision.
+ if (!FormatPrecision) {
+ // It's an interesting question whether to use the nominal
+ // precision or the active precision here for denormals.
+
+ // FormatPrecision = ceil(significandBits / lg_2(10))
+ FormatPrecision = (semantics->precision * 59 + 195) / 196;
+ }
+
+ // Ignore trailing binary zeros.
+ int trailingZeros = significand.countTrailingZeros();
+ exp += trailingZeros;
+ significand = significand.lshr(trailingZeros);
+
+ // Change the exponent from 2^e to 10^e.
+ if (exp == 0) {
+ // Nothing to do.
+ } else if (exp > 0) {
+ // Just shift left.
+ significand = significand.zext(semantics->precision + exp);
+ significand <<= exp;
+ exp = 0;
+ } else { /* exp < 0 */
+ int texp = -exp;
+
+ // We transform this using the identity:
+ // (N)(2^-e) == (N)(5^e)(10^-e)
+ // This means we have to multiply N (the significand) by 5^e.
+ // To avoid overflow, we have to operate on numbers large
+ // enough to store N * 5^e:
+ // log2(N * 5^e) == log2(N) + e * log2(5)
+ // <= semantics->precision + e * 137 / 59
+ // (log_2(5) ~ 2.321928 < 2.322034 ~ 137/59)
+
+ unsigned precision = semantics->precision + (137 * texp + 136) / 59;
+
+ // Multiply significand by 5^e.
+ // N * 5^0101 == N * 5^(1*1) * 5^(0*2) * 5^(1*4) * 5^(0*8)
+ significand = significand.zext(precision);
+ APInt five_to_the_i(precision, 5);
+ while (true) {
+ if (texp & 1) significand *= five_to_the_i;
+
+ texp >>= 1;
+ if (!texp) break;
+ five_to_the_i *= five_to_the_i;
+ }
+ }
+
+ AdjustToPrecision(significand, exp, FormatPrecision);
+
+ llvm::SmallVector<char, 256> buffer;
+
+ // Fill the buffer.
+ unsigned precision = significand.getBitWidth();
+ APInt ten(precision, 10);
+ APInt digit(precision, 0);
+
+ bool inTrail = true;
+ while (significand != 0) {
+ // digit <- significand % 10
+ // significand <- significand / 10
+ APInt::udivrem(significand, ten, significand, digit);
+
+ unsigned d = digit.getZExtValue();
+
+ // Drop trailing zeros.
+ if (inTrail && !d) exp++;
+ else {
+ buffer.push_back((char) ('0' + d));
+ inTrail = false;
+ }
+ }
+
+ assert(!buffer.empty() && "no characters in buffer!");
+
+ // Drop down to FormatPrecision.
+ // TODO: don't do more precise calculations above than are required.
+ AdjustToPrecision(buffer, exp, FormatPrecision);
+
+ unsigned NDigits = buffer.size();
+
+ // Check whether we should use scientific notation.
+ bool FormatScientific;
+ if (!FormatMaxPadding)
+ FormatScientific = true;
+ else {
+ if (exp >= 0) {
+ // 765e3 --> 765000
+ // ^^^
+ // But we shouldn't make the number look more precise than it is.
+ FormatScientific = ((unsigned) exp > FormatMaxPadding ||
+ NDigits + (unsigned) exp > FormatPrecision);
+ } else {
+ // Power of the most significant digit.
+ int MSD = exp + (int) (NDigits - 1);
+ if (MSD >= 0) {
+ // 765e-2 == 7.65
+ FormatScientific = false;
+ } else {
+ // 765e-5 == 0.00765
+ // ^ ^^
+ FormatScientific = ((unsigned) -MSD) > FormatMaxPadding;
+ }
+ }
+ }
+
+ // Scientific formatting is pretty straightforward.
+ if (FormatScientific) {
+ exp += (NDigits - 1);
+
+ Str.push_back(buffer[NDigits-1]);
+ Str.push_back('.');
+ if (NDigits == 1)
+ Str.push_back('0');
+ else
+ for (unsigned I = 1; I != NDigits; ++I)
+ Str.push_back(buffer[NDigits-1-I]);
+ Str.push_back('E');
+
+ Str.push_back(exp >= 0 ? '+' : '-');
+ if (exp < 0) exp = -exp;
+ SmallVector<char, 6> expbuf;
+ do {
+ expbuf.push_back((char) ('0' + (exp % 10)));
+ exp /= 10;
+ } while (exp);
+ for (unsigned I = 0, E = expbuf.size(); I != E; ++I)
+ Str.push_back(expbuf[E-1-I]);
+ return;
+ }
+
+ // Non-scientific, positive exponents.
+ if (exp >= 0) {
+ for (unsigned I = 0; I != NDigits; ++I)
+ Str.push_back(buffer[NDigits-1-I]);
+ for (unsigned I = 0; I != (unsigned) exp; ++I)
+ Str.push_back('0');
+ return;
+ }
+
+ // Non-scientific, negative exponents.
+
+ // The number of digits to the left of the decimal point.
+ int NWholeDigits = exp + (int) NDigits;
+
+ unsigned I = 0;
+ if (NWholeDigits > 0) {
+ for (; I != (unsigned) NWholeDigits; ++I)
+ Str.push_back(buffer[NDigits-I-1]);
+ Str.push_back('.');
+ } else {
+ unsigned NZeros = 1 + (unsigned) -NWholeDigits;
+
+ Str.push_back('0');
+ Str.push_back('.');
+ for (unsigned Z = 1; Z != NZeros; ++Z)
+ Str.push_back('0');
+ }
+
+ for (; I != NDigits; ++I)
+ Str.push_back(buffer[NDigits-I-1]);
+}
+
+bool APFloat::getExactInverse(APFloat *inv) const {
+ // We can only guarantee the existence of an exact inverse for IEEE floats.
+ if (semantics != &IEEEhalf && semantics != &IEEEsingle &&
+ semantics != &IEEEdouble && semantics != &IEEEquad)
+ return false;
+
+ // Special floats and denormals have no exact inverse.
+ if (category != fcNormal)
+ return false;
+
+ // Check that the number is a power of two by making sure that only the
+ // integer bit is set in the significand.
+ if (significandLSB() != semantics->precision - 1)
+ return false;
+
+ // Get the inverse.
+ APFloat reciprocal(*semantics, 1ULL);
+ if (reciprocal.divide(*this, rmNearestTiesToEven) != opOK)
+ return false;
+
+ // Avoid multiplication with a denormal, it is not safe on all platforms and
+ // may be slower than a normal division.
+ if (reciprocal.significandMSB() + 1 < reciprocal.semantics->precision)
+ return false;
+
+ assert(reciprocal.category == fcNormal &&
+ reciprocal.significandLSB() == reciprocal.semantics->precision - 1);
+
+ if (inv)
+ *inv = reciprocal;
+
+ return true;
}