compiler-rt/lib/builtins/ppc/fixunstfti.c - llvm-project - Git at Google

 //===-- lib/builtins/ppc/fixunstfti.c - Convert long double->int128 *-C -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements converting the 128bit IBM/PowerPC long double (double-
 // double) data type to an unsigned 128 bit integer.
 //
 //===----------------------------------------------------------------------===//

 #include "../int_math.h"
 #define BIAS 1023

 // Convert long double into an unsigned 128-bit integer.
 __uint128_t __fixunstfti(long double input) {

   // If we are trying to convert a NaN, return the NaN bit pattern.
   if (crt_isnan(input)) {
     return ((__uint128_t)0x7FF8000000000000ll) << 64 |
            (__uint128_t)0x0000000000000000ll;
   }

   __uint128_t result, hiResult, loResult;
   int hiExponent, loExponent, shift;
   // The long double representation, with the high and low portions of
   // the long double, and the corresponding bit patterns of each double.
   union {
     long double ld;
     double d[2];               // [0] is the high double, [1] is the low double.
     unsigned long long ull[2]; // High and low doubles as 64-bit integers.
   } ldUnion;

   // If the long double is less than 1.0 or negative,
   // return 0.
   if (input < 1.0)
     return 0;

   // Retrieve the 64-bit patterns of high and low doubles.
   // Compute the unbiased exponent of both high and low doubles by
   // removing the signs, isolating the exponent, and subtracting
   // the bias from it.
   ldUnion.ld = input;
   hiExponent = ((ldUnion.ull[0] & 0x7FFFFFFFFFFFFFFFll) >> 52) - BIAS;
   loExponent = ((ldUnion.ull[1] & 0x7FFFFFFFFFFFFFFFll) >> 52) - BIAS;

   // Convert each double into int64; they will be added to the int128 result.
   // CASE 1: High or low double fits in int64
   //      - Convert the each double normally into int64.
   //
   // CASE 2: High or low double does not fit in int64
   //      - Scale the double to fit within a 64-bit integer
   //      - Calculate the shift (amount to scale the double by in the int128)
   //      - Clear all the bits of the exponent (with 0x800FFFFFFFFFFFFF)
   //      - Add BIAS+53 (0x4350000000000000) to exponent to correct the value
   //      - Scale (move) the double to the correct place in the int128
   //        (Move it by 2^53 places)
   //
   // Note: If the high double is assumed to be positive, an unsigned conversion
   // from long double to 64-bit integer is needed. The low double can be either
   // positive or negative, so a signed conversion is needed to retain the result
   // of the low double and to ensure it does not simply get converted to 0.

   // CASE 1 - High double fits in int64.
   if (hiExponent < 63) {
     hiResult = (unsigned long long)ldUnion.d[0];
   } else if (hiExponent < 128) {
     // CASE 2 - High double does not fit in int64, scale and convert it.
     shift = hiExponent - 54;
     ldUnion.ull[0] &= 0x800FFFFFFFFFFFFFll;
     ldUnion.ull[0] |= 0x4350000000000000ll;
     hiResult = (unsigned long long)ldUnion.d[0];
     hiResult <<= shift;
   } else {
     // Detect cases for overflow. When the exponent of the high
     // double is greater than 128 bits and when the long double
     // input is positive, return the max 128-bit integer.
     // For negative inputs with exponents > 128, return 1, like gcc.
     if (ldUnion.d[0] > 0) {
       return ((__uint128_t)0xFFFFFFFFFFFFFFFFll) << 64 |
              (__uint128_t)0xFFFFFFFFFFFFFFFFll;
     } else {
       return ((__uint128_t)0x0000000000000000ll) << 64 |
              (__uint128_t)0x0000000000000001ll;
     }
   }

   // CASE 1 - Low double fits in int64.
   if (loExponent < 63) {
     loResult = (long long)ldUnion.d[1];
   } else {
     // CASE 2 - Low double does not fit in int64, scale and convert it.
     shift = loExponent - 54;
     ldUnion.ull[1] &= 0x800FFFFFFFFFFFFFll;
     ldUnion.ull[1] |= 0x4350000000000000ll;
     loResult = (long long)ldUnion.d[1];
     loResult <<= shift;
   }

   // If the low double is negative, it may change the integer value of the
   // whole number if the absolute value of its fractional part is bigger than
   // the fractional part of the high double. Because both doubles cannot
   // overlap, this situation only occurs when the high double has no
   // fractional part.
   ldUnion.ld = input;
   if ((ldUnion.d[0] == (double)hiResult) &&
       (ldUnion.d[1] < (double)((__int128_t)loResult)))
     loResult--;

   // Add the high and low doublewords together to form a 128 bit integer.
   result = loResult + hiResult;
   return result;
 }
	//===-- lib/builtins/ppc/fixunstfti.c - Convert long double->int128 -C --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements converting the 128bit IBM/PowerPC long double (double-
	// double) data type to an unsigned 128 bit integer.
	//
	//===----------------------------------------------------------------------===//

	#include "../int_math.h"
	#define BIAS 1023

	// Convert long double into an unsigned 128-bit integer.
	__uint128_t __fixunstfti(long double input) {

	// If we are trying to convert a NaN, return the NaN bit pattern.
	if (crt_isnan(input)) {
	return ((__uint128_t)0x7FF8000000000000ll) << 64 \|
	(__uint128_t)0x0000000000000000ll;
	}

	__uint128_t result, hiResult, loResult;
	int hiExponent, loExponent, shift;
	// The long double representation, with the high and low portions of
	// the long double, and the corresponding bit patterns of each double.
	union {
	long double ld;
	double d[2]; // [0] is the high double, [1] is the low double.
	unsigned long long ull[2]; // High and low doubles as 64-bit integers.
	} ldUnion;

	// If the long double is less than 1.0 or negative,
	// return 0.
	if (input < 1.0)
	return 0;

	// Retrieve the 64-bit patterns of high and low doubles.
	// Compute the unbiased exponent of both high and low doubles by
	// removing the signs, isolating the exponent, and subtracting
	// the bias from it.
	ldUnion.ld = input;
	hiExponent = ((ldUnion.ull[0] & 0x7FFFFFFFFFFFFFFFll) >> 52) - BIAS;
	loExponent = ((ldUnion.ull[1] & 0x7FFFFFFFFFFFFFFFll) >> 52) - BIAS;

	// Convert each double into int64; they will be added to the int128 result.
	// CASE 1: High or low double fits in int64
	// - Convert the each double normally into int64.
	//
	// CASE 2: High or low double does not fit in int64
	// - Scale the double to fit within a 64-bit integer
	// - Calculate the shift (amount to scale the double by in the int128)
	// - Clear all the bits of the exponent (with 0x800FFFFFFFFFFFFF)
	// - Add BIAS+53 (0x4350000000000000) to exponent to correct the value
	// - Scale (move) the double to the correct place in the int128
	// (Move it by 2^53 places)
	//
	// Note: If the high double is assumed to be positive, an unsigned conversion
	// from long double to 64-bit integer is needed. The low double can be either
	// positive or negative, so a signed conversion is needed to retain the result
	// of the low double and to ensure it does not simply get converted to 0.

	// CASE 1 - High double fits in int64.
	if (hiExponent < 63) {
	hiResult = (unsigned long long)ldUnion.d[0];
	} else if (hiExponent < 128) {
	// CASE 2 - High double does not fit in int64, scale and convert it.
	shift = hiExponent - 54;
	ldUnion.ull[0] &= 0x800FFFFFFFFFFFFFll;
	ldUnion.ull[0] \|= 0x4350000000000000ll;
	hiResult = (unsigned long long)ldUnion.d[0];
	hiResult <<= shift;
	} else {
	// Detect cases for overflow. When the exponent of the high
	// double is greater than 128 bits and when the long double
	// input is positive, return the max 128-bit integer.
	// For negative inputs with exponents > 128, return 1, like gcc.
	if (ldUnion.d[0] > 0) {
	return ((__uint128_t)0xFFFFFFFFFFFFFFFFll) << 64 \|
	(__uint128_t)0xFFFFFFFFFFFFFFFFll;
	} else {
	return ((__uint128_t)0x0000000000000000ll) << 64 \|
	(__uint128_t)0x0000000000000001ll;
	}
	}

	// CASE 1 - Low double fits in int64.
	if (loExponent < 63) {
	loResult = (long long)ldUnion.d[1];
	} else {
	// CASE 2 - Low double does not fit in int64, scale and convert it.
	shift = loExponent - 54;
	ldUnion.ull[1] &= 0x800FFFFFFFFFFFFFll;
	ldUnion.ull[1] \|= 0x4350000000000000ll;
	loResult = (long long)ldUnion.d[1];
	loResult <<= shift;
	}

	// If the low double is negative, it may change the integer value of the
	// whole number if the absolute value of its fractional part is bigger than
	// the fractional part of the high double. Because both doubles cannot
	// overlap, this situation only occurs when the high double has no
	// fractional part.
	ldUnion.ld = input;
	if ((ldUnion.d[0] == (double)hiResult) &&
	(ldUnion.d[1] < (double)((__int128_t)loResult)))
	loResult--;

	// Add the high and low doublewords together to form a 128 bit integer.
	result = loResult + hiResult;
	return result;
	}