Retro68/gcc/libgo/go/math/big/arith.go

// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.

// This file provides Go implementations of elementary multi-precision
// arithmetic operations on word vectors. Needed for platforms without
// assembly implementations of these routines.

package big

// A Word represents a single digit of a multi-precision unsigned integer.
type Word uintptr

const (
	// Compute the size _S of a Word in bytes.
	_m    = ^Word(0)
	_logS = _m>>8&1 + _m>>16&1 + _m>>32&1
	_S    = 1 << _logS

	_W = _S << 3 // word size in bits
	_B = 1 << _W // digit base
	_M = _B - 1  // digit mask

	_W2 = _W / 2   // half word size in bits
	_B2 = 1 << _W2 // half digit base
	_M2 = _B2 - 1  // half digit mask
)

// ----------------------------------------------------------------------------
// Elementary operations on words
//
// These operations are used by the vector operations below.

// z1<<_W + z0 = x+y+c, with c == 0 or 1
func addWW_g(x, y, c Word) (z1, z0 Word) {
	yc := y + c
	z0 = x + yc
	if z0 < x || yc < y {
		z1 = 1
	}
	return
}

// z1<<_W + z0 = x-y-c, with c == 0 or 1
func subWW_g(x, y, c Word) (z1, z0 Word) {
	yc := y + c
	z0 = x - yc
	if z0 > x || yc < y {
		z1 = 1
	}
	return
}

// z1<<_W + z0 = x*y
func mulWW(x, y Word) (z1, z0 Word) { return mulWW_g(x, y) }

// Adapted from Warren, Hacker's Delight, p. 132.
func mulWW_g(x, y Word) (z1, z0 Word) {
	x0 := x & _M2
	x1 := x >> _W2
	y0 := y & _M2
	y1 := y >> _W2
	w0 := x0 * y0
	t := x1*y0 + w0>>_W2
	w1 := t & _M2
	w2 := t >> _W2
	w1 += x0 * y1
	z1 = x1*y1 + w2 + w1>>_W2
	z0 = x * y
	return
}

// z1<<_W + z0 = x*y + c
func mulAddWWW_g(x, y, c Word) (z1, z0 Word) {
	z1, zz0 := mulWW(x, y)
	if z0 = zz0 + c; z0 < zz0 {
		z1++
	}
	return
}

// Length of x in bits.
func bitLen(x Word) (n int) { return bitLen_g(x) }
func bitLen_g(x Word) (n int) {
	for ; x >= 0x8000; x >>= 16 {
		n += 16
	}
	if x >= 0x80 {
		x >>= 8
		n += 8
	}
	if x >= 0x8 {
		x >>= 4
		n += 4
	}
	if x >= 0x2 {
		x >>= 2
		n += 2
	}
	if x >= 0x1 {
		n++
	}
	return
}

// log2 computes the integer binary logarithm of x.
// The result is the integer n for which 2^n <= x < 2^(n+1).
// If x == 0, the result is -1.
func log2(x Word) int {
	return bitLen(x) - 1
}

// Number of leading zeros in x.
func leadingZeros(x Word) uint {
	return uint(_W - bitLen(x))
}

// q = (u1<<_W + u0 - r)/y
func divWW(x1, x0, y Word) (q, r Word) { return divWW_g(x1, x0, y) }

// Adapted from Warren, Hacker's Delight, p. 152.
func divWW_g(u1, u0, v Word) (q, r Word) {
	if u1 >= v {
		return 1<<_W - 1, 1<<_W - 1
	}

	s := leadingZeros(v)
	v <<= s

	vn1 := v >> _W2
	vn0 := v & _M2
	un32 := u1<<s | u0>>(_W-s)
	un10 := u0 << s
	un1 := un10 >> _W2
	un0 := un10 & _M2
	q1 := un32 / vn1
	rhat := un32 - q1*vn1

again1:
	if q1 >= _B2 || q1*vn0 > _B2*rhat+un1 {
		q1--
		rhat += vn1
		if rhat < _B2 {
			goto again1
		}
	}

	un21 := un32*_B2 + un1 - q1*v
	q0 := un21 / vn1
	rhat = un21 - q0*vn1

again2:
	if q0 >= _B2 || q0*vn0 > _B2*rhat+un0 {
		q0--
		rhat += vn1
		if rhat < _B2 {
			goto again2
		}
	}

	return q1*_B2 + q0, (un21*_B2 + un0 - q0*v) >> s
}

func addVV(z, x, y []Word) (c Word) { return addVV_g(z, x, y) }
func addVV_g(z, x, y []Word) (c Word) {
	for i := range z {
		c, z[i] = addWW_g(x[i], y[i], c)
	}
	return
}

func subVV(z, x, y []Word) (c Word) { return subVV_g(z, x, y) }
func subVV_g(z, x, y []Word) (c Word) {
	for i := range z {
		c, z[i] = subWW_g(x[i], y[i], c)
	}
	return
}

func addVW(z, x []Word, y Word) (c Word) { return addVW_g(z, x, y) }
func addVW_g(z, x []Word, y Word) (c Word) {
	c = y
	for i := range z {
		c, z[i] = addWW_g(x[i], c, 0)
	}
	return
}

func subVW(z, x []Word, y Word) (c Word) { return subVW_g(z, x, y) }
func subVW_g(z, x []Word, y Word) (c Word) {
	c = y
	for i := range z {
		c, z[i] = subWW_g(x[i], c, 0)
	}
	return
}

func shlVU(z, x []Word, s uint) (c Word) { return shlVU_g(z, x, s) }
func shlVU_g(z, x []Word, s uint) (c Word) {
	if n := len(z); n > 0 {
		ŝ := _W - s
		w1 := x[n-1]
		c = w1 >> ŝ
		for i := n - 1; i > 0; i-- {
			w := w1
			w1 = x[i-1]
			z[i] = w<<s | w1>>ŝ
		}
		z[0] = w1 << s
	}
	return
}

func shrVU(z, x []Word, s uint) (c Word) { return shrVU_g(z, x, s) }
func shrVU_g(z, x []Word, s uint) (c Word) {
	if n := len(z); n > 0 {
		ŝ := _W - s
		w1 := x[0]
		c = w1 << ŝ
		for i := 0; i < n-1; i++ {
			w := w1
			w1 = x[i+1]
			z[i] = w>>s | w1<<ŝ
		}
		z[n-1] = w1 >> s
	}
	return
}

func mulAddVWW(z, x []Word, y, r Word) (c Word) { return mulAddVWW_g(z, x, y, r) }
func mulAddVWW_g(z, x []Word, y, r Word) (c Word) {
	c = r
	for i := range z {
		c, z[i] = mulAddWWW_g(x[i], y, c)
	}
	return
}

func addMulVVW(z, x []Word, y Word) (c Word) { return addMulVVW_g(z, x, y) }
func addMulVVW_g(z, x []Word, y Word) (c Word) {
	for i := range z {
		z1, z0 := mulAddWWW_g(x[i], y, z[i])
		c, z[i] = addWW_g(z0, c, 0)
		c += z1
	}
	return
}

func divWVW(z []Word, xn Word, x []Word, y Word) (r Word) { return divWVW_g(z, xn, x, y) }
func divWVW_g(z []Word, xn Word, x []Word, y Word) (r Word) {
	r = xn
	for i := len(z) - 1; i >= 0; i-- {
		z[i], r = divWW_g(r, x[i], y)
	}
	return
}
add gcc 4.70 2012-03-27 23:13:14 +00:00			`// Copyright 2009 The Go Authors. All rights reserved.`
			`// Use of this source code is governed by a BSD-style`
			`// license that can be found in the LICENSE file.`

			`// This file provides Go implementations of elementary multi-precision`
			`// arithmetic operations on word vectors. Needed for platforms without`
			`// assembly implementations of these routines.`

			`package big`

			`// A Word represents a single digit of a multi-precision unsigned integer.`
			`type Word uintptr`

			`const (`
			`// Compute the size _S of a Word in bytes.`
			`_m = ^Word(0)`
			`_logS = _m>>8&1 + _m>>16&1 + _m>>32&1`
			`_S = 1 << _logS`

			`_W = _S << 3 // word size in bits`
			`_B = 1 << _W // digit base`
			`_M = _B - 1 // digit mask`

			`_W2 = _W / 2 // half word size in bits`
			`_B2 = 1 << _W2 // half digit base`
			`_M2 = _B2 - 1 // half digit mask`
			`)`

			`// ----------------------------------------------------------------------------`
			`// Elementary operations on words`
			`//`
			`// These operations are used by the vector operations below.`

			`// z1<<_W + z0 = x+y+c, with c == 0 or 1`
			`func addWW_g(x, y, c Word) (z1, z0 Word) {`
			`yc := y + c`
			`z0 = x + yc`
			`if z0 < x \|\| yc < y {`
			`z1 = 1`
			`}`
			`return`
			`}`

			`// z1<<_W + z0 = x-y-c, with c == 0 or 1`
			`func subWW_g(x, y, c Word) (z1, z0 Word) {`
			`yc := y + c`
			`z0 = x - yc`
			`if z0 > x \|\| yc < y {`
			`z1 = 1`
			`}`
			`return`
			`}`

			`// z1<<_W + z0 = x*y`
			`func mulWW(x, y Word) (z1, z0 Word) { return mulWW_g(x, y) }`

			`// Adapted from Warren, Hacker's Delight, p. 132.`
			`func mulWW_g(x, y Word) (z1, z0 Word) {`
			`x0 := x & _M2`
			`x1 := x >> _W2`
			`y0 := y & _M2`
			`y1 := y >> _W2`
			`w0 := x0 * y0`
			`t := x1*y0 + w0>>_W2`
			`w1 := t & _M2`
			`w2 := t >> _W2`
			`w1 += x0 * y1`
			`z1 = x1*y1 + w2 + w1>>_W2`
			`z0 = x * y`
			`return`
			`}`

			`// z1<<_W + z0 = x*y + c`
			`func mulAddWWW_g(x, y, c Word) (z1, z0 Word) {`
			`z1, zz0 := mulWW(x, y)`
			`if z0 = zz0 + c; z0 < zz0 {`
			`z1++`
			`}`
			`return`
			`}`

			`// Length of x in bits.`
			`func bitLen(x Word) (n int) { return bitLen_g(x) }`
			`func bitLen_g(x Word) (n int) {`
			`for ; x >= 0x8000; x >>= 16 {`
			`n += 16`
			`}`
			`if x >= 0x80 {`
			`x >>= 8`
			`n += 8`
			`}`
			`if x >= 0x8 {`
			`x >>= 4`
			`n += 4`
			`}`
			`if x >= 0x2 {`
			`x >>= 2`
			`n += 2`
			`}`
			`if x >= 0x1 {`
			`n++`
			`}`
			`return`
			`}`

			`// log2 computes the integer binary logarithm of x.`
			`// The result is the integer n for which 2^n <= x < 2^(n+1).`
			`// If x == 0, the result is -1.`
			`func log2(x Word) int {`
			`return bitLen(x) - 1`
			`}`

			`// Number of leading zeros in x.`
			`func leadingZeros(x Word) uint {`
			`return uint(_W - bitLen(x))`
			`}`

			`// q = (u1<<_W + u0 - r)/y`
			`func divWW(x1, x0, y Word) (q, r Word) { return divWW_g(x1, x0, y) }`

			`// Adapted from Warren, Hacker's Delight, p. 152.`
			`func divWW_g(u1, u0, v Word) (q, r Word) {`
			`if u1 >= v {`
			`return 1<<_W - 1, 1<<_W - 1`
			`}`

			`s := leadingZeros(v)`
			`v <<= s`

			`vn1 := v >> _W2`
			`vn0 := v & _M2`
			`un32 := u1<<s \| u0>>(_W-s)`
			`un10 := u0 << s`
			`un1 := un10 >> _W2`
			`un0 := un10 & _M2`
			`q1 := un32 / vn1`
			`rhat := un32 - q1*vn1`

			`again1:`
			`if q1 >= _B2 \|\| q1vn0 > _B2rhat+un1 {`
			`q1--`
			`rhat += vn1`
			`if rhat < _B2 {`
			`goto again1`
			`}`
			`}`

			`un21 := un32_B2 + un1 - q1v`
			`q0 := un21 / vn1`
			`rhat = un21 - q0*vn1`

			`again2:`
			`if q0 >= _B2 \|\| q0vn0 > _B2rhat+un0 {`
			`q0--`
			`rhat += vn1`
			`if rhat < _B2 {`
			`goto again2`
			`}`
			`}`

			`return q1_B2 + q0, (un21_B2 + un0 - q0*v) >> s`
			`}`

			`func addVV(z, x, y []Word) (c Word) { return addVV_g(z, x, y) }`
			`func addVV_g(z, x, y []Word) (c Word) {`
			`for i := range z {`
			`c, z[i] = addWW_g(x[i], y[i], c)`
			`}`
			`return`
			`}`

			`func subVV(z, x, y []Word) (c Word) { return subVV_g(z, x, y) }`
			`func subVV_g(z, x, y []Word) (c Word) {`
			`for i := range z {`
			`c, z[i] = subWW_g(x[i], y[i], c)`
			`}`
			`return`
			`}`

			`func addVW(z, x []Word, y Word) (c Word) { return addVW_g(z, x, y) }`
			`func addVW_g(z, x []Word, y Word) (c Word) {`
			`c = y`
			`for i := range z {`
			`c, z[i] = addWW_g(x[i], c, 0)`
			`}`
			`return`
			`}`

			`func subVW(z, x []Word, y Word) (c Word) { return subVW_g(z, x, y) }`
			`func subVW_g(z, x []Word, y Word) (c Word) {`
			`c = y`
			`for i := range z {`
			`c, z[i] = subWW_g(x[i], c, 0)`
			`}`
			`return`
			`}`

			`func shlVU(z, x []Word, s uint) (c Word) { return shlVU_g(z, x, s) }`
			`func shlVU_g(z, x []Word, s uint) (c Word) {`
			`if n := len(z); n > 0 {`
			`ŝ := _W - s`
			`w1 := x[n-1]`
			`c = w1 >> ŝ`
			`for i := n - 1; i > 0; i-- {`
			`w := w1`
			`w1 = x[i-1]`
			`z[i] = w<<s \| w1>>ŝ`
			`}`
			`z[0] = w1 << s`
			`}`
			`return`
			`}`

			`func shrVU(z, x []Word, s uint) (c Word) { return shrVU_g(z, x, s) }`
			`func shrVU_g(z, x []Word, s uint) (c Word) {`
			`if n := len(z); n > 0 {`
			`ŝ := _W - s`
			`w1 := x[0]`
			`c = w1 << ŝ`
			`for i := 0; i < n-1; i++ {`
			`w := w1`
			`w1 = x[i+1]`
			`z[i] = w>>s \| w1<<ŝ`
			`}`
			`z[n-1] = w1 >> s`
			`}`
			`return`
			`}`

			`func mulAddVWW(z, x []Word, y, r Word) (c Word) { return mulAddVWW_g(z, x, y, r) }`
			`func mulAddVWW_g(z, x []Word, y, r Word) (c Word) {`
			`c = r`
			`for i := range z {`
			`c, z[i] = mulAddWWW_g(x[i], y, c)`
			`}`
			`return`
			`}`

			`func addMulVVW(z, x []Word, y Word) (c Word) { return addMulVVW_g(z, x, y) }`
			`func addMulVVW_g(z, x []Word, y Word) (c Word) {`
			`for i := range z {`
			`z1, z0 := mulAddWWW_g(x[i], y, z[i])`
			`c, z[i] = addWW_g(z0, c, 0)`
			`c += z1`
			`}`
			`return`
			`}`

			`func divWVW(z []Word, xn Word, x []Word, y Word) (r Word) { return divWVW_g(z, xn, x, y) }`
			`func divWVW_g(z []Word, xn Word, x []Word, y Word) (r Word) {`
			`r = xn`
			`for i := len(z) - 1; i >= 0; i-- {`
			`z[i], r = divWW_g(r, x[i], y)`
			`}`
			`return`
			`}`