Plan 9 from Bell Labs’s /usr/web/sources/contrib/stallion/root/arm/go/src/strconv/itoa.go

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Distributed under the MIT License.
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// 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.

package strconv

import "math/bits"

const fastSmalls = true // enable fast path for small integers

// FormatUint returns the string representation of i in the given base,
// for 2 <= base <= 36. The result uses the lower-case letters 'a' to 'z'
// for digit values >= 10.
func FormatUint(i uint64, base int) string {
	if fastSmalls && i < nSmalls && base == 10 {
		return small(int(i))
	}
	_, s := formatBits(nil, i, base, false, false)
	return s
}

// FormatInt returns the string representation of i in the given base,
// for 2 <= base <= 36. The result uses the lower-case letters 'a' to 'z'
// for digit values >= 10.
func FormatInt(i int64, base int) string {
	if fastSmalls && 0 <= i && i < nSmalls && base == 10 {
		return small(int(i))
	}
	_, s := formatBits(nil, uint64(i), base, i < 0, false)
	return s
}

// Itoa is equivalent to FormatInt(int64(i), 10).
func Itoa(i int) string {
	return FormatInt(int64(i), 10)
}

// AppendInt appends the string form of the integer i,
// as generated by FormatInt, to dst and returns the extended buffer.
func AppendInt(dst []byte, i int64, base int) []byte {
	if fastSmalls && 0 <= i && i < nSmalls && base == 10 {
		return append(dst, small(int(i))...)
	}
	dst, _ = formatBits(dst, uint64(i), base, i < 0, true)
	return dst
}

// AppendUint appends the string form of the unsigned integer i,
// as generated by FormatUint, to dst and returns the extended buffer.
func AppendUint(dst []byte, i uint64, base int) []byte {
	if fastSmalls && i < nSmalls && base == 10 {
		return append(dst, small(int(i))...)
	}
	dst, _ = formatBits(dst, i, base, false, true)
	return dst
}

// small returns the string for an i with 0 <= i < nSmalls.
func small(i int) string {
	if i < 10 {
		return digits[i : i+1]
	}
	return smallsString[i*2 : i*2+2]
}

const nSmalls = 100

const smallsString = "00010203040506070809" +
	"10111213141516171819" +
	"20212223242526272829" +
	"30313233343536373839" +
	"40414243444546474849" +
	"50515253545556575859" +
	"60616263646566676869" +
	"70717273747576777879" +
	"80818283848586878889" +
	"90919293949596979899"

const host32bit = ^uint(0)>>32 == 0

const digits = "0123456789abcdefghijklmnopqrstuvwxyz"

// formatBits computes the string representation of u in the given base.
// If neg is set, u is treated as negative int64 value. If append_ is
// set, the string is appended to dst and the resulting byte slice is
// returned as the first result value; otherwise the string is returned
// as the second result value.
//
func formatBits(dst []byte, u uint64, base int, neg, append_ bool) (d []byte, s string) {
	if base < 2 || base > len(digits) {
		panic("strconv: illegal AppendInt/FormatInt base")
	}
	// 2 <= base && base <= len(digits)

	var a [64 + 1]byte // +1 for sign of 64bit value in base 2
	i := len(a)

	if neg {
		u = -u
	}

	// convert bits
	// We use uint values where we can because those will
	// fit into a single register even on a 32bit machine.
	if base == 10 {
		// common case: use constants for / because
		// the compiler can optimize it into a multiply+shift

		if host32bit {
			// convert the lower digits using 32bit operations
			for u >= 1e9 {
				// Avoid using r = a%b in addition to q = a/b
				// since 64bit division and modulo operations
				// are calculated by runtime functions on 32bit machines.
				q := u / 1e9
				us := uint(u - q*1e9) // u % 1e9 fits into a uint
				for j := 4; j > 0; j-- {
					is := us % 100 * 2
					us /= 100
					i -= 2
					a[i+1] = smallsString[is+1]
					a[i+0] = smallsString[is+0]
				}

				// us < 10, since it contains the last digit
				// from the initial 9-digit us.
				i--
				a[i] = smallsString[us*2+1]

				u = q
			}
			// u < 1e9
		}

		// u guaranteed to fit into a uint
		us := uint(u)
		for us >= 100 {
			is := us % 100 * 2
			us /= 100
			i -= 2
			a[i+1] = smallsString[is+1]
			a[i+0] = smallsString[is+0]
		}

		// us < 100
		is := us * 2
		i--
		a[i] = smallsString[is+1]
		if us >= 10 {
			i--
			a[i] = smallsString[is]
		}

	} else if isPowerOfTwo(base) {
		// Use shifts and masks instead of / and %.
		// Base is a power of 2 and 2 <= base <= len(digits) where len(digits) is 36.
		// The largest power of 2 below or equal to 36 is 32, which is 1 << 5;
		// i.e., the largest possible shift count is 5. By &-ind that value with
		// the constant 7 we tell the compiler that the shift count is always
		// less than 8 which is smaller than any register width. This allows
		// the compiler to generate better code for the shift operation.
		shift := uint(bits.TrailingZeros(uint(base))) & 7
		b := uint64(base)
		m := uint(base) - 1 // == 1<<shift - 1
		for u >= b {
			i--
			a[i] = digits[uint(u)&m]
			u >>= shift
		}
		// u < base
		i--
		a[i] = digits[uint(u)]
	} else {
		// general case
		b := uint64(base)
		for u >= b {
			i--
			// Avoid using r = a%b in addition to q = a/b
			// since 64bit division and modulo operations
			// are calculated by runtime functions on 32bit machines.
			q := u / b
			a[i] = digits[uint(u-q*b)]
			u = q
		}
		// u < base
		i--
		a[i] = digits[uint(u)]
	}

	// add sign, if any
	if neg {
		i--
		a[i] = '-'
	}

	if append_ {
		d = append(dst, a[i:]...)
		return
	}
	s = string(a[i:])
	return
}

func isPowerOfTwo(x int) bool {
	return x&(x-1) == 0
}

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