// 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" // 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 base == 10 { if i < nSmalls { return small(int(i)) } var a [24]byte j := formatBase10(a[:], i) return string(a[j:]) } _, 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 base == 10 { if 0 <= i && i < nSmalls { return small(int(i)) } var a [24]byte u := uint64(i) if i < 0 { u = -u } j := formatBase10(a[:], u) if i < 0 { j-- a[j] = '-' } return string(a[j:]) } _, 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 { u := uint64(i) if i < 0 { dst = append(dst, '-') u = -u } return AppendUint(dst, u, base) } // 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 base == 10 { if i < nSmalls { return append(dst, small(int(i))...) } var a [24]byte j := formatBase10(a[:], i) return append(dst, a[j:]...) } dst, _ = formatBits(dst, i, base, false, true) return dst } 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. // The caller is expected to have handled base 10 separately for speed. func formatBits(dst []byte, u uint64, base int, neg, append_ bool) (d []byte, s string) { if base < 2 || base == 10 || 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 isPowerOfTwo(base) { // Use shifts and masks instead of / and %. shift := uint(bits.TrailingZeros(uint(base))) b := uint64(base) m := uint(base) - 1 // == 1<= 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 } const nSmalls = 100 // smalls is the formatting of 00..99 concatenated. // It is then padded out with 56 x's to 256 bytes, // so that smalls[x&0xFF] has no bounds check. const smalls = "00010203040506070809" + "10111213141516171819" + "20212223242526272829" + "30313233343536373839" + "40414243444546474849" + "50515253545556575859" + "60616263646566676869" + "70717273747576777879" + "80818283848586878889" + "90919293949596979899" const host64bit = ^uint(0)>>32 != 0 // 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 smalls[i*2 : i*2+2] } // RuntimeFormatBase10 formats u into the tail of a // and returns the offset to the first byte written to a. // It is only for use by package runtime. // Other packages should use AppendUint. func RuntimeFormatBase10(a []byte, u uint64) int { return formatBase10(a, u) } // formatBase10 formats the decimal representation of u into the tail of a // and returns the offset of the first byte written to a. That is, after // // i := formatBase10(a, u) // // the decimal representation is in a[i:]. func formatBase10(a []byte, u uint64) int { // Split into 9-digit chunks that fit in uint32s // and convert each chunk using uint32 math instead of uint64 math. // The obvious way to write the outer loop is "for u >= 1e9", but most numbers are small, // so the setup for the comparison u >= 1e9 is usually pure overhead. // Instead, we approximate it by u>>29 != 0, which is usually faster and good enough. i := len(a) for (host64bit && u>>29 != 0) || (!host64bit && uint32(u)>>29|uint32(u>>32) != 0) { var lo uint32 u, lo = u/1e9, uint32(u%1e9) // Convert 9 digits. for range 4 { var dd uint32 lo, dd = lo/100, (lo%100)*2 i -= 2 a[i+0], a[i+1] = smalls[dd+0], smalls[dd+1] } i-- a[i] = smalls[lo*2+1] // If we'd been using u >= 1e9 then we would be guaranteed that u/1e9 > 0, // but since we used u>>29 != 0, u/1e9 might be 0, so we might be done. // (If u is now 0, then at the start we had 2²⁹ ≤ u < 10⁹, so it was still correct // to write 9 digits; we have not accidentally written any leading zeros.) if u == 0 { return i } } // Convert final chunk, at most 8 digits. lo := uint32(u) for lo >= 100 { var dd uint32 lo, dd = lo/100, (lo%100)*2 i -= 2 a[i+0], a[i+1] = smalls[dd+0], smalls[dd+1] } i-- dd := lo * 2 a[i] = smalls[dd+1] if lo >= 10 { i-- a[i] = smalls[dd+0] } return i }