// 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. // Functions and constants to support text encoded in UTF-8. // This package calls a Unicode character a rune for brevity. package utf8 import "unicode" // only needed for a couple of constants // Numbers fundamental to the encoding. const ( RuneError = unicode.ReplacementChar; // the "error" Rune or "replacement character". RuneSelf = 0x80; // characters below Runeself are represented as themselves in a single byte. UTFMax = 4; // maximum number of bytes of a UTF-8 encoded Unicode character. ) const ( _T1 = 0x00; // 0000 0000 _Tx = 0x80; // 1000 0000 _T2 = 0xC0; // 1100 0000 _T3 = 0xE0; // 1110 0000 _T4 = 0xF0; // 1111 0000 _T5 = 0xF8; // 1111 1000 _Maskx = 0x3F; // 0011 1111 _Mask2 = 0x1F; // 0001 1111 _Mask3 = 0x0F; // 0000 1111 _Mask4 = 0x07; // 0000 0111 _Rune1Max = 1<<7 - 1; _Rune2Max = 1<<11 - 1; _Rune3Max = 1<<16 - 1; _Rune4Max = 1<<21 - 1; ) func decodeRuneInternal(p []byte) (rune, size int, short bool) { n := len(p); if n < 1 { return RuneError, 0, true } c0 := p[0]; // 1-byte, 7-bit sequence? if c0 < _Tx { return int(c0), 1, false } // unexpected continuation byte? if c0 < _T2 { return RuneError, 1, false } // need first continuation byte if n < 2 { return RuneError, 1, true } c1 := p[1]; if c1 < _Tx || _T2 <= c1 { return RuneError, 1, false } // 2-byte, 11-bit sequence? if c0 < _T3 { rune = int(c0&_Mask2)<<6 | int(c1&_Maskx); if rune <= _Rune1Max { return RuneError, 1, false } return rune, 2, false; } // need second continuation byte if n < 3 { return RuneError, 1, true } c2 := p[2]; if c2 < _Tx || _T2 <= c2 { return RuneError, 1, false } // 3-byte, 16-bit sequence? if c0 < _T4 { rune = int(c0&_Mask3)<<12 | int(c1&_Maskx)<<6 | int(c2&_Maskx); if rune <= _Rune2Max { return RuneError, 1, false } return rune, 3, false; } // need third continuation byte if n < 4 { return RuneError, 1, true } c3 := p[3]; if c3 < _Tx || _T2 <= c3 { return RuneError, 1, false } // 4-byte, 21-bit sequence? if c0 < _T5 { rune = int(c0&_Mask4)<<18 | int(c1&_Maskx)<<12 | int(c2&_Maskx)<<6 | int(c3&_Maskx); if rune <= _Rune3Max { return RuneError, 1, false } return rune, 4, false; } // error return RuneError, 1, false; } func decodeRuneInStringInternal(s string) (rune, size int, short bool) { n := len(s); if n < 1 { return RuneError, 0, true } c0 := s[0]; // 1-byte, 7-bit sequence? if c0 < _Tx { return int(c0), 1, false } // unexpected continuation byte? if c0 < _T2 { return RuneError, 1, false } // need first continuation byte if n < 2 { return RuneError, 1, true } c1 := s[1]; if c1 < _Tx || _T2 <= c1 { return RuneError, 1, false } // 2-byte, 11-bit sequence? if c0 < _T3 { rune = int(c0&_Mask2)<<6 | int(c1&_Maskx); if rune <= _Rune1Max { return RuneError, 1, false } return rune, 2, false; } // need second continuation byte if n < 3 { return RuneError, 1, true } c2 := s[2]; if c2 < _Tx || _T2 <= c2 { return RuneError, 1, false } // 3-byte, 16-bit sequence? if c0 < _T4 { rune = int(c0&_Mask3)<<12 | int(c1&_Maskx)<<6 | int(c2&_Maskx); if rune <= _Rune2Max { return RuneError, 1, false } return rune, 3, false; } // need third continuation byte if n < 4 { return RuneError, 1, true } c3 := s[3]; if c3 < _Tx || _T2 <= c3 { return RuneError, 1, false } // 4-byte, 21-bit sequence? if c0 < _T5 { rune = int(c0&_Mask4)<<18 | int(c1&_Maskx)<<12 | int(c2&_Maskx)<<6 | int(c3&_Maskx); if rune <= _Rune3Max { return RuneError, 1, false } return rune, 4, false; } // error return RuneError, 1, false; } // FullRune reports whether the bytes in p begin with a full UTF-8 encoding of a rune. // An invalid encoding is considered a full Rune since it will convert as a width-1 error rune. func FullRune(p []byte) bool { _, _, short := decodeRuneInternal(p); return !short; } // FullRuneInString is like FullRune but its input is a string. func FullRuneInString(s string) bool { _, _, short := decodeRuneInStringInternal(s); return !short; } // DecodeRune unpacks the first UTF-8 encoding in p and returns the rune and its width in bytes. func DecodeRune(p []byte) (rune, size int) { rune, size, _ = decodeRuneInternal(p); return; } // DecodeRuneInString is like DecodeRune but its input is a string. func DecodeRuneInString(s string) (rune, size int) { rune, size, _ = decodeRuneInStringInternal(s); return; } // RuneLen returns the number of bytes required to encode the rune. func RuneLen(rune int) int { switch { case rune <= _Rune1Max: return 1 case rune <= _Rune2Max: return 2 case rune <= _Rune3Max: return 3 case rune <= _Rune4Max: return 4 } return -1; } // EncodeRune writes into p (which must be large enough) the UTF-8 encoding of the rune. // It returns the number of bytes written. func EncodeRune(rune int, p []byte) int { if rune <= _Rune1Max { p[0] = byte(rune); return 1; } if rune <= _Rune2Max { p[0] = _T2 | byte(rune>>6); p[1] = _Tx | byte(rune)&_Maskx; return 2; } if rune > unicode.MaxRune { rune = RuneError } if rune <= _Rune3Max { p[0] = _T3 | byte(rune>>12); p[1] = _Tx | byte(rune>>6)&_Maskx; p[2] = _Tx | byte(rune)&_Maskx; return 3; } p[0] = _T4 | byte(rune>>18); p[1] = _Tx | byte(rune>>12)&_Maskx; p[2] = _Tx | byte(rune>>6)&_Maskx; p[3] = _Tx | byte(rune)&_Maskx; return 4; } // RuneCount returns the number of runes in p. Erroneous and short // encodings are treated as single runes of width 1 byte. func RuneCount(p []byte) int { i := 0; var n int; for n = 0; i < len(p); n++ { if p[i] < RuneSelf { i++ } else { _, size := DecodeRune(p[i:]); i += size; } } return n; } // RuneCountInString is like RuneCount but its input is a string. func RuneCountInString(s string) (n int) { for _ = range s { n++ } return; } // RuneStart reports whether the byte could be the first byte of // an encoded rune. Second and subsequent bytes always have the top // two bits set to 10. func RuneStart(b byte) bool { return b&0xC0 != 0x80 }