vendor minify package

vendor/github.com/tdewolff/buffer/lexer.go

@@ -0,0 +1,221 @@
+package buffer // import "github.com/tdewolff/buffer"
+
+import "io"
+
+type block struct {
+	buf    []byte
+	next   int // index in pool plus one
+	active bool
+}
+
+type bufferPool struct {
+	pool []block
+	head int // index in pool plus one
+	tail int // index in pool plus one
+
+	pos int // byte pos in tail
+}
+
+func (z *bufferPool) swap(oldBuf []byte, size int) []byte {
+	// find new buffer that can be reused
+	swap := -1
+	for i := 0; i < len(z.pool); i++ {
+		if !z.pool[i].active && size <= cap(z.pool[i].buf) {
+			swap = i
+			break
+		}
+	}
+	if swap == -1 { // no free buffer found for reuse
+		if z.tail == 0 && z.pos >= len(oldBuf) && size <= cap(oldBuf) { // but we can reuse the current buffer!
+			z.pos -= len(oldBuf)
+			return oldBuf[:0]
+		}
+		// allocate new
+		z.pool = append(z.pool, block{make([]byte, 0, size), 0, true})
+		swap = len(z.pool) - 1
+	}
+
+	newBuf := z.pool[swap].buf
+
+	// put current buffer into pool
+	z.pool[swap] = block{oldBuf, 0, true}
+	if z.head != 0 {
+		z.pool[z.head-1].next = swap + 1
+	}
+	z.head = swap + 1
+	if z.tail == 0 {
+		z.tail = swap + 1
+	}
+
+	return newBuf[:0]
+}
+
+func (z *bufferPool) free(n int) {
+	z.pos += n
+	// move the tail over to next buffers
+	for z.tail != 0 && z.pos >= len(z.pool[z.tail-1].buf) {
+		z.pos -= len(z.pool[z.tail-1].buf)
+		newTail := z.pool[z.tail-1].next
+		z.pool[z.tail-1].active = false // after this, any thread may pick up the inactive buffer, so it can't be used anymore
+		z.tail = newTail
+	}
+	if z.tail == 0 {
+		z.head = 0
+	}
+}
+
+// Lexer is a buffered reader that allows peeking forward and shifting, taking an io.Reader.
+// It keeps data in-memory until Free, taking a byte length, is called to move beyond the data.
+type Lexer struct {
+	r   io.Reader
+	err error
+
+	pool bufferPool
+
+	buf       []byte
+	start     int // index in buf
+	pos       int // index in buf
+	prevStart int
+
+	free int
+}
+
+// NewLexer returns a new Lexer for a given io.Reader with a 4kB estimated buffer size.
+// If the io.Reader implements Bytes, that buffer is used instead.
+func NewLexer(r io.Reader) *Lexer {
+	return NewLexerSize(r, defaultBufSize)
+}
+
+// NewLexerSize returns a new Lexer for a given io.Reader and estimated required buffer size.
+// If the io.Reader implements Bytes, that buffer is used instead.
+func NewLexerSize(r io.Reader, size int) *Lexer {
+	// if reader has the bytes in memory already, use that instead
+	if buffer, ok := r.(interface {
+		Bytes() []byte
+	}); ok {
+		return &Lexer{
+			err: io.EOF,
+			buf: buffer.Bytes(),
+		}
+	}
+	return &Lexer{
+		r:   r,
+		buf: make([]byte, 0, size),
+	}
+}
+
+func (z *Lexer) read(pos int) byte {
+	if z.err != nil {
+		return 0
+	}
+
+	// free unused bytes
+	z.pool.free(z.free)
+	z.free = 0
+
+	// get new buffer
+	c := cap(z.buf)
+	p := pos - z.start + 1
+	if 2*p > c { // if the token is larger than half the buffer, increase buffer size
+		c = 2*c + p
+	}
+	d := len(z.buf) - z.start
+	buf := z.pool.swap(z.buf[:z.start], c)
+	copy(buf[:d], z.buf[z.start:]) // copy the left-overs (unfinished token) from the old buffer
+
+	// read in new data for the rest of the buffer
+	var n int
+	for pos-z.start >= d && z.err == nil {
+		n, z.err = z.r.Read(buf[d:cap(buf)])
+		d += n
+	}
+	pos -= z.start
+	z.pos -= z.start
+	z.start, z.buf = 0, buf[:d]
+	if pos >= d {
+		return 0
+	}
+	return z.buf[pos]
+}
+
+// Err returns the error returned from io.Reader. It may still return valid bytes for a while though.
+func (z *Lexer) Err() error {
+	if z.err == io.EOF && z.pos < len(z.buf) {
+		return nil
+	}
+	return z.err
+}
+
+// Free frees up bytes of length n from previously shifted tokens.
+// Each call to Shift should at one point be followed by a call to Free with a length returned by ShiftLen.
+func (z *Lexer) Free(n int) {
+	z.free += n
+}
+
+// Peek returns the ith byte relative to the end position and possibly does an allocation.
+// Peek returns zero when an error has occurred, Err returns the error.
+// TODO: inline function
+func (z *Lexer) Peek(pos int) byte {
+	pos += z.pos
+	if uint(pos) < uint(len(z.buf)) { // uint for BCE
+		return z.buf[pos]
+	}
+	return z.read(pos)
+}
+
+// PeekRune returns the rune and rune length of the ith byte relative to the end position.
+func (z *Lexer) PeekRune(pos int) (rune, int) {
+	// from unicode/utf8
+	c := z.Peek(pos)
+	if c < 0xC0 {
+		return rune(c), 1
+	} else if c < 0xE0 {
+		return rune(c&0x1F)<<6 | rune(z.Peek(pos+1)&0x3F), 2
+	} else if c < 0xF0 {
+		return rune(c&0x0F)<<12 | rune(z.Peek(pos+1)&0x3F)<<6 | rune(z.Peek(pos+2)&0x3F), 3
+	}
+	return rune(c&0x07)<<18 | rune(z.Peek(pos+1)&0x3F)<<12 | rune(z.Peek(pos+2)&0x3F)<<6 | rune(z.Peek(pos+3)&0x3F), 4
+}
+
+// Move advances the position.
+func (z *Lexer) Move(n int) {
+	z.pos += n
+}
+
+// Pos returns a mark to which can be rewinded.
+func (z *Lexer) Pos() int {
+	return z.pos - z.start
+}
+
+// Rewind rewinds the position to the given position.
+func (z *Lexer) Rewind(pos int) {
+	z.pos = z.start + pos
+}
+
+// Lexeme returns the bytes of the current selection.
+func (z *Lexer) Lexeme() []byte {
+	return z.buf[z.start:z.pos]
+}
+
+// Skip collapses the position to the end of the selection.
+func (z *Lexer) Skip() {
+	z.start = z.pos
+}
+
+// Shift returns the bytes of the current selection and collapses the position to the end of the selection.
+// It also returns the number of bytes we moved since the last call to Shift. This can be used in calls to Free.
+func (z *Lexer) Shift() []byte {
+	if z.pos > len(z.buf) { // make sure we peeked at least as much as we shift
+		z.read(z.pos - 1)
+	}
+	b := z.buf[z.start:z.pos]
+	z.start = z.pos
+	return b
+}
+
+// ShiftLen returns the number of bytes moved since the last call to ShiftLen. This can be used in calls to Free because it takes into account multiple Shifts or Skips.
+func (z *Lexer) ShiftLen() int {
+	n := z.start - z.prevStart
+	z.prevStart = z.start
+	return n
+}