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375 lines
10 KiB
Go
375 lines
10 KiB
Go
package unsnap
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// copyright (c) 2014, Jason E. Aten
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// license: MIT
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// Some text from the Golang standard library doc is adapted and
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// reproduced in fragments below to document the expected behaviors
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// of the interface functions Read()/Write()/ReadFrom()/WriteTo() that
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// are implemented here. Those descriptions (see
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// http://golang.org/pkg/io/#Reader for example) are
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// copyright 2010 The Go Authors.
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import "io"
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// FixedSizeRingBuf:
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//
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// a fixed-size circular ring buffer. Yes, just what is says.
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//
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// We keep a pair of ping/pong buffers so that we can linearize
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// the circular buffer into a contiguous slice if need be.
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//
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// For efficiency, a FixedSizeRingBuf may be vastly preferred to
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// a bytes.Buffer. The ReadWithoutAdvance(), Advance(), and Adopt()
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// methods are all non-standard methods written for speed.
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//
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// For an I/O heavy application, I have replaced bytes.Buffer with
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// FixedSizeRingBuf and seen memory consumption go from 8GB to 25MB.
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// Yes, that is a 300x reduction in memory footprint. Everything ran
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// faster too.
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//
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// Note that Bytes(), while inescapable at times, is expensive: avoid
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// it if possible. Instead it is better to use the FixedSizeRingBuf.Readable
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// member to get the number of bytes available. Bytes() is expensive because
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// it may copy the back and then the front of a wrapped buffer A[Use]
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// into A[1-Use] in order to get a contiguous slice. If possible use ContigLen()
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// first to get the size that can be read without copying, Read() that
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// amount, and then Read() a second time -- to avoid the copy.
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type FixedSizeRingBuf struct {
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A [2][]byte // a pair of ping/pong buffers. Only one is active.
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Use int // which A buffer is in active use, 0 or 1
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N int // MaxViewInBytes, the size of A[0] and A[1] in bytes.
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Beg int // start of data in A[Use]
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Readable int // number of bytes available to read in A[Use]
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OneMade bool // lazily instantiate the [1] buffer. If we never call Bytes(),
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// we may never need it. If OneMade is false, the Use must be = 0.
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}
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func (b *FixedSizeRingBuf) Make2ndBuffer() {
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if b.OneMade {
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return
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}
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b.A[1] = make([]byte, b.N, b.N)
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b.OneMade = true
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}
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// get the length of the largest read that we can provide to a contiguous slice
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// without an extra linearizing copy of all bytes internally.
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func (b *FixedSizeRingBuf) ContigLen() int {
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extent := b.Beg + b.Readable
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firstContigLen := intMin(extent, b.N) - b.Beg
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return firstContigLen
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}
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func NewFixedSizeRingBuf(maxViewInBytes int) *FixedSizeRingBuf {
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n := maxViewInBytes
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r := &FixedSizeRingBuf{
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Use: 0, // 0 or 1, whichever is actually in use at the moment.
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// If we are asked for Bytes() and we wrap, linearize into the other.
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N: n,
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Beg: 0,
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Readable: 0,
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OneMade: false,
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}
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r.A[0] = make([]byte, n, n)
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// r.A[1] initialized lazily now.
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return r
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}
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// from the standard library description of Bytes():
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// Bytes() returns a slice of the contents of the unread portion of the buffer.
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// If the caller changes the contents of the
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// returned slice, the contents of the buffer will change provided there
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// are no intervening method calls on the Buffer.
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//
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func (b *FixedSizeRingBuf) Bytes() []byte {
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extent := b.Beg + b.Readable
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if extent <= b.N {
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// we fit contiguously in this buffer without wrapping to the other
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return b.A[b.Use][b.Beg:(b.Beg + b.Readable)]
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}
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// wrap into the other buffer
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b.Make2ndBuffer()
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src := b.Use
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dest := 1 - b.Use
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n := copy(b.A[dest], b.A[src][b.Beg:])
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n += copy(b.A[dest][n:], b.A[src][0:(extent%b.N)])
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b.Use = dest
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b.Beg = 0
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return b.A[b.Use][:n]
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}
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// Read():
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//
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// from bytes.Buffer.Read(): Read reads the next len(p) bytes
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// from the buffer or until the buffer is drained. The return
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// value n is the number of bytes read. If the buffer has no data
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// to return, err is io.EOF (unless len(p) is zero); otherwise it is nil.
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//
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// from the description of the Reader interface,
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// http://golang.org/pkg/io/#Reader
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//
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/*
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Reader is the interface that wraps the basic Read method.
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Read reads up to len(p) bytes into p. It returns the number
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of bytes read (0 <= n <= len(p)) and any error encountered.
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Even if Read returns n < len(p), it may use all of p as scratch
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space during the call. If some data is available but not
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len(p) bytes, Read conventionally returns what is available
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instead of waiting for more.
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When Read encounters an error or end-of-file condition after
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successfully reading n > 0 bytes, it returns the number of bytes
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read. It may return the (non-nil) error from the same call or
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return the error (and n == 0) from a subsequent call. An instance
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of this general case is that a Reader returning a non-zero number
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of bytes at the end of the input stream may return
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either err == EOF or err == nil. The next Read should
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return 0, EOF regardless.
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Callers should always process the n > 0 bytes returned before
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considering the error err. Doing so correctly handles I/O errors
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that happen after reading some bytes and also both of the
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allowed EOF behaviors.
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Implementations of Read are discouraged from returning a zero
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byte count with a nil error, and callers should treat that
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situation as a no-op.
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*/
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//
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func (b *FixedSizeRingBuf) Read(p []byte) (n int, err error) {
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return b.ReadAndMaybeAdvance(p, true)
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}
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// if you want to Read the data and leave it in the buffer, so as
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// to peek ahead for example.
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func (b *FixedSizeRingBuf) ReadWithoutAdvance(p []byte) (n int, err error) {
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return b.ReadAndMaybeAdvance(p, false)
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}
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func (b *FixedSizeRingBuf) ReadAndMaybeAdvance(p []byte, doAdvance bool) (n int, err error) {
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if len(p) == 0 {
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return 0, nil
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}
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if b.Readable == 0 {
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return 0, io.EOF
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}
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extent := b.Beg + b.Readable
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if extent <= b.N {
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n += copy(p, b.A[b.Use][b.Beg:extent])
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} else {
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n += copy(p, b.A[b.Use][b.Beg:b.N])
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if n < len(p) {
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n += copy(p[n:], b.A[b.Use][0:(extent%b.N)])
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}
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}
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if doAdvance {
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b.Advance(n)
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}
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return
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}
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//
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// Write writes len(p) bytes from p to the underlying data stream.
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// It returns the number of bytes written from p (0 <= n <= len(p))
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// and any error encountered that caused the write to stop early.
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// Write must return a non-nil error if it returns n < len(p).
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//
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func (b *FixedSizeRingBuf) Write(p []byte) (n int, err error) {
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for {
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if len(p) == 0 {
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// nothing (left) to copy in; notice we shorten our
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// local copy p (below) as we read from it.
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return
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}
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writeCapacity := b.N - b.Readable
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if writeCapacity <= 0 {
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// we are all full up already.
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return n, io.ErrShortWrite
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}
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if len(p) > writeCapacity {
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err = io.ErrShortWrite
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// leave err set and
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// keep going, write what we can.
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}
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writeStart := (b.Beg + b.Readable) % b.N
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upperLim := intMin(writeStart+writeCapacity, b.N)
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k := copy(b.A[b.Use][writeStart:upperLim], p)
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n += k
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b.Readable += k
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p = p[k:]
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// we can fill from b.A[b.Use][0:something] from
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// p's remainder, so loop
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}
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}
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// WriteTo and ReadFrom avoid intermediate allocation and copies.
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// WriteTo writes data to w until there's no more data to write
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// or when an error occurs. The return value n is the number of
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// bytes written. Any error encountered during the write is also returned.
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func (b *FixedSizeRingBuf) WriteTo(w io.Writer) (n int64, err error) {
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if b.Readable == 0 {
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return 0, io.EOF
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}
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extent := b.Beg + b.Readable
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firstWriteLen := intMin(extent, b.N) - b.Beg
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secondWriteLen := b.Readable - firstWriteLen
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if firstWriteLen > 0 {
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m, e := w.Write(b.A[b.Use][b.Beg:(b.Beg + firstWriteLen)])
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n += int64(m)
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b.Advance(m)
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if e != nil {
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return n, e
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}
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// all bytes should have been written, by definition of
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// Write method in io.Writer
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if m != firstWriteLen {
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return n, io.ErrShortWrite
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}
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}
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if secondWriteLen > 0 {
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m, e := w.Write(b.A[b.Use][0:secondWriteLen])
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n += int64(m)
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b.Advance(m)
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if e != nil {
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return n, e
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}
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// all bytes should have been written, by definition of
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// Write method in io.Writer
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if m != secondWriteLen {
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return n, io.ErrShortWrite
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}
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}
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return n, nil
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}
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// ReadFrom() reads data from r until EOF or error. The return value n
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// is the number of bytes read. Any error except io.EOF encountered
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// during the read is also returned.
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func (b *FixedSizeRingBuf) ReadFrom(r io.Reader) (n int64, err error) {
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for {
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writeCapacity := b.N - b.Readable
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if writeCapacity <= 0 {
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// we are all full
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return n, nil
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}
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writeStart := (b.Beg + b.Readable) % b.N
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upperLim := intMin(writeStart+writeCapacity, b.N)
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m, e := r.Read(b.A[b.Use][writeStart:upperLim])
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n += int64(m)
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b.Readable += m
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if e == io.EOF {
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return n, nil
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}
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if e != nil {
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return n, e
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}
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}
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}
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func (b *FixedSizeRingBuf) Reset() {
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b.Beg = 0
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b.Readable = 0
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b.Use = 0
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}
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// Advance(): non-standard, but better than Next(),
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// because we don't have to unwrap our buffer and pay the cpu time
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// for the copy that unwrapping may need.
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// Useful in conjuction/after ReadWithoutAdvance() above.
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func (b *FixedSizeRingBuf) Advance(n int) {
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if n <= 0 {
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return
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}
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if n > b.Readable {
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n = b.Readable
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}
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b.Readable -= n
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b.Beg = (b.Beg + n) % b.N
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}
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// Adopt(): non-standard.
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//
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// For efficiency's sake, (possibly) take ownership of
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// already allocated slice offered in me.
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//
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// If me is large we will adopt it, and we will potentially then
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// write to the me buffer.
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// If we already have a bigger buffer, copy me into the existing
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// buffer instead.
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func (b *FixedSizeRingBuf) Adopt(me []byte) {
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n := len(me)
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if n > b.N {
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b.A[0] = me
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b.OneMade = false
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b.N = n
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b.Use = 0
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b.Beg = 0
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b.Readable = n
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} else {
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// we already have a larger buffer, reuse it.
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copy(b.A[0], me)
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b.Use = 0
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b.Beg = 0
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b.Readable = n
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}
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}
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func intMax(a, b int) int {
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if a > b {
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return a
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} else {
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return b
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}
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}
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func intMin(a, b int) int {
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if a < b {
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return a
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} else {
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return b
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}
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}
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// Get the (beg, end] indices of the tailing empty buffer of bytes slice that from that is free for writing.
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// Note: not guaranteed to be zeroed. At all.
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func (b *FixedSizeRingBuf) GetEndmostWritable() (beg int, end int) {
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extent := b.Beg + b.Readable
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if extent < b.N {
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return extent, b.N
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}
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return extent % b.N, b.Beg
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}
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// Note: not guaranteed to be zeroed.
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func (b *FixedSizeRingBuf) GetEndmostWritableSlice() []byte {
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beg, e := b.GetEndmostWritable()
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return b.A[b.Use][beg:e]
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}
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