minio/internal/ioutil/ioutil.go

409 lines
10 KiB
Go

// Copyright (c) 2015-2021 MinIO, Inc.
//
// This file is part of MinIO Object Storage stack
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU Affero General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Affero General Public License for more details.
//
// You should have received a copy of the GNU Affero General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
// Package ioutil implements some I/O utility functions which are not covered
// by the standard library.
package ioutil
import (
"bytes"
"context"
"io"
"os"
"sync"
"time"
"github.com/minio/minio/internal/disk"
)
// WriteOnCloser implements io.WriteCloser and always
// executes at least one write operation if it is closed.
//
// This can be useful within the context of HTTP. At least
// one write operation must happen to send the HTTP headers
// to the peer.
type WriteOnCloser struct {
io.Writer
hasWritten bool
}
func (w *WriteOnCloser) Write(p []byte) (int, error) {
w.hasWritten = true
return w.Writer.Write(p)
}
// Close closes the WriteOnCloser. It behaves like io.Closer.
func (w *WriteOnCloser) Close() error {
if !w.hasWritten {
_, err := w.Write(nil)
if err != nil {
return err
}
}
if closer, ok := w.Writer.(io.Closer); ok {
return closer.Close()
}
return nil
}
// HasWritten returns true if at least one write operation was performed.
func (w *WriteOnCloser) HasWritten() bool { return w.hasWritten }
// WriteOnClose takes an io.Writer and returns an ioutil.WriteOnCloser.
func WriteOnClose(w io.Writer) *WriteOnCloser {
return &WriteOnCloser{w, false}
}
type ioret struct {
n int
err error
}
// DeadlineReader deadline reader with timeout
type DeadlineReader struct {
io.ReadCloser
timeout time.Duration
err error
}
// NewDeadlineReader wraps a writer to make it respect given deadline
// value per Write(). If there is a blocking write, the returned Reader
// will return whenever the timer hits (the return values are n=0
// and err=context.DeadlineExceeded.)
func NewDeadlineReader(r io.ReadCloser, timeout time.Duration) io.ReadCloser {
return &DeadlineReader{ReadCloser: r, timeout: timeout}
}
func (r *DeadlineReader) Read(buf []byte) (int, error) {
if r.err != nil {
return 0, r.err
}
c := make(chan ioret, 1)
t := time.NewTimer(r.timeout)
go func() {
n, err := r.ReadCloser.Read(buf)
c <- ioret{n, err}
close(c)
}()
select {
case res := <-c:
if !t.Stop() {
<-t.C
}
r.err = res.err
return res.n, res.err
case <-t.C:
r.ReadCloser.Close()
r.err = context.DeadlineExceeded
return 0, context.DeadlineExceeded
}
}
// Close closer interface to close the underlying closer
func (r *DeadlineReader) Close() error {
return r.ReadCloser.Close()
}
// DeadlineWriter deadline writer with timeout
type DeadlineWriter struct {
io.WriteCloser
timeout time.Duration
err error
}
// DeadlineWorker implements the deadline/timeout resiliency pattern.
type DeadlineWorker struct {
timeout time.Duration
err error
}
// NewDeadlineWorker constructs a new DeadlineWorker with the given timeout.
func NewDeadlineWorker(timeout time.Duration) *DeadlineWorker {
return &DeadlineWorker{
timeout: timeout,
}
}
// Run runs the given function, passing it a stopper channel. If the deadline passes before
// the function finishes executing, Run returns ErrTimeOut to the caller and closes the stopper
// channel so that the work function can attempt to exit gracefully. It does not (and cannot)
// simply kill the running function, so if it doesn't respect the stopper channel then it may
// keep running after the deadline passes. If the function finishes before the deadline, then
// the return value of the function is returned from Run.
func (d *DeadlineWorker) Run(work func() error) error {
if d.err != nil {
return d.err
}
c := make(chan ioret, 1)
t := time.NewTimer(d.timeout)
go func() {
c <- ioret{0, work()}
close(c)
}()
select {
case r := <-c:
if !t.Stop() {
<-t.C
}
d.err = r.err
return r.err
case <-t.C:
d.err = context.DeadlineExceeded
return context.DeadlineExceeded
}
}
// NewDeadlineWriter wraps a writer to make it respect given deadline
// value per Write(). If there is a blocking write, the returned Writer
// will return whenever the timer hits (the return values are n=0
// and err=context.DeadlineExceeded.)
func NewDeadlineWriter(w io.WriteCloser, timeout time.Duration) io.WriteCloser {
return &DeadlineWriter{WriteCloser: w, timeout: timeout}
}
func (w *DeadlineWriter) Write(buf []byte) (int, error) {
if w.err != nil {
return 0, w.err
}
c := make(chan ioret, 1)
t := time.NewTimer(w.timeout)
go func() {
n, err := w.WriteCloser.Write(buf)
c <- ioret{n, err}
close(c)
}()
select {
case r := <-c:
if !t.Stop() {
<-t.C
}
w.err = r.err
return r.n, r.err
case <-t.C:
w.WriteCloser.Close()
w.err = context.DeadlineExceeded
return 0, context.DeadlineExceeded
}
}
// Close closer interface to close the underlying closer
func (w *DeadlineWriter) Close() error {
return w.WriteCloser.Close()
}
// LimitWriter implements io.WriteCloser.
//
// This is implemented such that we want to restrict
// an enscapsulated writer upto a certain length
// and skip a certain number of bytes.
type LimitWriter struct {
io.Writer
skipBytes int64
wLimit int64
}
// Write implements the io.Writer interface limiting upto
// configured length, also skips the first N bytes.
func (w *LimitWriter) Write(p []byte) (n int, err error) {
n = len(p)
var n1 int
if w.skipBytes > 0 {
if w.skipBytes >= int64(len(p)) {
w.skipBytes -= int64(len(p))
return n, nil
}
p = p[w.skipBytes:]
w.skipBytes = 0
}
if w.wLimit == 0 {
return n, nil
}
if w.wLimit < int64(len(p)) {
n1, err = w.Writer.Write(p[:w.wLimit])
w.wLimit -= int64(n1)
return n, err
}
n1, err = w.Writer.Write(p)
w.wLimit -= int64(n1)
return n, err
}
// Close closes the LimitWriter. It behaves like io.Closer.
func (w *LimitWriter) Close() error {
if closer, ok := w.Writer.(io.Closer); ok {
return closer.Close()
}
return nil
}
// LimitedWriter takes an io.Writer and returns an ioutil.LimitWriter.
func LimitedWriter(w io.Writer, skipBytes int64, limit int64) *LimitWriter {
return &LimitWriter{w, skipBytes, limit}
}
type nopCloser struct {
io.Writer
}
func (nopCloser) Close() error { return nil }
// NopCloser returns a WriteCloser with a no-op Close method wrapping
// the provided Writer w.
func NopCloser(w io.Writer) io.WriteCloser {
return nopCloser{w}
}
// SkipReader skips a given number of bytes and then returns all
// remaining data.
type SkipReader struct {
io.Reader
skipCount int64
}
func (s *SkipReader) Read(p []byte) (int, error) {
l := int64(len(p))
if l == 0 {
return 0, nil
}
for s.skipCount > 0 {
if l > s.skipCount {
l = s.skipCount
}
n, err := s.Reader.Read(p[:l])
if err != nil {
return 0, err
}
s.skipCount -= int64(n)
}
return s.Reader.Read(p)
}
// NewSkipReader - creates a SkipReader
func NewSkipReader(r io.Reader, n int64) io.Reader {
return &SkipReader{r, n}
}
var copyBufPool = sync.Pool{
New: func() interface{} {
b := make([]byte, 32*1024)
return &b
},
}
// Copy is exactly like io.Copy but with re-usable buffers.
func Copy(dst io.Writer, src io.Reader) (written int64, err error) {
bufp := copyBufPool.Get().(*[]byte)
buf := *bufp
defer copyBufPool.Put(bufp)
return io.CopyBuffer(dst, src, buf)
}
// SameFile returns if the files are same.
func SameFile(fi1, fi2 os.FileInfo) bool {
if !os.SameFile(fi1, fi2) {
return false
}
if !fi1.ModTime().Equal(fi2.ModTime()) {
return false
}
if fi1.Mode() != fi2.Mode() {
return false
}
return fi1.Size() == fi2.Size()
}
// DirectioAlignSize - DirectIO alignment needs to be 4K. Defined here as
// directio.AlignSize is defined as 0 in MacOS causing divide by 0 error.
const DirectioAlignSize = 4096
// CopyAligned - copies from reader to writer using the aligned input
// buffer, it is expected that input buffer is page aligned to
// 4K page boundaries. Without passing aligned buffer may cause
// this function to return error.
//
// This code is similar in spirit to io.Copy but it is only to be
// used with DIRECT I/O based file descriptor and it is expected that
// input writer *os.File not a generic io.Writer. Make sure to have
// the file opened for writes with syscall.O_DIRECT flag.
func CopyAligned(w io.Writer, r io.Reader, alignedBuf []byte, totalSize int64, file *os.File) (int64, error) {
// Writes remaining bytes in the buffer.
writeUnaligned := func(w io.Writer, buf []byte) (remainingWritten int64, err error) {
// Disable O_DIRECT on fd's on unaligned buffer
// perform an amortized Fdatasync(fd) on the fd at
// the end, this is performed by the caller before
// closing 'w'.
if err = disk.DisableDirectIO(file); err != nil {
return remainingWritten, err
}
// Since w is *os.File io.Copy shall use ReadFrom() call.
return io.Copy(w, bytes.NewReader(buf))
}
var written int64
for {
buf := alignedBuf
if totalSize != -1 {
remaining := totalSize - written
if remaining < int64(len(buf)) {
buf = buf[:remaining]
}
}
nr, err := io.ReadFull(r, buf)
eof := err == io.EOF || err == io.ErrUnexpectedEOF
if err != nil && !eof {
return written, err
}
buf = buf[:nr]
var nw int64
if len(buf)%DirectioAlignSize == 0 {
var n int
// buf is aligned for directio write()
n, err = w.Write(buf)
nw = int64(n)
} else {
// buf is not aligned, hence use writeUnaligned()
nw, err = writeUnaligned(w, buf)
}
if nw > 0 {
written += nw
}
if err != nil {
return written, err
}
if nw != int64(len(buf)) {
return written, io.ErrShortWrite
}
if totalSize != -1 {
if written == totalSize {
return written, nil
}
}
if eof {
return written, nil
}
}
}